FCC ID: YTXA103 Wireless Adapter

 

A103 Wireless Adapter Rev: 2.0.0 1910020432 FCC STATEMENT This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures:

Reorient or relocate the receiving antenna. Increase the separation between the equipment and receiver. Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. Consult the dealer or an experienced radio/ TV technician for help. This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions:

1) This device may not cause harmful interference. 2) This device must accept any interference received, including interference that may cause undesired operation. Any changes or modifications not expressly approved by the party responsible for compliance could void the users authority to operate the equipment. Note: The manufacturer is not responsible for any radio or tv interference caused by unauthorized modifications to this equipment. Such modifications could void the users authority to operate the equipment. FCC RF Radiation Exposure Statement This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. End users must follow the specific operating instructions for satisfying RF exposure compliance. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. This equipment has been SAR-evaluated for use in hand. SAR measurements are based on 5mm spacing from the body and that compliance is achieved at that distance. I CE Mark Warning This is a class B product. In a domestic environment, this product may cause radio interference, in which case the user may be required to take adequate measures. National restrictions This device is intended for home and office use in all EU countries (and other countries following the EU directive 1999/5/EC) without any limitation except for the countries mentioned below:

Country Restriction Reason/remark Bulgaria public service General authorization required for outdoor use and Outdoor use limited to 10 Military Radiolocation use. Refarming of the 2.4 GHz France mW e.i.r.p. within the band band has been ongoing in recent years to allow current 2454-2483.5 MHz relaxed regulation. Full implementation planned 2012 Italy required If used outside of own premises, general authorization is Luxembourg None General authorization required for network and service supply(not for spectrum) Norway Implemented This subsection does not apply for the geographical area within a radius of 20 km from the centre of Ny-lesund Russian Federation Only for indoor applications Note: Please dont use the product outdoors in France. II Industry Canada Statement Complies with the Canadian ICES-003 Class B specifications. Cet appareil numrique de la classe B est conforme la norme NMB-003 du Canada. This device complies with RSS 210 of Industry Canada. This Class B device meets all the requirements of the Canadian interference-causing equipment regulations. Cet appareil numrique de la Classe B respecte toutes les exigences du Rglement sur le matriel brouilleur du Canada. III CONTENTS Package Contents .................................................................................................... 1 Chapter 1 Introduction .......................................................................................... 2 1.1 Product Overview ............................................................................................ 2 1.2 Main Features .................................................................................................. 2 1.3 LED Status ...................................................................................................... 2 Chapter 2 Installation Guide ................................................................................. 3 2.1 Hardware Installation ....................................................................................... 3 2.2 Software Installation ........................................................................................ 3 2.2.1 Overview ........................................................................................................ 3 2.2.2 Installation Guide ............................................................................................ 3 2.3 Uninstall Software ............................................................................................ 8 2.3.1 Uninstall the utility software from your PC ....................................................... 8 2.3.2 Uninstall the driver software from your PC....................................................... 8 Chapter 3 Configuration ........................................................................................ 9 3.1 Configuration of Utility ...................................................................................... 9 3.1.1 Site Survey ................................................................................................... 10 3.1.2 Profile ........................................................................................................... 10 3.1.3 Link Information ............................................................................................ 22 3.1.4 Advanced ..................................................................................................... 24 3.1.5 About ............................................................................................................ 25 3.1.6 An example for application ............................................................................ 25 3.2 Configure with Windows XP Wireless Zero Configuration .............................. 26 Chapter 4 AP Mode .............................................................................................. 28 4.1 Config AP ...................................................................................................... 28 4.2 Advanced ...................................................................................................... 30 4.3 Access Control List ........................................................................................ 30 4.4 Associate List ................................................................................................ 32 4.5 About ............................................................................................................. 33 Chapter 5 Example for Application .................................................................... 34 5.1 Configuration of PSP XLink Online game ...................................................... 34 Appendix A: Glossary ......................................................................................... 38 Appendix B: Specifications ................................................................................ 40 Package Contents A103 Wireless Adapter User Guide The following items should be found in your package:

One A103 Wireless Adapter One USB extension cable Quick Installation Guide One Resource CD for A103 Wireless Adapter, including:

Drivers and Utility User Guide Other Helpful Information Note:

Make sure that the package contains the above items. If any of the listed items are damaged or missing, please contact with your distributor.

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A103 Wireless Adapter User Guide Chapter 1 Introduction 1.1 Product Overview Thank you for choosing the A103 Wireless Adapter. The adapter is designed to provide a high-speed and unrivaled wireless performance for your computer. With a faster wireless connection, you can get a better Internet experience, such as downloading, gaming, video streaming and so on. The A103 Wireless Adapter complies with IEEE 802.11n, IEEE 802.11g and IEEE 802.11b standards. It can perfectly interoperate with all the 802.11n/g/b devices. The A103s auto-sensing capability allows high packet transfer rate of up to 150Mbps for maximum throughput. Additionally, the A103 adapter has good capability on anti-jamming and supports WEP, TKIP, AES WPA and WPA2 encryption to prevent outside intrusion and protect your personal information from being exposed. The adapter is easy to install and manage. The A103 supports WPS function, which can help you create a wireless connection immediately. Quick Setup Wizard is supported and detailed instructions are provided step by step in this user guide. Featuring high performance transmission rates, simple installation and adaptability, as well as strong security, the A103 Wireless Adapter is the perfect solution for small office and home needs. 1.2 Main Features IEEE 802.11n, IEEE 802.11g, IEEE 802.11b standards Supports USB 2.0 standard Supports WPA data security, IEEE 802.1x authentication, TKIP/AES encryption, 64/128-bit WEP encryption Supports wireless LAN data transfer rate of up to 150Mbps Supports Ad-Hoc and Infrastructure modes Supports roaming between access points when configured in Infrastructure mode Eases configuration and provides monitoring information Supports Windows XP/ Vista/ 7 1.3 LED Status The LED on the top of this card indicates Link/Act status. It blinks when sending and receiving data.

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A103 Wireless Adapter User Guide Chapter 2 Installation Guide 2.1 Hardware Installation 1. Connect one end of the USB cable to the Adapter. 2. Connect the other end of the USB cable to the USB port on your computer. The Adapter gets its power from the host and there is no external power supply. The LED should light up when the Adapter is plugged in and the PC is on. Note:

The Adapter can also be plugged into the USB port on your computer directly. 2.2 Software Installation 2.2.1 Overview The Adapters Setup Wizard will guide you through the installation of the Utility and drivers. Before you install the software, please connect the USB adapter with your computer by USB cable. After that, you will be prompted Found New Hardware Wizard, click the Cancel button, and run the Setup Wizard program on the CD-ROM. Note:

The Setup steps for Windows XP/ Vista/ 7 are very similar, so the following installation guide takes Windows XP for example. 2.2.2 Installation Guide 1. Insert the Resource CD into your CD-ROM drive, then go to My Computer to double-click CD-ROM A103, and you will see the screen as Figure 2-1. Double-click Setup.exe to start the installation.

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A103 Wireless Adapter User Guide Figure 2-1 Start the Installation 2. Youll see the screen as below. You can choose which to be installed and click Next. Figure 2-2 Setup Type 3. In the following screen, select the configuration tool and click Next.

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A103 Wireless Adapter User Guide Figure 2-3 Setup Type 1) If you want to install the RL52 Wireless N Client Utility, please select the Wireless Configuration Tool. 2) If you only want to use the Microsoft Zero Configuration Tool to configure the wireless connection, please select Microsoft Zero Configuration Tool. 4. Choose the destination location and click Next. Figure 2-4 Choose Destination Location

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5. You will see the next screen as below. Click Install to continue. A103 Wireless Adapter User Guide 6. The following screen for installing will appear. Figure 2-5 Ready to Install the Program Figure 2-6 Setup Status Note:

While files are copying, a warning box about Windows Logo testing (shown in Figure 2-7) may pop up, please click Continue Anyway to continue the installation for our drivers have been tested thoroughly and are able to work with the operating system.

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A103 Wireless Adapter User Guide Figure 2-7 Windows XP Warning Box 7. After the files have been successfully copied, the screen in Figure 2-8 will appear. Click the Finish button to finish the installation and reboot the system. Figure 2-8 InstallShield Wizard Complete After installing the driver successfully, you should see an icon or in your system tray.

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2.3 Uninstall Software A103 Wireless Adapter User Guide 2.3.1 Uninstall the utility software from your PC 1. On the Windows taskbar, click the Start button, point to All programsWireless, and then click Uninstal-RL52 Wireless N Client Utility. 2. Follow the Install Shield Wizard to uninstall the utility software from your PC. 2.3.2 Uninstall the driver software from your PC 1. On the Windows taskbar, click the Start button, and then click Control Panel. 2. Click the System icon, click on the Hardware tab in the System window. 3. Click on the Device Manager button, double-click Network adapters, and then right-click Wireless N Client Adapter. Figure 2-9 Device Manager 4. Click Uninstall shown in above Figure 2-9, the system will uninstall the driver software of the adapter from your PC.

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A103 Wireless Adapter User Guide Chapter 3 Configuration 3.1 Configuration of Utility A103 Wireless Adapter can be configured by its utility for Windows XP/ Vista/ 7. This section will take the configuration in Windows XP for example and guide you to configure your wireless adapter for wireless connectivity with trustable data security encryption features. The configuration steps in Windows XP/ Vista/ 7 are similar. For the configurations in Windows Vista/ 7, please refer to the instructions in Windows XP. After the Adapter's driver and utility have been installed, the adapters tray icon, or

, will appear in your system tray. It means the utility is running on your system. If the utility does not run, you can run the utility by clicking: Start> All programs> Wireless> RL52 Wireless N Client Utility. If the icon still does not appear, the driver or utility may be installed incorrectly or the adapter is unplugged, please try again. Icon means the connection has been established. Icon means there is no connection. Right-click the icon and choose Launch Config Utility, the configuration screen of the utility will appear as shown in the figure below. Figure 3-1 Configuration Screen The utility provides complete and easy manage tools to:

Display current status information Edit and add configured profiles Display current diagnostics information Note:

If your OS is Windows XP, you can use Windows XP to configure the wireless network settings.

(To use this function, you must upgrade the OS with sp2). Just right-click the icon at the bottom of the screen, and click Use Zero Configuration as Configuration utility to switch the utility.

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3.1.1 Site Survey A103 Wireless Adapter User Guide Click the Site Survey icon on the screen of the Utility and the Site Survey screen with many available wireless network choices will appear. The AP list will be updated every two seconds. The AP list includes most used fields, such as SSID, network type, channel used, wireless mode, security status and the signal percentage. The dialog box is shown in Figure 3-2.

(Rescan): Click the Rescan icon to refresh the list at any time. Figure 3-2 Site Survey

(Add to Profile): Choose an SSID and click the Add to Profile icon to add the network to the profile.

(Connect): Choose an SSID and click the Connect icon to connect to an available network without adding it to the profile. 3.1.2 Profile Click the icon on the screen of the Utility and the Profile List screen will appear as Figure 3-3. The Profile List keeps a record of your favorite wireless settings at home, office, and other public hot-spots. You can save multiple profiles, and activate the correct one at your preference. Figure 3-3 shows the basic profile section. The Profile screen provides tools to:

Add a profile Delete a profile

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A103 Wireless Adapter User Guide Edit a profile Import a profile Export a profile Add a WPS profile Figure 3-3 Profile List

- Click to add a new profile.

- Deletes an existing profile.

- Click to edit an existing profile.

- Imports an existing profile.

- Exports an existing profile.

- Add a WPS profile Profile Name - Name of profile, preset to PROF* (* indicate 1, 2, 3...). SSID - The access point or Ad-hoc name. Authentication - Indicates the authentication mode used. Encryption - Indicates the encryption type used. 3.1.2.1. Add a profile 1. Click the Add icon on the Profile List screen (Figure 3-3), the Profile configuration screen will appear as shown in Figure 3-4. Enter the Profile Name and choose the SSID from the pull-down list, then click the Next icon to continue.

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A103 Wireless Adapter User Guide Figure 3-4 Add a new profile

- Cancel button.

- Back to the previous page.

- Continue to the next page. Profile Name - Identifies the configuration profile. This name must be unique. Profile names are not case-sensitive. SSID - The IEEE 802.11 wireless network name. This field has a maximum limit of 32 characters. Network Type: There are basically two modes of networking:

Infrastructure - All wireless clients will connect to an access point or wireless router. Ad Hoc - Directly connecting to another computer, for peer-to-peer communication, using wireless network adapters on each computer, such as two or more A103 wireless adapters. Note:

1) An Infrastructure network contains an Access Point or wireless router. All the wireless devices or clients will connect to the wireless router or access point. 2) An Ad Hoc network contains only clients, such as laptops with wireless desktop adapters. All the adapters must be in Ad Hoc mode to communicate. 2. In the following screen, select the corresponding Authentication mode and Encryption type of the profile from the drop-down lists (here takes WPA2-PSK and AES for example), then click the Next icon to continue.

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A103 Wireless Adapter User Guide Figure 3-5 Authentication and Encryption Authentication - You can choose the Authentication Type from the pull-down list with seven options, Open, Shared, WPA, WPA-PSK, WPA2, WPA2-PSK, and 802.1X. Encryption - Displays which encryption type that the adapter is using. When you select Open as Authentication, there are two options: None and WEP. If you select Shared and 802.1X as Authentication, there is only one option: WEP. When you select WPA, WPA-PSK or WPA2-PSK as Authentication, there are two options: TKIP and AES. When you select WPA2 as Authentication, four options are available: TKIP, AES, TKIP(MFP) and AES(MFP). 3. In the screen that follows, enter the key of the AP in the empty field. Here takes Key 1234567890 for example. If the wireless network you are trying to connect is security-enabled, you must enter the corresponding key to establish a successful connection. Then click the Next icon to continue. Figure 3-6 Enter the Key 4. The Pre-logon Connect configuration page as shown in Figure 3-7 will then appear. Click the Next icon to continue.

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A103 Wireless Adapter User Guide Use Pre-logon Connection - Use ID and Password in Profile. Figure 3-7 Use Pre-logon Connection 5. Some advanced settings can be made in Figure 3-8. Tx Power - Manually force the APs transmitting power. Figure 3-8 Profile Use RTS Threshold - Here you can specify the RTS (Request to Send) Threshold. If you are not sure, please leave it default here. Use Fragment Threshold - This value is the maximum size determining whether packets will be fragmented. Setting the Fragment Threshold too low may result in poor network performance because of excessive packages. You are recommended to leave it default if you are not sure about it. 6. Click the Active icon in the screen below to connect to the chosen network. When the screen looks like below, it shows that you have successfully added a new profile and connected to the wireless network.

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A103 Wireless Adapter User Guide Figure 3-9 Profile Added Successfully 3.1.2.2. Delete a profile Highlight the desired profile name on Profile List and click the Delete icon

. The profile will be removed from the list. Figure 3-10 Delete a Profile 3.1.2.3. Edit a profile Highlight the desired profile name on Profile List, and click the Edit icon

, the Profile configuration screen will appear as shown in Figure 3-11. You can make some changes of the profile, for instance, you can change the Profile Name to name it like My Network.

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A103 Wireless Adapter User Guide Figure 3-11 Edit a Profile 3.1.2.4. Import a profile 1. From the Profile List screen (shown in Figure 3-3), click the Import icon

. Then the Import Profile screen will appear below. 2. Browse to the directory where the profile is located. 3. Highlight the profile name. 4. Click Open, the imported profile will then appear in the Profile List. Figure 3-12 Import a Profile 3.1.2.5. Export a profile 1. From the Profile List screen (shown in Figure 3-9), highlight the profile to be exported. 2. Click Export icon

, the Export Profile window will then appear below. 3. Browse the directory to export the profile to. 4. Click Save. The profile should then be exported to the specified location.

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A103 Wireless Adapter User Guide Figure 3-13 Export a Profile 3.1.2.6. Add a WPS profile Click the Add WPS Profile icon of the Utility and you can configure the WPS function to join an existing network quickly in the following screen. Figure 3-14 Profile List If the wireless card supports WPS (Wi-Fi Protected Setup) or QSS (Quick Secure Setup), you can establish a wireless connection between wireless card and router using either Push Button Configuration (PBC) method or PIN method. For the configuration of WPS, here takes the Wireless Router of our company for example. Note:

To build a successful connection by WPS, you should also do the corresponding configuration of the Access Point for WPS or QSS function meanwhile.

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I. PBC Method A103 Wireless Adapter User Guide If your Access Point is equipped with a push-button for Wi-Fi Protected Setup, you can connect the adapter to the Access Point by Push-Button Configuration (PBC) method. Step 1 Press the WPS button on your Access Point device. Figure 3-15 Press the WPS Button Step 2 Click the Add WPS Profile icon on the screen as Figure 3-14. Step 3 Select Push-Button Configuration (PBC) on the screen below. Step 4 Click Start PBC. Figure 3-16 Push-Button Configuration Figure 3-17 Start PBC

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Step 5 The Adapter will search for the AP to establish connection automatically. A103 Wireless Adapter User Guide Step 6 Wait a moment until Figure 3-19 appears. Figure 3-18 II. PIN Method Figure 3-19 If your Access Point supports Wi-Fi Protected Setup and the PIN method, you can add the adapter to the network by the following two ways:

1) Enter the PIN into my Access Point Step 1 Click the Add WPS Profile icon on the screen as Figure 3-14. Step 2 Tick PIN/numeric code and then select the desired SSID from the WPS AP List

(take Network for example) on the screen below.

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A103 Wireless Adapter User Guide Figure 3-20 Step 3 Choose the Config Mode as Enrollee and click the Next icon on the screen below. Meanwhile, enter the PIN code of the adapter (here takes 51349417 in the screen for example) into the configuration utility of the AP. For the detailed instructions of the AP configuration, please refer to the User Guide of the AP. Step 4 Click Start PIN on the following screen. Figure 3-21 Enrollee Mode Step 5 When Figure 3-19 appears, the configuration is complete. Figure 3-22 Start PIN

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A103 Wireless Adapter User Guide 2) Enter a PIN from my Access Point Step 1 Click the Add WPS Profile icon on the screen as Figure 3-14. Step 2 Tick PIN/numeric code and then select the desired SSID from the WPS AP List

(take Network for example) on the screen below. Figure 3-23 Step 3 Choose the Config Mode as Registrar and enter the PIN of AP (here takes 97056270 for example) into the field beside the Pin Code as Figure 3-24 shows. For the detailed instructions of the AP configuration, please refer to the User Guide of the AP. And then click Next icon to continue. Step 4 Click Start PIN on the following screen. Figure 3-24 Registrar Mode Figure 3-25 Start PIN

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A103 Wireless Adapter User Guide Step 5 When Figure 3-19 appears, the configuration is complete. Note:

The default PIN code of the AP always can be found in its label or User Guide. 3.1.3 Link Information Click the Link Information icon of the Utility and you will see the following screen displaying the receiving and transmitting statistical information. Click the Link Status icon

, you can view the current linking status of the Adapter as shown in the figure below. Figure 3-26 Link Status The following table describes the items found on the Link Status screen. Status - Current connection status. If no connection, it will show Disconnected. Otherwise, the SSID and BSSID will show here. Extra Info - Here displays the link status in use. Authentication - Shows the authentication mode in use. Encrtption - The encryption type in use is displayed here. Network Type - The type of network and the station currently connected are shown here. The options include:

Infrastructure (access point) Ad Hoc Central Channel - The channel of the currently connected AP. Click the Throughput icon

, you can view the Link Quality, Signal Strength and Link Speed to see whether the Adapter is working well.

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A103 Wireless Adapter User Guide Link Quality - Displays connection quality based on signal strength and TX/RX packet error rate. Figure 3-27 Throughput Signal Strength - This shows the strength of the signal. Link Speed - Shows current transmit rate and receive rate. Throughput - Displays transmit and receive throughput in unit of Mbps. When clicking the Statistics icon

, you will see the following screens respectively displaying the receiving and transmitting statistical information. Click the Reset Counter icon to reset all the counters to zero. Figure 3-28 Transmit Statistics Transmitted Successfully - Frames successfully sent. Retransmitted Successfully - Successfully retransmitted frames numbers. Fail To Receive ACK After All Retries - Frames failed to transmit after hitting retry limit.

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A103 Wireless Adapter User Guide Figure 3-29 Receive Statistics Received Successfully - The number of frames successfully received. Received With CRC Error - The number of frames received with a CRC error. Dropped Due To Out-of-Resource - The number of frames dropped due to a resource issue. Duplicate Frames Received - The number of duplicate frames received. 3.1.4 Advanced Click the Advanced icon following screen. of the Utility and then you can choose the wireless mode on the Figure 3-30 Advanced Wireless Mode - Specifies 2.4 GHz 150 Mbps, 2.4 GHz 54 Mbps or 2.4 GHz 11 Mbps operation in an access point network. The Wireless adapter must match the wireless mode of

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A103 Wireless Adapter User Guide the access point with which it associates. Enable TX Burst - It can translate more data when it is enabled. Enable TCP Window Size - It can enhance the TCP throughput when it is enabled. Fast Roaming at - Roaming will disable when Transmit Power is below some dBm if the function is selected. Apply - Click the Apply button to save the current setting. 3.1.5 About Click the About icon on the Utility screen and you will see the following screen displaying the wireless card and driver version information. Figure 3-31 About Version - The version of the following items. Utility Date - The creation date of this utility. Driver Date - The creation date of the wireless network adapter driver. SDK Date The creation date of the SDK. Firmware Version -The version of the adapter firmware. EEPROM Version - The version of this EEPROM. MAC Address - The MAC address of the wireless network adapter. Note:

For more help information, you can go to website of our company. 3.1.6 An example for application Suppose you are using an AP, the SSID is TEST and it adopts 64-bit encryption with the key 1234567890. To establish a connection with this AP, please follow these steps below:

1. Launch RL52 Wireless N Client Utility. 2. Click the Profile icon of the utility and click the Add icon on the screen that appears. 3. The Profile configuration screen will appear, please select SSID TEST from the drop-down

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A103 Wireless Adapter User Guide list. Enter Test for the Profile Name, and select Infrastructure for the Network Type, then click Next icon to the next page. Select WPA2-PSK for the Authentication, AES for the Encryption and click Next icon to continue. Enter 1234567890 for the Key. You can make some advanced settings in the following screens or you are recommended to leave the options default if you are not sure about them. 4. Highlight the profile named Test on the profile list and click Active icon on the Profile screen. The utility will establish a connection with this AP by configured profile. 3.2 Configure with Windows XP Wireless Zero Configuration 1. Right click the icon on the bottom of the desktop first an d you will see Figure 3-32. Click the Use Zero Configuration as Configuration Utility option to enable Wireless Zero Configuration function. Figure 3-32 Use Zero Configuration as Configuration utility 2. After that, double click the icon

, and the following Figure 3-33 will appear with some available wireless network choices. You can highlight a network and then click Connect to add to a network. Figure 3-33 Choose a Wireless Network Note:

If you have not installed SP2 for Windows XP, the screen above will not be available. 3. Enter the key and click Connect to continue.

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A103 Wireless Adapter User Guide 4. If the connection is finished, you will see the screen as Figure 3-35 shows. Figure 3-34 Enter Network Key Figure 3-35 Connected

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A103 Wireless Adapter User Guide Chapter 4 AP Mode Right click the icon to switch to AP Mode. In this mode you can use the A103 as a soft AP. Figure 4-1 Note:

At this time, if your PC has Installed other network card (wireless or wired), you will be prompted ICS Select WAN Adapter to select one of them to be WAN. With this function A103 can serve as wireless router based on the selected card connecting to the Internet, which will make the APs of the LAN share the Internet. Figure 4-2 The configuration utility screen will then appear as shown in the figure below. By clicking the corresponding icon, you can configure the AP, make some advanced settings and view the APs status. The tools section shown in the following figure respectively stands for Config AP , Advanced

, Access Control List

, Associate List and About from the left to the right . Figure 4-3 4.1 Config AP Click the Config AP icon to load the following screen and set the AP as you need.

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Step 1. Click Config AP icon continue. A103 Wireless Adapter User Guide

, the following screen will pop up. Click Next icon to Figure 4-4 Config AP SSID - Enter the SSID of your soft AP, for example, you can name it My Network instead of the default name SoftAP-58. Step 2. Here you can select country region and set the APs channel. Figure 4-5 Channel - Select the channel from the drop-down list. This field determines which operating frequency will be used. Step 3. The APs authentication mode and encryption type can be set in the following figure. Step 4. Enter the Key in the empty field to make your AP security enabled (here takes 1234567890 for example). Only by entering the corresponding key can other computers Figure 4-6

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A103 Wireless Adapter User Guide establish a successful connection with your AP. Figure 4-7 4.2 Advanced Click the Advanced icon

, the following screen will appear. Here you can make some advanced settings and click Apply to make these settings take effect. Figure 4-8 Beacon Interval(ms)- Enter a value between 20-1000 milliseconds for Beacon Interval here. The beacons are the packets sent by the router to synchronize a wireless network. Beacon Interval value determines the time interval of the beacons. The default value is 100. TX Power - Manually force the APs transmitting power. System default is 100%. Idle Time - Manually force the Idle Time using a selected value. The default is 300. 4.3 Access Control List Click the Access Control List icon of the utility and the Access Control List screen will appear as Figure 4-9. In this page, you can enable/disable the AP to connect with the specified Mac address. Click Allow All, and enter the Mac address allowed to connect to your AP in the empty field beside MAC Address, and then click to add it to the list, shown in Figure 4-10. Highlight an existing Mac address in the list and click to remove it from the list as shown in Figure 4-11. When clicking

, you will clear all the Mac addresses in the Access Control List as Figure 4-12.

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A103 Wireless Adapter User Guide Figure 4-9 Access Control Function Access Policy - This field allows you to start the function or not. System default is disabled. Disable - Disable the Access Policy feature. Allow All - Allow all the MAC addresses in the Access List to access the AP. Reject All - Disable all the MAC addresses in the Access List to access the AP. Mac Address - Manually force the Mac address using the function. Apply - Click to make the settings take effect. Figure 4-10 Add an Mac Address to the List

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A103 Wireless Adapter User Guide Figure 4-11 Remove an existing Mac Address from the List Figure 4-12 Clear All MAC Addresses 4.4 Associate List Figure 4-13 shows the link status page. It displays detailed station information of current connection.

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A103 Wireless Adapter User Guide Figure 4-13 Mac Table Function MAC Address - The stations Mac address of the current connection. AID - Raise value by current connection. Power Saving Mode - Support Power Saving Mode on the currently connected station. Status - The link status of the current connection. 4.5 About The About page displays the wireless card and driver version information as shown in Figure 4-14. Figure 4-14 About Page

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A103 Wireless Adapter User Guide Chapter 5 Example for Application 5.1 Configuration of PSP XLink Online game Please ensure the software and hardware environments are well established before configuring. For hardware, at least a PC, a A103 Wireless Adapter and a PSP device are needed. For software, the A103 Adapter driver should be properly installed. Please operate as follows:

Step 1. Connect the website of X-LINK http://www.teamxlink.co.uk/ to register, and download the latest software of X-LINK Kai. Step 2. Install the X-LINK Kai software, click Start > All programs > XLink Kai > Configure Kai, then set as Figure 5-1. Figure 5-1 Step 3. After completing the settings, please click Start > All programs > XLink Kai > Start Kai to connect to XLink Kai. Step 4. Open the wireless mode of the PSP device, and then start an internet game.

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A103 Wireless Adapter User Guide Step 5. Right-click My Computer and select Management. In the prompt page, click Device Manager, then right-click Wireless N Client Adapter and select Properties. Then set the value of PSP Xlink Mode as Enable following the red marked instruction in the figure. Step 6. Click Start > Control Panel > Network. Figure 5-2 Figure 5-3 Step 7. Right-click Wireless Network Connection icon

, and select Properties. In the following prompt page, highlight Internet Protocol (TCP/IP) and click Properties.

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A103 Wireless Adapter User Guide Figure 5-4 Step 8. In the prompt page shown below, select Use the Following IP Address, and set the IP and Subnet mask. After completing setting, click OK. Figure 5-5 Note:

Please set the IP address in different network segment with the other network card to avoid conflict. Step 9. Launch RL52 Wireless N Client Utility, then highlight the Network Name (SSID) beginning with PSP in the Network page, and click Connect. Step 10. Check whether your PSP device is detected in the Diagnostics mode of Kai as Figure 5-6 shown: Click the icon first and then click the folder

.

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A103 Wireless Adapter User Guide Figure 5-6 Step 11. Click the icon on the right top corner to enter the Arena Mode, highlight the arena of your wanted game, and then join or start a new game. Figure 5-7

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A103 Wireless Adapter User Guide Appendix A: Glossary 802.11b - The 802.11b standard specifies a wireless networking at 11 Mbps using direct-sequence spread-spectrum (DSSS) technology and operating in the unlicensed radio spectrum at 2.4GHz, and WEP encryption for security. 802.11b networks are also referred to as Wi-Fi networks. 802.11g

- Specification for wireless networking at 54 Mbps using direct-sequence spread-spectrum (DSSS) technology, using OFDM modulation and operating in the unlicensed radio spectrum at 2.4GHz, and backward compatibility with IEEE 802.11b devices, and WEP encryption for security. 802.11n - 802.11n builds upon previous 802.11 standards by adding MIMO (multiple-input multiple-output). MIMO uses multiple transmitter and Hreceiver H antennas to allow for increased data throughput via spatial multiplexing and increased range by exploiting the spatial diversity, perhaps through coding schemes like Alamouti coding. The Enhanced Wireless Consortium

(EWC)H H was formed to help accelerate the IEEE 802.11n development process and promote a

[3]

technology specification for interoperability of next-generation wireless local area networking

(WLAN) products. Ad-hoc Network - An ad-hoc network is a group of computers, each with a wireless adapter, connected as an independent 802.11 wireless LAN. Ad-hoc wireless computers operate on a peer-to-peer basis, communicating directly with each other without the use of an access point. Ad-hoc mode is also referred to as an Independent Basic Service Set (IBSS) or as peer-to-peer mode, and is useful at a departmental scale or SOHO operation. DSSS (Direct-Sequence Spread Spectrum) - DSSS generates a redundant bit pattern for all data transmitted. This bit pattern is called a chip (or chipping code). Even if one or more bits in the chip are damaged during transmission, statistical techniques embedded in the receiver can recover the original data without the need for retransmission. To an unintended receiver, DSSS appears as low power wideband noise and is rejected (ignored) by most narrowband receivers. However, to an intended receiver (i.e. another wireless LAN endpoint), the DSSS signal is recognized as the only valid signal, and interference is inherently rejected (ignored). FHSS (Frequency Hopping Spread Spectrum) - FHSS continuously changes (hops) the carrier frequency of a conventional carrier several times per second according to a pseudo-random set of channels. Because a fixed frequency is not used, and only the transmitter and receiver know the hop patterns, interception of FHSS is extremely difficult. Infrastructure Network - An infrastructure network is a group of computers or other devices, each with a wireless adapter, connected as an 802.11 wireless LAN. In infrastructure mode, the wireless devices communicate with each other and to a wired network by first going through an access point. An infrastructure wireless network connected to a wired network is referred to as a Basic Service Set (BSS). A set of two or more BSS in a single network is referred to as an Extended Service Set (ESS). Infrastructure mode is useful at a corporation scale, or when it is necessary to connect the wired and wireless networks.

- 38 -

U U A103 Wireless Adapter User Guide Spread Spectrum - Spread Spectrum technology is a wideband radio frequency technique developed by the military for use in reliable, secure, mission-critical communications systems. It is designed to trade off bandwidth efficiency for reliability, integrity, and security. In other words, more bandwidth is consumed than in the case of narrowband transmission, but the trade off produces a signal that is, in effect, louder and thus easier to detect, provided that the receiver knows the parameters of the spread-spectrum signal being broadcast. If a receiver is not tuned to the right frequency, a spread-spectrum signal looks like background noise. There are two main alternatives, Direct Sequence Spread Spectrum (DSSS) and Frequency Hopping Spread Spectrum (FHSS). SSID - A Service Set Identification is a thirty-two character (maximum) alphanumeric key identifying a wireless local area network. For the wireless devices in a network to communicate with each other, all devices must be configured with the same SSID. This is typically the configuration parameter for a wireless PC card. It corresponds to the ESSID in the wireless Access Point and to the wireless network name. WEP (Wired Equivalent Privacy) - A data privacy mechanism based on a 64-bit or 128-bit shared key algorithm, as described in the IEEE 802.11 standard. Wi-Fi - A trade name for the 802.11b wireless networking standard, given by the Wireless Ethernet Compatibility Alliance (WECA, see http://www.wi-fi.net), an industry standards group promoting interoperability among 802.11b devices. WLAN (Wireless Local Area Network) - A group of computers and associated devices communicate with each other wirelessly, which network serving users are limited in a local area. WPA (Wi-Fi Protected Access) - A wireless security protocol use TKIP (Temporal Key Integrity Protocol) encryption, which can be used in conjunction with a RADIUS server.

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A103 Wireless Adapter User Guide Appendix B: Specifications General Interface USB 2.0 Connector Standards IEEE 802.11n, IEEE 802.11g, IEEE 802.11b Operating System Windows XP/ Vista/ 7 Safety & Emission FCC, CE Frequency 2.412 ~ 2.472 GHz (For CE Area) 2.412 ~ 2.462 GHz (For FCC Area) 130M: -68dBm Sensitivity 54M: -68dBm 11M: -85dBm Spread Spectrum Direct Sequence Spread Spectrum (DSSS) Wireless Radio Data Rate Up to 150Mbps Modulation 11n OFDM, 11g OFDM , 11b CCK/DSSS Media Access Protocol CSMA/CA with ACK Data Security WPA, 64/128 bits WEP, TKIP/AES, IEEE 802.1X authentication Physical Environmental Working Temperature 040 (32104) Storage Temperature

-4070 (-40158) Humidity 10%90% RH, Non-condensing

* Only 2.412GHz~2.462GHz is allowed to be used in USA, which means only channel 1~11 is available for American users to choose.

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CONSTRUCTION PHOTOS OF EUT Page 1 Page 2

 

 

1 2 3 4 5 6 7 8 9 A B C D E 19.129 5 7

. 4 5 0

. 1 2 5 3 5

. 0 7 17 8 3 3

. 6 1 5 6

. 3 1 5 3 5

. 0 7 24.282 24.282 LOGOPantone 8001C 1 2 3 4 5 6 7 8 9 OPPO A1 MU6 PW-DN427_3.0.0 2012-9-10 Pantone 8001C Pantone 8001C Pantone 8001C logo A B C D E

 

 

AGENCY AUTHORIZATION LETTER FCC ID: YTXA103 Date: August 12, 2012 Towhomitmayconcern:

We,theundersignedOPPODigital,lncherebyauthorizeBureauVeritasConsumer ProductsServices(H.K.)Ltd.,TaoyuanBranch(BVCPSTaoyuan)ofTaiwantoactonour behalf in all matters relating to all processes required in FCC approval and any communicationneededwiththenationalauthority.AnyandallactscarriedoutbyBV CPSTaoyuanonourbehalfshallhavethesameeffectsasactsofourown. Ifyouhaveanyquestionsregardingtheauthorization,pleasedonthesitateto contactus. Thankyou!

Sincerelyyours, Name of authorized signer: Jason J. Liao Title of authorized signer :CTO & VP of Product Development Company Name :OPPO Digital, Inc 2629 Terminal Blvd. Suite B Mountain View, CA 94043 Tel: 650-810-1619 Fax: 650-961-1119 Email: jason@oppodigital.com www.oppodigital.com OPPO Digital, Inc. 2629 Terminal Blvd, Suite B Mountain View CA 94043 Tel: (650) 961-1118 Fax: (650) 961-1119 www.oppodigital.com

 

 

August 21, 2012 FCC ID: YTXA103 Product Name: A103 To the attention of Federal Communications Commission AuthorizationandEvaluationDivision Request for Confidentiality Pursuant to Sections 0.457 and 0.459 of the Commissions Rules, the Applicant hereby requests confidential treatment of information accompanying this application as outlined below:

1. Block diagram 2. Schematics 3. Operation Description The above materials contain trade secrets and proprietary information not customarily released to the public. The public disclosure of these matters might to harmful to the applicant and provide unjustified benefits to its competitors. The applicant understands that pursuant to Rule 0.457, disclosure of this application and all accompanying documentation will not be made before the date of the grant for this application. Sincerelyyours, Jason J. Liao CTO & VP of Product Development OPPO Digital, Inc 2629 Terminal Blvd. Suite B Mountain View, CA 94043 Tel: 650-810-1619 Fax: 650-961-1119 Email: jason@oppodigital.com www.oppodigital.com OPPO Digital, Inc. 2629 Terminal Blvd, Suite B Mountain View CA 94043 Tel: (650) 961-1118 Fax: (650) 961-1119 www.oppodigital.com

 

 

Attestation for FCC Declaration of Conformity FCC ID: YTXA103 Date: August 20, 2012 Please be notified that we, the undersigned, OPPO Digital, Inc, declare that the product bears the above FCC ID is also complying with the requirements of FCC DoC. The test report number for FCC DoC is FD110701C18D , which is issued by an accredited lab, Bureau Veritas Consumer Products Services (H.K.) Ltd., Taoyuan Branch (BV CPS Taoyuan) of Taiwan. Which has been accredited in accordance to all of the requirements of 47CFR 2.948(d) and (e) of the FCC rules and KDB349827. Sincerely, Name of authorized signer: Jason J. Liao Title of authorized signer :CTO & VP of Product Development Company Name :OPPO Digital, Inc 2629 Terminal Blvd. Suite B Mountain View, CA 94043 Tel: 650-810-1619 Fax: 650-961-1119 Email: jason@oppodigital.com www.oppodigital.com OPPO Digital, Inc. 2629 Terminal Blvd, Suite B Mountain View CA 94043 Tel: (650) 961-1118 Fax: (650) 961-1119 www.oppodigital.com

 

 

TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 1 of 63 TESTING No. L2264 OET 65 TEST REPORT Product Name 150Mbps Wireless N USB Adapter Model FCC ID Client PW-DN427 WWMDN427V3 Proware Technologies Co Ltd. TA Technology (Shanghai) Co., Ltd. TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 2 of 63 GENERAL SUMMARY Product Name 150Mbps Wireless N USB Adapter Model PW-DN427 FCC ID Report No. Client WWMDN427V3 RXA1206-0418SAR01R1 Proware Technologies Co Ltd. Manufacturer Proware Technologies Co Ltd. IEEE Std C95.1, 1999: IEEE Standard for Safety Levels with Respect to Human Exposure to Radio Frequency Electromagnetic Fields, 3 kHz to 300 GHz. SUPPLEMENT C Edition 01-01 to OET BULLETIN 65 Edition 97-01 June 2001 including DA 02-1438, published June 2002: Evaluating Compliance with FCC Guidelines for Human Exposure to Radio frequency Electromagnetic Fields Additional Information for Evaluation Compliance of Mobile and Portable Devices with FCC Limits for Human Exposure to Radio frequency Emissions. KDB 248227 D01 SAR meas for 802 11 a b g v01r02: SAR Measurement Procedures for 802.11a/b/g Transmitters. KDB 447498 D02 SAR Procedures for Dongle Xmtr v02: SAR Measurement Procedures for USB Dongle Transmitters. This portable wireless equipment has been measured in all cases requested by the relevant standards. Test results in Chapter 7 of this test report are below limits specified in the relevant standards. General Judgment: Pass

(Stamp) Date of issue: August 3rd, 2012 Reference Standard(s) Conclusion Comment The test result only responds to the measured sample. Approved by Revised by Director SAR Manager Performed by SAR Engineer TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 3 of 63 TABLE OF CONTENT 1. General Information ........................................................................................................................ 4 1.1. Notes of the Test Report.......................................................................................................... 4 1.2. Testing Laboratory................................................................................................................... 4 1.3. Applicant Information ............................................................................................................... 5 1.4. Manufacturer Information......................................................................................................... 5 1.5. Information of EUT................................................................................................................... 6 1.6. The Maximum SAR1g Values ................................................................................................... 7 1.7. Test Date ................................................................................................................................. 7 2. SAR Measurements System Configuration..................................................................................... 8 2.1. SAR Measurement Set-up ....................................................................................................... 8 2.2. DASY5 E-field Probe System .................................................................................................. 9 2.2.1. EX3DV4 Probe Specification ............................................................................................ 9 2.2.2. E-field Probe Calibration................................................................................................. 10 2.3. Other Test Equipment ............................................................................................................ 10 2.3.1. Device Holder for Transmitters ....................................................................................... 10 2.3.2. Phantom ..........................................................................................................................11 2.4. Scanning Procedure .............................................................................................................. 11 2.5. Data Storage and Evaluation ................................................................................................. 13 2.5.1. Data Storage................................................................................................................... 13 2.5.2. Data Evaluation by SEMCAD ......................................................................................... 13 3. Laboratory Environment................................................................................................................ 15 4. Tissue-equivalent Liquid ............................................................................................................... 16 4.1. Tissue-equivalent Liquid Ingredients...................................................................................... 16 4.2. Tissue-equivalent Liquid Properties ....................................................................................... 16 5. System Check............................................................................................................................... 17 5.1. Description of System Check................................................................................................. 17 5.2. System Check........................................................................................................................ 18 6. Operational Conditions during Test ............................................................................................... 19 6.1. General Description of Test Procedures ................................................................................ 19 6.2. Position of Module in Portable Devices.................................................................................. 20 6.3. Picture of Host Product .......................................................................................................... 21 7. Test Results .................................................................................................................................. 22 7.1. Conducted Power Results ..................................................................................................... 22 7.2. SAR Test Results ................................................................................................................... 25 802.11b........................................................................................................................... 25 8. 300MHz to 3GHz Measurement Uncertainty................................................................................. 26 9. Main Test Instruments ................................................................................................................... 27 ANNEX A: Test Layout ......................................................................................................................... 28 ANNEX B: System Check Results ....................................................................................................... 29 ANNEX C: Graph Results .................................................................................................................... 30 ANNEX D: Probe Calibration Certificate .............................................................................................. 37 ANNEX E: D2450V2 Dipole Calibration Certificate .............................................................................. 48 ANNEX F: DAE4 Calibration Certificate ............................................................................................... 56 ANNEX G: The EUT Appearances and Test Configuration .................................................................. 61 7.2.1. TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 4 of 63 1. General Information 1.1. Notes of the Test Report TA Technology (Shanghai) Co., Ltd. guarantees the reliability of the data presented in this test report, which is the results of measurements and tests performed for the items under test on the date and under the conditions stated in this test report and is based on the knowledge and technical facilities available at TA Technology (Shanghai) Co., Ltd. at the time of execution of the test. TA Technology (Shanghai) Co., Ltd. is liable to the client for the maintenance by its personnel of the confidentiality of all information related to the items under test and the results of the test. This report only refers to the item that has undergone the test. This report standalone dose not constitute or imply by its own an approval of the product by the certification Bodies or competent Authorities. This report cannot be used partially or in full for publicity and/or promotional purposes without previous written approval of TA Technology (Shanghai) Co., Ltd. and the Accreditation Bodies, if it applies. If the electrical report is inconsistent with the printed one, it should be subject to the latter. 1.2. Testing Laboratory Company:

TA Technology (Shanghai) Co., Ltd. Address:

No.145, Jintang Rd, Tangzhen Industry Park, Pudong City:

Post code:

Country:

Shanghai 201201 P. R. China Contact:

Yang Weizhong Telephone:

+86-021-50791141/2/3

+86-021-50791141/2/3-8000 http://www.ta-shanghai.com yangweizhong@ta-shanghai.com Fax:

Website:

E-mail:

TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 5 of 63 1.3. Applicant Information Company:

Address:

City:

Proware Technologies Co Ltd. 2nd F1 East Wing,South Section,Factory Building 24,Science&Technology Park,Shennan Rd,Nanshan District,Shenzhen Shenzhen Postal Code:

518057 Country:

China 1.4. Manufacturer Information Company:

Address:

City:

Proware Technologies Co Ltd. 2nd F1 East Wing,South Section,Factory Building 24,Science&Technology Park,Shennan Rd,Nanshan District,Shenzhen Shenzhen Postal Code:

518057 Country:

China TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 6 of 63 1.5. Information of EUT General Information Device Type:

Portable Device Exposure Category:

Uncontrolled Environment / General Population State of Sample:

Product Name:

SN:

Hardware Version:

Software Version:

Antenna Type:

Prototype Unit 150Mbps Wireless N USB Adapter

/

3.0

/

Internal Antenna Device Operating Configurations:

Supporting Mode(s):

802.11b; (tested) 802.11g/n HT20/HT40; (untested) Mode Tx (MHz) Operating Frequency Range(s):

802.11b/g/n HT20 2412 ~ 2462MHz Test Channel:

(Low - Middle - High) Used Host Products:

802.11n HT40 2422 ~ 2452MHz 1-6-11 (802.11b/g/n HT20) 3-6-9 (802.11n HT40) IBM T61 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 7 of 63 Equipment Under Test (EUT) is 150Mbps Wireless N USB Adapter. During SAR test of the EUT, it was connected to a portable computer. SAR is tested for 802.11b in this report. SAR is not required for 802.11g/n when the maximum average output power is less than 0.25dB higher than that measured on the corresponding 802.11b channels. The EUT has a WiFi antenna that is used for Tx/Rx. The sample undergoing test was selected by the Client. Components list please refer to documents of the manufacturer. 1.6. The Maximum SAR1g Values Body SAR Configuration Channel Position Separation distance SAR1g (W/kg) Low/1 Test Position 1 5mm 0.435 Mode 802.11b 1.7. Test Date The test performed on June 21, 2012. TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 8 of 63 2. SAR Measurements System Configuration 2.1. SAR Measurement Set-up The DASY5 system for performing compliance tests consists of the following items:

(cid:122) A standard high precision 6-axis robot (Stubli RX family) with controller and software. An arm extension for accommodating the data acquisition electronics (DAE).

(cid:122) A dosimetric probe, i.e. an isotropic E-field probe optimized and calibrated for usage in tissue simulating liquid. The probe is equipped with an optical surface detector system.

(cid:122) A data acquisition electronic (DAE) which performs the signal amplification, signal multiplexing, AD-conversion, offset measurements, mechanical surface detection, collision detection, etc. The unit is battery powered with standard or rechargeable batteries. The signal is optically transmitted to the EOC.

(cid:122) A unit to operate the optical surface detector which is connected to the EOC.

(cid:122) The Electro-Optical Coupler (EOC) performs the conversion from the optical into a digital electric signal of the DAE. The EOC is connected to the DASY5 measurement server.

(cid:122) The DASY5 measurement server, which performs all real-time data evaluation for field measurements and surface detection, controls robot movements and handles safety operation. A computer operating Windows 2003

(cid:122) DASY5 software and SEMCAD data evaluation software.

(cid:122) Remote control with teach panel and additional circuitry for robot safety such as warning lamps, etc.

(cid:122) The generic twin phantom enabling the testing of left-hand and right-hand usage.

(cid:122) The device holder for handheld mobile phones.

(cid:122) Tissue simulating liquid mixed according to the given recipes.

(cid:122) System validation dipoles allowing to validate the proper functioning of the system. Figure 1. SAR Lab Test Measurement Set-up TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 9 of 63 2.2. DASY5 E-field Probe System The SAR measurements were conducted with the dosimetric probe EX3DV4 (manufactured by SPEAG), designed in the classical triangular configuration and optimized for dosimetric evaluation. 2.2.1. EX3DV4 Probe Specification Construction Symmetrical design with triangular core Built-in shielding against static charges PEEK enclosure material (resistant to organic solvents, e.g., DGBE) Calibration ISO/IEC 17025 calibration service available Frequency 10 MHz to > 6 GHz Linearity: 0.2 dB

(30 MHz to 6 GHz) Directivity Dynamic Range 0.3 dB in HSL (rotation around probe axis) 0.5 dB in tissue material (rotation normal to probe axis) Figure 2.EX3DV4 E-field Probe 10 W/g to > 100 mW/g Linearity:

0.2dB (noise: typically < 1 W/g) Dimensions Overall length: 330 mm (Tip: 20 mm) Tip diameter: 2.5 mm (Body: 12 mm) Typical distance from probe tip to dipole centers:

1 mm Application High precision dosimetric measurements in any exposure scenario (e.g., very strong gradient fields). Only probe which enables compliance testing for frequencies up to 6 GHz with precision of better 30%. Figure 3. EX3DV4 E-field probe TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 10 of 63 2.2.2. E-field Probe Calibration Each probe is calibrated according to a dosimetric assessment procedure with accuracy better than 10%. The spherical isotropy was evaluated and found to be better than 0.25dB. The sensitivity parameters (NormX, NormY, NormZ), the diode compression parameter (DCP) and the conversion factor (ConvF) of the probe are tested. The free space E-field from amplified probe outputs is determined in a test chamber. This is performed in a TEM cell for frequencies bellow 1 GHz, and in a wave guide above 1 GHz for free space. For the free space calibration, the probe is placed in the volumetric center of the cavity and at the proper orientation with the field. The probe is then rotated 360 degrees. E-field temperature correlation calibration is performed in a flat phantom filled with the appropriate simulated brain tissue. The measured free space E-field in the medium correlates to temperature rise in a dielectric medium. For temperature correlation calibration a RF transparent thermistor-based temperature probe is used in conjunction with the E-field probe. Where: t = Exposure time (30 seconds), C = Heat capacity of tissue (brain or muscle), T = Temperature increase due to RF exposure. Or Where:

= Simulated tissue conductivity,

= Tissue density (kg/m3). 2.3. Other Test Equipment 2.3.1. Device Holder for Transmitters Construction: Simple but effective and easy-to-use extension for Mounting Device that facilitates the testing of larger devices according to IEC 62209-2 (e.g., laptops, cameras, etc.) It is lightweight and fits easily on the upper part of the Mounting Device in place of the phone positioner. The extension is fully compatible with the Twin SAM, ELI4 and SAM v6.0 Phantoms. Material: POM, Acrylic glass, Foam TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 11 of 63 2.3.2. Phantom The Generic Twin Phantom is constructed of a fiberglass shell integrated in a wooden Figure. The shape of the shell is based on data from an anatomical study designed to determine the maximum exposure in at least 90% of all users. It enables the dosimetric evaluation of left and right hand phone usage as well as body mounted usage at the flat phantom region. A cover prevents the evaporation of the liquid. Reference markings on the Phantom allow the complete setup of all predefined phantom positions and measurement grids by manually teaching three points in the robot. Shell Thickness 20.1 mm Filling Volume Approx. 20 liters Dimensions 810 x l000 x 500 mm (H x L x W) Aailable Special Figure 4 Generic Twin Phantom 2.4. Scanning Procedure The DASY5 installation includes predefined files with recommended procedures for measurements and validation. They are read-only document files and destined as fully defined but unmeasured masks. All test positions (head or body-worn) are tested with the same configuration of test steps differing only in the grid definition for the different test positions.

(cid:122) The reference and drift measurements are located at the beginning and end of the batch process. They measure the field drift at one single point in the liquid over the complete procedure. The indicated drift is mainly the variation of the DUTs output power and should vary max. 5 %.

(cid:122) The surface check measurement tests the optical surface detection system of the DASY5 system by repeatedly detecting the surface with the optical and mechanical surface detector and comparing the results. The output gives the detecting heights of both systems, the difference between the two systems and the standard deviation of the detection repeatability. Air bubbles or refraction in the liquid due to separation of the sugar-water mixture gives poor repeatability (above 0.1mm). To prevent wrong results tests are only executed when the liquid is free of air bubbles. The difference between the optical surface detection and the actual surface depends on the probe and is specified with each probe. (It does not depend on the surface reflectivity or the probe angle to the surface within 30.)

(cid:122) Area Scan The Area Scan is used as a fast scan in two dimensions to find the area of high field values before running a detailed measurement around the hot spot.Before starting the area scan a grid spacing of 10 mm x 10 mm is set. During the scan the distance of the probe to the phantom remains TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 12 of 63 unchanged. After finishing area scan, the field maxima within a range of 2 dB will be ascertained.

(cid:122) Zoom Scan Zoom Scans are used to estimate the peak spatial SAR values within a cubic averaging volume containing 1 g and 10 g of simulated tissue. The default Zoom Scan is done by 7x7x7 points within a cube whose base is centered around the maxima found in the preceding area scan.

(cid:122) Spatial Peak Detection The procedure for spatial peak SAR evaluation has been implemented and can determine values of masses of 1g and 10g, as well as for user-specific masses.The DASY5 system allows evaluations that combine measured data and robot positions, such as:

maximum search extrapolation boundary correction peak search for averaged SAR During a maximum search, global and local maxima searches are automatically performed in 2-D after each Area Scan measurement with at least 6 measurement points. It is based on the evaluation of the local SAR gradient calculated by the Quadratic Shepards method. The algorithm will find the global maximum and all local maxima within -2 dB of the global maxima for all SAR distributions. Extrapolation routines are used to obtain SAR values between the lowest measurement points and the inner phantom surface. The extrapolation distance is determined by the surface detection distance and the probe sensor offset. Several measurements at different distances are necessary for the extrapolation. Extrapolation routines require at least 10 measurement points in 3-D space. They are used in the Zoom Scan to obtain SAR values between the lowest measurement points and the inner phantom surface. The routine uses the modified Quadratic Shepards method for extrapolation. For a grid using 7x7x7 measurement points with 5mm resolution amounting to 343 measurement points, the uncertainty of the extrapolation routines is less than 1% for 1g and 10g cubes.

(cid:122) A Z-axis scan measures the total SAR value at the x-and y-position of the maximum SAR value found during the cube 7x7x7 scan. The probe is moved away in z-direction from the bottom of the SAM phantom in 5mm steps. TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 13 of 63 2.5. Data Storage and Evaluation 2.5.1. Data Storage The DASY5 software stores the acquired data from the data acquisition electronics as raw data (in microvolt readings from the probe sensors), together with all necessary software parameters for the data evaluation (probe calibration data, liquid parameters and device frequency and modulation data) in measurement files with the extension .DAE4. The software evaluates the desired unit and format for output each time the data is visualized or exported. This allows verification of the complete software setup even after the measurement and allows correction of incorrect parameter settings. For example, if a measurement has been performed with a wrong crest factor parameter in the device setup, the parameter can be corrected afterwards and the data can be re-evaluated. The measured data can be visualized or exported in different units or formats, depending on the selected probe type ([V/m], [A/m], [C], [mW/g], [mW/cm], [dBrel], etc.). Some of these units are not available in certain situations or show meaningless results, e.g., a SAR output in a lossless media will always be zero. Raw data can also be exported to perform the evaluation with other software packages. 2.5.2. Data Evaluation by SEMCAD The SEMCAD software automatically executes the following procedures to calculate the field units from the microvolt readings at the probe connector. The parameters used in the evaluation are stored in the configuration modules of the software:

Probe parameters: - Sensitivity Normi, ai0, ai1, ai2

- Conversion factor ConvFi

- Diode compression point Dcpi Device parameters: - Frequency f

- Crest factor cf Media parameters: - Conductivity

- Density These parameters must be set correctly in the software. They can be found in the component documents or they can be imported into the software from the configuration files issued for the DASY5 components. In the direct measuring mode of the multimeter option, the parameters of the actual system setup are used. In the scan visualization and export modes, the parameters stored in the corresponding document files are used. The first step of the evaluation is a linearization of the filtered input signal to account for the compression characteristics of the detector diode. The compensation depends on the input signal, the diode type and the DC-transmission factor from the diode to the evaluation electronics. TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 14 of 63 If the exciting field is pulsed, the crest factor of the signal must be known to correctly compensate for peak power. The formula for each channel can be given as:

Vi = Ui + Ui 2 c f / d c pi With Vi = compensated signal of channel i ( i = x, y, z ) Ui = input signal of channel i ( i = x, y, z ) cf = crest factor of exciting field (DASY parameter) dcpi = diode compression point (DASY parameter) From the compensated input signals the primary field data for each channel can be evaluated:

E-field probes: Ei = ( Vi / Normi ConvF )1/2 H-field probes: Hi = ( Vi )1/2 ( ai0 + ai1 f + ai2f2 ) / f With Vi = compensated signal of channel i (i = x, y, z) Normi = sensor sensitivity of channel i (i = x, y, z)

[mV/(V/m)2] for E-field Probes ConvF = sensitivity enhancement in solution aij = sensor sensitivity factors for H-field probes f = carrier frequency [GHz]

Ei = electric field strength of channel i in V/m Hi = magnetic field strength of channel i in A/m The RSS value of the field components gives the total field strength (Hermitian magnitude):

Etot = (Ex 2+ EY 2+ Ez 2)1/2 The primary field data are used to calculate the derived field units. SAR = (Etot) 2 / ( 1000) with SAR = local specific absorption rate in mW/g TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 15 of 63 Etot = total field strength in V/m

= conductivity in [mho/m] or [Siemens/m]

= equivalent tissue density in g/cm3 Note that the density is normally set to 1 (or 1.06), to account for actual brain density rather than the density of the simulation liquid. The power flow density is calculated assuming the excitation field to be a free space field. Ppwe = Etot 2 / 3770 or Ppwe = Htot 2 37.7 with Ppwe = equivalent power density of a plane wave in mW/cm2 Etot = total electric field strength in V/m Htot = total magnetic field strength in A/m 3. Laboratory Environment Table 1: The Requirements of the Ambient Conditions Temperature Relative humidity Ground system resistance Ambient noise is checked and found very low and in compliance with requirement of standards. Reflection of surrounding objects is minimized and in compliance with requirement of standards. Min. = 18C, Max. = 25 C Min. = 30%, Max. = 70%

< 0.5 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 16 of 63 4. Tissue-equivalent Liquid 4.1. Tissue-equivalent Liquid Ingredients The liquid is consisted of water, sugar, salt, Glycol monobutyl, Preventol and Cellulose. The liquid has previously been proven to be suited for worst-case. The Table 2 shows the detail solution. Its satisfying the latest tissue dielectric parameters requirements proposed by OET 65. Table 2: Composition of the Body Tissue Equivalent Matter MIXTURE%

Water Glycol Salt Dielectric Parameters Target Value FREQUENCY(Body) 2450MHz 73.2 26.7 0.1 f=2450MHz =52.70 =1.95 4.2. Tissue-equivalent Liquid Properties Table 3: Dielectric Performance of Tissue Simulating Liquid Frequency Description Target value 5% window Measurement value 2011-6-21 2450MHz

(body) Dielectric Parameters r 52.70

(s/m) 1.95 50.07 55.34 1.85 2.05 51.7 1.9 Temp

/

21.5 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 17 of 63 5. System Check 5.1. Description of System Check The manufacturer calibrates the probes annually. Dielectric parameters of the tissue simulants were measured every day using the dielectric probe kit and the network analyzer. A system check measurement was made following the determination of the dielectric parameters of the simulant, using the dipole validation kit. A power level of 250 mW was supplied to the dipole antenna, which was placed under the flat section of the twin SAM phantom. The system check results (dielectric parameters and SAR values) are given in the Table 4. System check results have to be equal or near the values determined during dipole calibration with the relevant liquids and test system (10 %). System check is performed regularly on all frequency bands where tests are performed with the DASY5 system. Figure 5. System Check Set-up TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 18 of 63 5.2. System Check Table 4: System Check for Body Tissue Simulating Liquid Frequency Test Date Dielectric Parameters Temp r

(s/m)

() 2450MHz 2012-6-21 51.7 1.9 21.5 12.9 Note1. The graph results see ANNEX B. 2. Target Values derive from the calibration certificate 250mW Measured SAR1g 1W 1W Normalized SAR1g Target SAR1g

(10% deviation)

(W/kg) 51.6 51.70

(46.53~56.87) TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 19 of 63 6. Operational Conditions during Test 6.1. General Description of Test Procedures For WLAN SAR testing, WLAN engineering testing software installed on the DUT can provide continuous transmitting RF signal. This RF signal utilized in SAR measurement has almost 100% duty cycle and its crest factor is 1. For the 802.11b/g SAR body tests, a communication link is set up with the test mode software for WIFI mode test. The Absolute Radio Frequency Channel Number (ARFCN) is allocated to 1, 6 and 11 respectively in the case of 2450 MHz. During the test, at the each test frequency channel, the EUT is operated at the RF continuous emission mode. Each channel should be tested at the lowest data rate. Testing at higher data rates is not required when the maximum average output power is less than 0.25dB higher than those measured at the lowest data rate. 802.11b/g operating modes are tested independently according to the service requirements in each frequency band. 802.11b/g modes are tested on channels 1,6 and 11; however, if output power reduction is necessary for channels 1 and /or 11 to meet restricted band requirements the highest output channels closest to each of these channels must be tested instead. SAR is not required for 802.11g channels when the maximum average output power is less than 0.25dB higher than that measured on the corresponding 802.11b channels. When the maximum average output channel in each frequency band is not included in the default test channels, the maximum channel should be tested instead of an adjacent default test channels, these are referred to as the required test channels and are illustrated in Table 5. Table 5: Default Test Channels Mode GHz Channel 802.11b/g 2.412 2.437 2.462 1#

6 11#

Turbo Channel 6 Default Test Channels 15.247 802.11b 802.11g UNII

*

*

*

Note: #=when output power is reduced for channel 1 and /or 11to meet restricted band requirements the highest out put channels closet to each of these channels should be tested.

= default test channels

* =possible 802.11g channels with maximum average output 0.25dB>=the default test channels TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 20 of 63 6.2. Position of Module in Portable Devices The measurements were performed in combination with a host product (IBM T61). IBM T61 laptop has horizontal USB slot and vertical USB slot. A test distance of 5mm or less, according to KDB 447498 D02, should be considered for the orientation that can satisfy such requirements. For each channel, the EUT is tested at the following 4 test positions:

Test Position 1: The EUT is connected to the portable computer with horizontal USB slot. The back side of the EUT towards the bottom of the flat phantom. The distance from back side of the EUT to the bottom of the flat phantom is 5mm. (ANNEX G Picture 5) Test Position 2: The EUT is connected to the portable computer through a 19 cm USB cable. The front side of the EUT towards the bottom of the flat phantom. The distance from front side of the EUT to the bottom of the flat phantom is 5mm. (ANNEX G Picture 6) Test Position 3: The EUT is connected to the portable computer through a 19 cm USB cable. The left side of the EUT towards the bottom of the flat phantom. The distance from left side of the EUT to the bottom of the flat phantom is 5mm. (ANNEX G Picture 7) Test Position 4: The EUT is connected to the portable computer with vertical USB slot. The right side of the EUT towards the bottom of the flat phantom. The distance from right side of the EUT to the bottom of the flat phantom is 5mm. (ANNEX G Picture 8) TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 21 of 63 6.3. Picture of Host Product During the test, IBM T61 laptop was used as an assistant to help to setup communication. (See Picture 1) Picture 1-a: IBM T61 Close Picture 1-b: IBM T61 Open Picture 1-e: IBM T61 with horizontal USB slot Picture 1-f: IBM T61 with Vertical USB slot Picture 1-g: a 19 cm USB cable Picture 1: Computer as a test assistant TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 22 of 63 7. Test Results 6 1 11 11b Mode Channel 7.1. Conducted Power Results Table 6: Conducted Power Measurement Results Data rate 1 Mbps 2 Mbps 5.5 Mbps 11 Mbps 1 Mbps 2 Mbps 5.5 Mbps 11 Mbps 1 Mbps 2 Mbps 5.5 Mbps 11 Mbps 6 Mbps 9 Mbps 12 Mbps 18 Mbps 24 Mbps 36 Mbps 48 Mbps 54 Mbps 6 Mbps 9 Mbps 12 Mbps 18 Mbps 24 Mbps 36 Mbps 48 Mbps 54 Mbps 6 Mbps 11g 11 1 6 AV Power (dBm) PK Power (dBm) 17.23 17.32 17.25 17.22 17.07 17.06 17.10 17.00 16.87 16.76 16.81 16.73 16.68 16.61 16.66 16.85 14.81 15.31 13.07 12.94 16.72 16.69 16.66 16.79 14.92 14.97 13.09 13.34 16.37 19.4 19.84 19.33 19.48 18.47 18.34 18.13 18.29 18.23 18.30 18.20 18.43 25.12 25.03 25.46 25.10 24.38 24.21 22.86 23.80 24.08 23.88 24.54 24.06 23.51 23.17 21.70 22.74 24.53 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 23 of 63 9 Mbps 12 Mbps 18 Mbps 24 Mbps 36 Mbps 48 Mbps 54 Mbps 13.5 MCS 0 27 MCS 1 40.5 MCS 2 54 MCS 3 81 MCS 4 108 MCS 5 121.5 MCS 6 135 MCS 7 13.5 MCS 0 27 MCS 1 40.5 MCS 2 54 MCS 3 81 MCS 4 108 MCS 5 121.5 MCS 6 135 MCS 7 13.5 MCS 0 27 MCS 1 40.5 MCS 2 54 MCS 3 81 MCS 4 108 MCS 5 121.5 MCS 6 135 MCS 7 13.5 MCS 0 27 MCS 1 40.5 MCS 2 54 MCS 3 16.41 16.39 16.55 14.71 14.64 12.71 12.75 16.94 16.87 17.14 17.12 15.21 15.33 13.39 13.28 17.36 16.96 17.05 17.04 15.22 15.29 13.13 13.32 16.82 16.67 16.78 16.85 14.91 15.05 12.97 13.10 16.82 16.72 16.67 16.66 23.87 24.43 23.96 23.24 23.15 21.79 22.88 24.89 25.12 24.98 24.83 24.02 23.69 23.06 22.55 23.77 24.19 23.99 24.01 22.94 22.74 22.16 21.67 23.68 24.14 23.85 23.99 23.26 22.81 22.24 21.85 25.54 24.52 24.16 24.49 1 11n HT20 6 11 11n HT40 3 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 24 of 63 81 MCS 4 108 MCS 5 121.5 MCS 6 135 MCS 7 13.5 MCS 0 27 MCS 1 40.5 MCS 2 54 MCS 3 81 MCS 4 108 MCS 5 121.5 MCS 6 135 MCS 7 13.5 MCS 0 27 MCS 1 40.5 MCS 2 54 MCS 3 81 MCS 4 108 MCS 5 121.5 MCS 6 135 MCS 7 14.87 14.77 12.87 12.83 16.63 16.62 16.54 16.62 14.70 14.73 12.84 12.78 16.32 16.3 16.28 16.34 14.4 14.43 12.45 12.37 23.65 23.89 22.76 22.46 24.24 24.18 23.89 24.06 23.02 23.59 22.97 22.13 24.32 24.04 23.75 23.93 23.04 23.38 22.46 22.15 6 9 Note: 1. KDB 248227-SAR is not required for 802.11g/n channels when the maximum average output power is less than dB higher than measured on the corresponding 802.11b channels. TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 25 of 63 7.2. SAR Test Results 7.2.1. 802.11b Table 7: SAR Values (802.11b) Limit of SAR 10 g Average 1g Average Power Drift 2.0 W/kg 1.6 W/kg 0.21 dB Test Case Of Body Measurement Result (W/kg) Different Test Position Channel 10 g Average 1 g Average Power Drift

(dB) IBM T61 High/11 Test Position 1 Middle/6 Test Position 2 Test Position 3 Test Position 4 Low/1 Low/1 Low/1 Low/1 0.125 0.165 0.211 0.196 0.187 0.071 0.250 0.325 0.435 0.371 0.351 0.117

-0.146 0.128 0.046 0.181

-0.549 0.086 Graph Results Figure 7 Figure 8 Figure 9 Figure 10 Figure 11 Figure 12 Note: 1.The value with blue color is the maximum SAR Value of each test band. 2. SAR test at the channel with maximum averaged output power, if the SAR value is at least 3.0 dB lower than the SAR limit (< 0.8W/kg), testing at the other channels is optional. 3. Other channels were measured at the worst case. 4. KDB 248227-SAR is not required for 802.11 g/n channels when the maximum average output power is less than dB higher than measured on the corresponding 802.11b channels. Standard ncertainty iu (%)

'

Degree of freedom Veff or vi TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 26 of 63 8. 300MHz to 3GHz Measurement Uncertainty No. source Type Uncertainty Value (%) Probability Distribution 1 2 3 4 6 7 8 9 System repetivity

-probe calibration

-axial isotropy of the probe

- Hemispherical isotropy of the probe

-boundary effect

-probe linearity

- System detection limits

-readout Electronics 10

-response time 11

-integration time 12

-noise 13

-RF Ambient Conditions 14

-Probe Positioner Mechanical Tolerance 15 16 17 18 19

-Probe Positioning with respect to Phantom Shell

-Extrapolation, interpolation and Integration Algorithms for Max. SAR Evaluation

-Test Sample Positioning

-Device Holder Uncertainty

-Output Power Variation measurement

- SAR drift 20

-phantom 21

-liquid conductivity (deviation from target) A 0.5 Measurement system B B B B B B B B B B B B B B A A B B B 6.0 4.7 9.4 1.9 4.7 1.0 1.0 0 4.32 0 3 0.4 2.9 3.9 Test sample Related 2.9 4.1 5.0 Physical parameter 4.0 5.0 N N R R R R R N R R R R R R R N N R R R k 1 1 3 3 3 3 3 1 3 3 3 3 3 3 3 1 1 3 3 3 ci 1 1 5.0 5.0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0.5 6.0 1.9 3.9 1.1 2.7 0.6 1.0 0 2.5 0 1.73 0.2 1.7 2.3 2.9 4.1 2.9 2.3 0.64 1.8 9 71 5 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 27 of 63 N R N N 1 3 1 0.64 1.6 0.6 1.7 0.6 1.5 11.50 k=2 23.00 9 9 22 conductivity

-liquid uncertainty)

(measurement 23

-liquid permittivity (deviation from target) 24

-liquid uncertainty ) permittivity

(measurement Combined standard uncertainty B B B u

'

c

=

2.5 5.0 2.5 uc 2 i 2 i 21 i 1

=

Expanded uncertainty (confidence interval of 95 %) u e u 2=

c 9. Main Test Instruments Table 8: List of Main Instruments No. Name Type Serial Number Calibration Date Valid Period 01 02 03 04 05 06 Network analyzer Agilent 8753E US37390326 September 12, 2011 One year Dielectric Probe Kit Agilent 85070E US44020115 No Calibration Requested Power meter Agilent E4417A GB41291714 March 11, 2012 One year Power sensor Agilent N8481H MY50350004 September 25, 2011 One year Power sensor E9327A US40441622 September 24, 2011 One year Signal Generator HP 8341B 2730A00804 September 12, 2011 One year 07 Dual directional coupler 777D 50146 August 21, 2011 One year 08 09 10 Amplifier E-field Probe DAE IXA-020 EX3DV4 DAE4 11 Validation Kit 2450MHz D2450V2 0401 3753 1291 786 Temperature Probe Hygrothermograph JM222 WS-1 12 13 No Calibration Requested January 4, 2012 One year October 10, 2011 One year August 29, 2011 One year One year AA1009129 March 15, 2012 64591 September 28, 2011 One year

***END OF REPORT BODY***

TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 28 of 63 ANNEX A: Test Layout Picture 2: Specific Absorption Rate Test Layout Picture 3: Liquid depth in the flat Phantom (2450 MHz, 15.2cm depth) TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 29 of 63 ANNEX B: System Check Results System Performance Check at 2450 MHz DUT: Dipole 2450 MHz; Type: D2450V2; Serial: D2450V2 - SN: 786 Date/Time: 6/21/2012 12:19:59 PM Communication System: CW; Frequency: 2450 MHz;Duty Cycle: 1:1 Medium parameters used: f = 2450 MHz; = 1.9 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 d=10mm, Pin=250mW/Area Scan (41x71x1): Measurement grid: dx=15mm, dy=15mm Maximum value of SAR (interpolated) = 16 mW/g d=10mm, Pin=250mW/Zoom Scan (7x7x7) /Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 81.2 V/m; Power Drift = 0.076 dB Peak SAR (extrapolated) = 25.4 W/kg SAR(1 g) = 12.9 mW/g; SAR(10 g) = 6.13 mW/g Maximum value of SAR (measured) = 14.9 mW/g Figure 6 System Performance Check 2450MHz 250mW TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 30 of 63 ANNEX C: Graph Results 802.11b with IBM T61 Test Position 1 High Date/Time: 6/21/2012 5:33:24 PM Communication System: 802.11b; Frequency: 2462 MHz;Duty Cycle: 1:1 Medium parameters used: f = 2462 MHz; = 1.92 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 Test Position 1 High/Area Scan (31x61x1): Measurement grid: dx=10mm, dy=10mm Maximum value of SAR (interpolated) = 0.288 mW/g Test Position 1 High/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 9.66 V/m; Power Drift = -0.146 dB Peak SAR (extrapolated) = 0.490 W/kg SAR(1 g) = 0.250 mW/g; SAR(10 g) = 0.125 mW/g Maximum value of SAR (measured) = 0.272 mW/g Figure 7 802.11b with IBM T61 Test Position 1 Channel 11 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 31 of 63 802.11b with IBM T61 Test Position 1 Middle Date/Time: 6/21/2012 5:01:26 PM Communication System: 802.11b; Frequency: 2437 MHz;Duty Cycle: 1:1 Medium parameters used (interpolated): f = 2437 MHz; = 1.88 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 Test Position 1 Middle/Area Scan (31x61x1): Measurement grid: dx=10mm, dy=10mm Maximum value of SAR (interpolated) = 0.419 mW/g Test Position 1 Middle/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 12.1 V/m; Power Drift = 0.128 dB Peak SAR (extrapolated) = 0.621 W/kg SAR(1 g) = 0.325 mW/g; SAR(10 g) = 0.165 mW/g Maximum value of SAR (measured) = 0.358 mW/g Figure 8 802.11b with IBM T61 Test Position 1 Channel 6 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 32 of 63 802.11b with IBM T61 Test Position 1 Low Date/Time: 6/21/2012 3:11:36 PM Communication System: 802.11b; Frequency: 2412 MHz;Duty Cycle: 1:1 Medium parameters used: f = 2412 MHz; = 1.85 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 Test Position 1 Low/Area Scan (31x61x1): Measurement grid: dx=10mm, dy=10mm Maximum value of SAR (interpolated) = 0.515 mW/g Test Position 1 Low/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 12.7 V/m; Power Drift = 0.046 dB Peak SAR (extrapolated) = 0.847 W/kg SAR(1 g) = 0.435 mW/g; SAR(10 g) = 0.211 mW/g Maximum value of SAR (measured) = 0.472 mW/g USB Plug TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 33 of 63 Figure 9 802.11b with IBM T61 Test Position 1 Channel 1 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 34 of 63 802.11b with IBM T61 Test Position 2 Low Date/Time: 6/21/2012 4:36:13 PM Communication System: 802.11b; Frequency: 2412 MHz;Duty Cycle: 1:1 Medium parameters used: f = 2412 MHz; = 1.85 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 Test Position 2 Low/Area Scan (31x61x1): Measurement grid: dx=10mm, dy=10mm Maximum value of SAR (interpolated) = 0.439 mW/g Test Position 2 Low/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 10.9 V/m; Power Drift = 0.181 dB Peak SAR (extrapolated) = 0.642 W/kg SAR(1 g) = 0.371 mW/g; SAR(10 g) = 0.196 mW/g Maximum value of SAR (measured) = 0.420 mW/g Figure 10 802.11b with IBM T61 Test Position 2 Channel 1 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 35 of 63 802.11b with IBM T61 Test Position 3 Low Date/Time: 6/21/2012 4:11:27 PM Communication System: 802.11b; Frequency: 2412 MHz;Duty Cycle: 1:1 Medium parameters used: f = 2412 MHz; = 1.85 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 Test Position 3 Low/Area Scan (31x61x1): Measurement grid: dx=10mm, dy=10mm Maximum value of SAR (interpolated) = 0.483 mW/g Test Position 3 Low/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 12.5 V/m; Power Drift = -0.049 dB Peak SAR (extrapolated) = 0.619 W/kg SAR(1 g) = 0.351 mW/g; SAR(10 g) = 0.187 mW/g Maximum value of SAR (measured) = 0.391 mW/g Figure 11 802.11b with IBM T61 Test Position 3 Channel 1 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 36 of 63 802.11b with IBM T61 Test Position 4 Low Date/Time: 6/21/2012 3:37:36 PM Communication System: 802.11b; Frequency: 2412 MHz;Duty Cycle: 1:1 Medium parameters used: f = 2412 MHz; = 1.85 mho/m; r = 51.7; = 1000 kg/m3 Ambient Temperature:22.3 Liquid Temperature: 21.5 Phantom section: Flat Section DASY5 Configuration:

Probe: EX3DV4 - SN3753; ConvF(7.03, 7.03, 7.03); Calibrated: 1/4/2012 Electronics: DAE4 Sn1291; Calibrated: 10/10/2011 Phantom: SAM2; Type: SAM; Serial: TP-1524 Measurement SW: DASY5, V5.2 Build 162; SEMCAD X Version 14.0 Build 59 Test Position 4 Low/Area Scan (31x61x1): Measurement grid: dx=10mm, dy=10mm Maximum value of SAR (interpolated) = 0.166 mW/g Test Position 4 Low/Zoom Scan (7x7x7)/Cube 0: Measurement grid: dx=5mm, dy=5mm, dz=5mm Reference Value = 7.42 V/m; Power Drift = 0.085 dB Peak SAR (extrapolated) = 0.187 W/kg SAR(1 g) = 0.117 mW/g; SAR(10 g) = 0.071 mW/g Maximum value of SAR (measured) = 0.129 mW/g Figure 12 802.11b with IBM T61 Test Position 4 Channel 1 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 37 of 63 ANNEX D: Probe Calibration Certificate TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 38 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 39 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 40 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 41 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 42 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 43 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 44 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 45 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 46 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 47 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 48 of 63 ANNEX E: D2450V2 Dipole Calibration Certificate TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 49 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 50 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 51 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 52 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 53 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 54 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 55 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 56 of 63 ANNEX F: DAE4 Calibration Certificate TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 57 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 58 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 59 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 60 of 63 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 61 of 63 ANNEX G: The EUT Appearances and Test Configuration Picture 4: Constituents of the EUT TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 62 of 63 5mm Picture 5: Test position 1 5mm Picture 6: Test position 2 TA Technology (Shanghai) Co., Ltd. Test Report Report No. RXA1206-0418SAR01R1 Page 63 of 63 5mm Picture 7: Test Position 3 5mm Picture 8: Test Position 4

 

 

FCC TEST REPORT REPORT NO.: RF110701C18D MODEL NO.: A103 FCC ID: YTXA103 RECEIVED: Jul. 1, 2011 TESTED: Jul. 11 ~ 25, 2011 & Jul. 10, 2012 ISSUED: Jul. 13, 2012 APPLICANT: OPPO Digital, Inc ADDRESS: 2629 Terminal Blvd. Suite B, Mountain View, CA 94043 ISSUED BY: Bureau Veritas Consumer Products Services

(H.K.) Ltd., Taoyuan Branch LAB ADDRESS: No. 47, 14th Ling, Chia Pau Vil., Lin Kou Dist., New Taipei City, Taiwan, R.O.C. This report should not be used by the client to claim product certification, approval, or endorsement by TAF or any government agencies. This report is for your exclusive use. Any copying or replication of this report to or for any other person or entity, or use of our name or trademark, is permitted only with our prior written permission. This report sets forth our findings solely with respect to the test samples identified herein. The results set forth in this report are not indicative or representative of the quality or characteristics of the lot from which a test sample was taken or any similar or identical product unless specifically and expressly noted. Our report includes all of the tests requested by you and the results thereof based upon the information that you provided to us. You have 60 days from date of issuance of this report to notify us of any material error or omission caused by our negligence, provided, however, that such notice shall be in writing and shall specifically address the issue you wish to raise. A failure to raise such issue within the prescribed time shall constitute your unqualified acceptance of the completeness of this report, the tests conducted and the correctness of the report contents. Unless specific mention, the uncertainty of measurement has been explicitly taken into account to declare the compliance or non-compliance to the specification. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 1 of 54 Report Format Version 5.0.0 TABLE OF CONTENTS RELEASE CONTROL RECORD...................................................................................4 CERTIFICATION.................................................................................................5 1. 2. SUMMARY OF TEST RESULTS.........................................................................6 2.1 MEASUREMENT UNCERTAINTY......................................................................6 3. GENERAL INFORMATION.................................................................................7 3.1 GENERAL DESCRIPTION OF EUT....................................................................7 3.2 DESCRIPTION OF TEST MODES......................................................................8 3.2.1 TEST MODE APPLICABILITY AND TESTED CHANNEL DETAIL......................9 3.3 DESCRIPTION OF SUPPORT UNITS..............................................................11 3.3.1 CONFIGURATION OF SYSTEM UNDER TEST...............................................11 3.4 GENERAL DESCRIPTION OF APPLIED STANDARDS...................................12 4. TEST TYPES AND RESULTS...........................................................................13 4.1 RADIATED EMISSION AND BANDEDGE MEASUREMENT............................13 4.1.1 LIMITS OF RADIATED EMISSION AND BANDEDGE MEASUREMENT.........13 4.1.2 TEST INSTRUMENTS......................................................................................14 4.1.3 TEST PROCEDURES.......................................................................................15 4.1.4 DEVIATION FROM TEST STANDARD.............................................................15 4.1.5 TEST SETUP....................................................................................................16 4.1.6 EUT OPERATING CONDITIONS......................................................................16 4.1.7 TEST RESULTS................................................................................................17 4.2 CONDUCTED EMISSION MEASUREMENT....................................................30 4.2.1 LIMITS OF CONDUCTED EMISSION MEASUREMENT..................................30 4.2.2 TEST INSTRUMENTS......................................................................................30 4.2.3 TEST PROCEDURES.......................................................................................31 4.2.4 DEVIATION FROM TEST STANDARD.............................................................31 4.2.5 TEST SETUP....................................................................................................31 4.2.6 EUT OPERATING CONDITIONS......................................................................31 4.2.7 TEST RESULTS................................................................................................32 4.3 6dB BANDWIDTH MEASUREMENT................................................................34 4.3.1 LIMITS OF 6dB BANDWIDTH MEASUREMENT..............................................34 4.3.2 TEST SETUP....................................................................................................34 4.3.3 TEST INSTRUMENTS......................................................................................34 4.3.4 TEST PROCEDURE.........................................................................................34 4.3.5 DEVIATION FROM TEST STANDARD.............................................................34 4.3.6 EUT OPERATING CONDITIONS......................................................................34 4.3.7 TEST RESULTS................................................................................................35 4.4 CONDUCTED OUTPUT POWER.....................................................................39 4.4.1 LIMITS OF CONDUCTED OUTPUT POWER MEASUREMENT......................39 4.4.2 TEST SETUP....................................................................................................39 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 2 of 54 Report Format Version 5.0.0 4.4.3 TEST INSTRUMENTS......................................................................................39 4.4.4 TEST PROCEDURES.......................................................................................39 4.4.5 DEVIATION FROM TEST STANDARD.............................................................39 4.4.6 EUT OPERATING CONDITIONS......................................................................39 4.4.7 TEST RESULTS................................................................................................40 4.5 POWER SPECTRAL DENSITY MEASUREMENT............................................41 4.5.1 LIMITS OF POWER SPECTRAL DENSITY MEASUREMENT.........................41 4.5.2 TEST SETUP....................................................................................................41 4.5.3 TEST INSTRUMENTS......................................................................................41 4.5.4 TEST PROCEDURE.........................................................................................41 4.5.5 DEVIATION FROM TEST STANDARD.............................................................41 4.5.6 EUT OPERATING CONDITION........................................................................41 4.5.7 TEST RESULTS................................................................................................42 4.6 CONDUCTED OUT OF BAND EMISSION MEASUREMENT...........................46 4.6.1 LIMITS OF CONDUCTED OUT OF BAND EMISSION MEASUREMENT........46 4.6.2 TEST SETUP....................................................................................................46 4.6.3 TEST INSTRUMENTS......................................................................................46 4.6.4 TEST PROCEDURE.........................................................................................46 4.6.5 DEVIATION FROM TEST STANDARD.............................................................47 4.6.6 EUT OPERATING CONDITION........................................................................47 4.6.7 TEST RESULTS................................................................................................47 5. PHOTOGRAPHS OF THE TEST CONFIGURATION........................................52 INFORMATION ON THE TESTING LABORATORIES......................................53 6. 7. APPENDIX A - MODIFICATIONS RECORDERS FOR ENGINEERING CHANGES TO THE EUT BY THE LAB........................................................54 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 3 of 54 Report Format Version 5.0.0 RELEASE CONTROL RECORD ISSUE NO. RF110701C18D Original release REASON FOR CHANGE DATE ISSUED Jul. 13, 2012 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 4 of 54 Report Format Version 5.0.0 1. CERTIFICATION PRODUCT: Wireless Adapter MODEL NO.: A103 BRAND: OPPO APPLICANT: OPPO Digital, Inc TESTED: Jul. 11 ~ 25, 2011 & Jul. 10, 2012 TEST SAMPLE: PROTOTYPE STANDARDS: FCC Part 15, Subpart C (Section 15.247) ANSI C63.10-2009 Bureau Veritas Consumer Products The above equipment has been tested by Services (H.K.) Ltd., Taoyuan Branch, and found compliance with the requirement of the above standards. The test record, data evaluation & Equipment Under Test

(EUT) configurations represented herein are true and accurate accounts of the measurements of the sample s EMC characteristics under the conditions specified in this report. PREPARED BY APPROVED BY

:

:

( Celia Chen / Senior Specialist )

, DATE:

( Ken Liu / Manager )

, DATE:

Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 5 of 54 Report Format Version 5.0.0 2. SUMMARY OF TEST RESULTS The EUT has been tested according to the following specifications:

APPLIED STANDARD: FCC PART 15, SUBPART C (SECTION 15.247) STANDARD SECTION TEST TYPE RESULT REMARK 15.207 AC Power Conducted Emission PASS 15.247(d) 15.209 Radiated Emissions Band Edge Measurement 15.247(d) 15.247(a)(2) 6dB bandwidth 15.247(b) 15.247(e) 15.203 Conducted power Power Spectral Density Antenna Requirement PASS PASS PASS PASS PASS PASS Meet the requirement of limit. Minimum passing margin is

-15.14dB at 0.189MHz. Meet the requirement of limit. Minimum passing margin is

-0.1dB at 2390.00 &

2483.50MHz. Meet the requirement of limit. Meet the requirement of limit. Meet the requirement of limit. Meet the requirement of limit. No antenna connector is used. 2.1 MEASUREMENT UNCERTAINTY Where relevant, the following measurement uncertainty levels have been estimated for tests performed on the EUT as specified in CISPR 16-4-2:

MEASUREMENT Conducted emissions Radiated emissions FREQUENCY 150kHz~30MHz 30MHz ~ 1GHz Above 1GHz UNCERTAINTY 2.41 dB 3.87 dB 3.36 dB This uncertainty represents an expanded uncertainty expressed at approximately the 95% confidence level using a coverage factor of k = 2. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 6 of 54 Report Format Version 5.0.0 3. GENERAL INFORMATION 3.1 GENERAL DESCRIPTION OF EUT EUT MODEL NO. POWER SUPPLY MODULATION TYPE MODULATION TECHNOLOGY TRANSFER RATE Wireless Adapter A103 5Vdc from host equipment CCK, DQPSK, DBPSK for DSSS 64QAM, 16QAM, QPSK, BPSK for OFDM DSSS, OFDM 802.11b:11.0/ 5.5/ 2.0/ 1.0Mbps 802.11g: 54.0/ 48.0/ 36.0/ 24.0/ 18.0/ 12.0/ 9.0/

6.0Mbps 802.11n: up to 150.0Mbps OPERATING FREQUENCY 2412 ~ 2462MHz NUMBER OF CHANNEL 11 for 802.11b, 802.11g, 802.11n (20MHz) 7 for 802.11n (40MHz) 309.0mW Printedantenna with 0dBi gain N/A USB cable (1.0m) USB port N/A OUTPUT POWER ANTENNA TYPE ANTENNA CONNECTOR DATA CABLE I/O PORTS ACCESSORY DEVICES NOTE:

1. The EUT is a Wireless Adapter. 2. The EUT incorporates a SISO function. Physically, the EUT provides one completed transmitter and one receiver. MODULATION MODE TX FUNCTION 802.11b 802.11g 802.11n (20MHz) 802.11n (40MHz) 1TX 1TX 1TX 1TX 3. The above EUT information is declared by manufacturer and for more detailed features description, please refer to the manufacturer's specifications or user's manual. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 7 of 54 Report Format Version 5.0.0 3.2 DESCRIPTION OF TEST MODES 11 channels are provided for 802.11b, 802.11g and 802.11n (20MHz):

CHANNEL FREQUENCY CHANNEL FREQUENCY 1 2 3 4 5 6 2412MHz 2417MHz 2422MHz 2427MHz 2432MHz 2437MHz 7 8 9 10 11 2442MHz 2447MHz 2452MHz 2457MHz 2462MHz 7 channels are provided for 802.11n (40MHz):

CHANNEL FREQUENCY CHANNEL FREQUENCY 3 4 5 6 2422MHz 2427MHz 2432MHz 2437MHz 7 8 9 2442MHz 2447MHz 2452MHz Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 8 of 54 Report Format Version 5.0.0 3.2.1 TEST MODE APPLICABILITY AND TESTED CHANNEL DETAIL APPLICABLE TO DESCRIPTION EUT CONFIGURE MODE RE1G RE<1G

-

PLC APCM

-

RE1G: Radiated Emission above 1GHz PLC: Power Line Conducted Emission Where NOTE:

The EUT had been pre-tested on the positioned of each 3 axis. The worst case was found when positioned on X-plane. RE<1G: Radiated Emission below 1GHz APCM: Antenna Port Conducted Measurement RADIATED EMISSION TEST (ABOVE 1GHz):

Pre-Scan has been conducted to determine the worst-case mode from all possible combinations between available modulations, data rates and antenna ports (if EUT with antenna diversity architecture). Following channel(s) was (were) selected for the final test as listed below. EUT CONFIGURE MODE MODE AVAILABLE CHANNEL TESTED CHANNEL MODULATION TECHNOLOGY

-

-

-

-

802.11b 802.11g 802.11n (20MHz) 802.11n (40MHz) 1 to 11 1 to 11 1 to 11 3 to 9 1, 6, 11 1, 6, 11 1, 6, 11 3, 6, 9 DSSS OFDM OFDM OFDM MODULATION TYPE DBPSK BPSK BPSK BPSK DATA RATE

(Mbps) 1.0 6.0 6.5 13.5 RADIATED EMISSION TEST (BELOW 1GHz):

Pre-Scan has been conducted to determine the worst-case mode from all possible combinations between available modulations, data rates and antenna ports (if EUT with antenna diversity architecture). Following channel(s) was (were) selected for the final test as listed below. EUT CONFIGURE MODE MODE

-

AVAILABLE CHANNEL TESTED CHANNEL MODULATION TECHNOLOGY 802.11g 1 to 11 11 OFDM MODULATION TYPE BPSK DATA RATE

(Mbps) 6.0 POWER LINE CONDUCTED EMISSION TEST:

Pre-Scan has been conducted to determine the worst-case mode from all possible combinations between available modulations, data rates and antenna ports (if EUT with antenna diversity architecture). Following channel(s) was (were) selected for the final test as listed below. EUT CONFIGURE MODE MODE

-

AVAILABLE CHANNEL TESTED CHANNEL MODULATION TECHNOLOGY 802.11g 1 to 11 11 OFDM MODULATION TYPE BPSK DATA RATE

(Mbps) 6.0 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 9 of 54 Report Format Version 5.0.0 BANDEDGE MEASUREMENT:

Pre-Scan has been conducted to determine the worst-case mode from all possible combinations between available modulations, data rates and antenna ports (if EUT with antenna diversity architecture). Following channel(s) was (were) selected for the final test as listed below. EUT CONFIGURE MODE MODE AVAILABLE CHANNEL TESTED CHANNEL MODULATION TECHNOLOGY

-

-

-

-

802.11b 802.11g 802.11n (20MHz) 802.11n (40MHz) 1 to 11 1 to 11 1 to 11 3 to 9 1, 11 1, 11 1, 11 3, 9 DSSS OFDM OFDM OFDM MODULATION TYPE DBPSK BPSK BPSK BPSK DATA RATE

(Mbps) 1.0 6.0 6.5 13.5 ANTENNA PORT CONDUCTED MEASUREMENT:

This item includes all test value of each mode, but only includes spectrum plot of worst value of each mode. Pre-Scan has been conducted to determine the worst-case mode from all possible combinations between available modulations, data rates and antenna ports (if EUT with antenna diversity architecture). Following channel(s) was (were) selected for the final test as listed below. EUT CONFIGURE MODE MODE AVAILABLE CHANNEL TESTED CHANNEL MODULATION TECHNOLOGY

-

-

-

-

802.11b 802.11g 802.11n (20MHz) 802.11n (40MHz) 1 to 11 1 to 11 1 to 11 3 to 9 1, 6, 11 1, 6, 11 1, 6, 11 3, 6, 9 DSSS OFDM OFDM OFDM MODULATION TYPE DBPSK BPSK BPSK BPSK DATA RATE

(Mbps) 1.0 6.0 6.5 13.5 TEST CONDITION:

APPLICABLE TO ENVIRONMENTAL CONDITIONS RE1G RE<1G PLC APCM 25deg. C, 57% RH 25deg. C, 57% RH 26deg. C, 66% RH 24deg. C, 78% RH INPUT POWER

(SYSTEM) 120Vac, 60Hz 120Vac, 60Hz 120Vac, 60Hz 120Vac, 60Hz TESTED BY Chad Lee Chad Lee Nick Chen Jun Wu Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 10 of 54 Report Format Version 5.0.0 3.3 DESCRIPTION OF SUPPORT UNITS The EUT has been tested as an independent unit together with other necessary accessories or support units. The following support units or accessories were used to form a representative test configuration during the tests. NO. PRODUCT BRAND MODEL NO. SERIAL NO. FCC ID 1 NOTEBOOK COMPUTER DELL PP27L 8SNZ12S FCC DoC Approved NO. SIGNAL CABLE DESCRIPTION OF THE ABOVE SUPPORT UNITS 1 N/A NOTE: All power cords of the above support units are non shielded (1.8m).

(Powered from adapter) PC A d a p t e r Notebook 3.3.1 CONFIGURATION OF SYSTEM UNDER TEST Test table USB cable EUT Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 11 of 54 Report Format Version 5.0.0 3.4 GENERAL DESCRIPTION OF APPLIED STANDARDS The EUT is a RF Product. According to the specifications of the manufacturer, it must comply with the requirements of the following standards:

FCC Part 15, Subpart C (15.247) 558074 D01 DTS Meas Guidance v01 ANSI C63.10-2009 All test items have been performed and recorded as per the above standards. NOTE: The EUT is also considered as a kind of computer peripheral, because the connection to computer is necessary for typical use. It has been verified to comply with the requirements of FCC Part 15, Subpart B, Class B (DoC). The test report has been issued separately. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 12 of 54 Report Format Version 5.0.0 4. TEST TYPES AND RESULTS 4.1 RADIATED EMISSION AND BANDEDGE MEASUREMENT 4.1.1 LIMITS OF RADIATED EMISSION AND BANDEDGE MEASUREMENT Radiated emissions which fall in the restricted bands must comply with the radiated emission limits specified as below table. Other emissions shall be at least 20dB below the highest level of the desired power:

FREQUENCIES

(MHz) FIELD STRENGTH

(microvolts/meter) MEASUREMENT DISTANCE

(meters) 0.009 ~ 0.490 0.490 ~ 1.705 1.705 ~ 30.0 30 ~ 88 88 ~ 216 216 ~ 960 Above 960 2400/F(kHz) 24000/F(kHz) 30 100 150 200 500 300 30 30 3 3 3 3 NOTE:

1. The lower limit shall apply at the transition frequencies. 2. Emission level (dBuV/m) = 20 log Emission level (uV/m). 3. For frequencies above 1000MHz, the field strength limits are based on average detector, however, the peak field strength of any emission shall not exceed the maximum permitted average limits, specified above by more than 20dB under any condition of modulation. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 13 of 54 Report Format Version 5.0.0 4.1.2 TEST INSTRUMENTS CALIBRATED DATE UNTIL 838251/021 MODEL NO. Jun. 22, 2011 8447D 8449B 8449B E4446A ESCS30 VULB 9168 VHBA 9123 SERIAL NO. CALIBRATED 2432A03504 Mar. 04, 2011 Mar. 03, 2012 3008A01924 Mar. 04, 2011 Mar. 03, 2012 3008A01292 Mar. 04, 2011 Mar. 03, 2012 Jun. 21, 2012 MY46180403 DESCRIPTION &

MANUFACTURER HP Preamplifier HP Preamplifier HP Preamplifier Agilent Spectrum Analyzer ROHDE & SCHWARZ TEST RECEIVER Schwarzbeck Antenna Schwarzbeck Antenna ADT. Turn Table ADT. Tower Software SUHNER RF cable EMCO Horn Antenna EMCO Horn Antenna Highpass filter Wainwright Instruments NOTE: 1. The calibration interval of the above test instruments is 12 months. And the calibrations Oct. 01, 2010 Sep. 30, 2011 Apr. 12, 2011 Apr. 11, 2012 May 06, 2011 May 05, 2012 Aug. 20, 2010 Aug. 19, 2011 Oct. 26, 2010 Oct. 25, 2011 Apr. 22, 2011 Apr. 21, 2012 SF102 3115 3115 WHK 137 480 0306 0306 NA ADT_Radiated_V 3.1/18G-10SS TT100 AT100 CABLE-CH6 NA NA NA NA NA NA 9312-4192 7.6.15.9.2 6714 SN 8 NA NA are traceable to NML/ROC and NIST/USA. 2. The horn antenna and HP preamplifier (model: 8449B) are used only for the measurement of emission frequency above 1GHz if tested. 3. The test was performed in Chamber No. 6. 4. The Industry Canada Reference No. IC 7450E-6. 5. The FCC Site Registration No. is 447212. 6. Tested Date: Jul. 11 ~ 25, 2011 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 14 of 54 Report Format Version 5.0.0 4.1.3 TEST PROCEDURES a. The EUT was placed on the top of a rotating table 0.8 meters above the ground at a 3 meters semi-anechoic chamber. The table was rotated 360 degrees to determine the position of the highest radiation. b. The EUT was set 3 meters away from the interference-receiving antenna, which was mounted on the top of a variable-height antenna tower. c. Height of receiving antenna is varied from one meter to four meters above the ground to determine the maximum value of the field strength. Both horizontal and vertical polarizations of the antenna are set to make the measurement. d. For each suspected emission, the EUT was arranged to its worst case and then the antenna was tuned to heights from 1 meter to 4 meters and the rotatable table was turned from 0 degrees to 360 degrees to find the maximum reading. e. The test-receiver system was set to Peak Detect Function and Specified Bandwidth with Maximum Hold Mode. f. If the emission level of the EUT in peak mode was lower than the limit specified, then testing could be stopped and the peak values of the EUT would be reported. Otherwise the emissions would be re-tested one by one using peak, quasi-peak or average method as specified and then reported in a data sheet. NOTE:

1. The resolution bandwidth and video bandwidth of test receiver/spectrum analyzer is 120kHz for Quasi-peak detection at frequency below 1GHz. 2. The resolution bandwidth of test receiver/spectrum analyzer is 1MHz and video bandwidth is 3MHz for Peak detection at frequency above 1GHz. 3. The resolution bandwidth of test receiver/spectrum analyzer is 1MHz and the video bandwidth is 10Hz for Average detection (AV) at frequency above 1GHz. 4. All modes of operation were investigated and the worst-case emissions are reported. 4.1.4 DEVIATION FROM TEST STANDARD No deviation. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 15 of 54 Report Format Version 5.0.0 4.1.5 TEST SETUP For the actual test configuration, please refer to the attached file (Test Setup Photo). 4.1.6 EUT OPERATING CONDITIONS a. Turn on the power of all equipment. b. Notebook PC ran a test program (provided by manufacture) to enable EUT under transmitting condition at specific channel continuously. c. Notebook PC read and wrote messages to/ from HDD. d. Notebook PC sent messages to panel and displayed on the screen. e. Repeated c ~ e. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 16 of 54 Report Format Version 5.0.0 4.1.7 TEST RESULTS 802.11b EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 1 120Vac, 60Hz 25deg. C, 57%RH MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2412.00

*2412.00 4824.00 4824.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV)

(dBuV/m) 74.0 54.0

-16.9

-9.3 MARGIN (dB) LEVEL

(dBuV/m) 57.1 PK 24.91 44.7 AV 12.56 104.1 PK 71.81 100.5 AV 68.25 53.2 PK 14.51 48.1 AV 9.40 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.16 H 1.16 H 1.16 H 1.16 H 1.00 H 1.00 H 160 160 160 160 242 242

-20.8

-5.9 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2412.00

*2412.00 4824.00 4824.00 LEVEL

(dBuV/m) 52.3 PK 42.7 AV 99.8 PK 96.5 AV 55.9 PK 52.7 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-21.7

-11.3

-18.2

-1.3 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 191 191 191 191 188 188

(dBuV) 20.12 10.56 67.57 64.25 17.19 14.00 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.24 32.24 38.66 38.66 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.24 32.24 38.66 38.66 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 17 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 6 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 104.1 PK 71.74 101.1 AV 68.78 52.3 PK 13.52 41.6 AV 2.84 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.17 H 1.17 H 1.00 H 1.00 H 148 148 143 143

-21.7

-12.4 74.0 54.0

(dBuV) RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree)

-21.7

-9.6 1.00 V 1.00 V 1.00 V 1.00 V 189 189 15 15

(dBuV) 67.79 64.41 13.55 5.65 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 LEVEL

(dBuV/m) 100.1 PK 96.7 AV 52.3 PK 44.4 AV LIMIT

(dBuV/m) 74.0 54.0 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 18 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 11 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6

*2462.00

*2462.00 2483.50 2483.50 4924.00 4924.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 103.2 PK 70.75 100.3 AV 67.82 60.6 PK 28.13 49.1 AV 16.59 53.2 PK 14.26 43.6 AV 4.68 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.12 H 1.12 H 1.12 H 1.12 H 1.00 H 1.00 H 152 152 152 152 19 19

-13.4

-4.9

-20.8

-10.4 74.0 54.0 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6

*2462.00

*2462.00 2483.50 2483.50 4924.00 4924.00 LEVEL

(dBuV/m) 99.8 PK 95.4 AV 54.6 PK 43.1 AV 56.6 PK 53.1 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-19.4

-10.9

-17.4

-0.9 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 188 188 188 188 12 12

(dBuV) 67.33 62.95 22.13 10.59 17.67 14.19 CORRECTION FACTOR

(dB/m) 32.43 32.43 32.51 32.51 38.90 38.90 CORRECTION FACTOR

(dB/m) 32.43 32.43 32.51 32.51 38.90 38.90 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 19 of 54 Report Format Version 5.0.0 802.11g EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 1 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2412.00

*2412.00 4824.00 4824.00 RAW VALUE TABLE ANGLE

(Degree) EMISSION LIMIT ANTENNA HEIGHT (m)

(dBuV)

-1.3

-0.1

(dBuV/m) 74.0 54.0 MARGIN (dB) LEVEL

(dBuV/m) 72.7 PK 40.56 53.9 AV 21.73 106.2 PK 73.98 94.2 AV 62.00 54.9 PK 16.25 42.0 AV 3.30 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.17 H 1.17 H 1.17 H 1.17 H 1.00 H 1.00 H 152 152 152 152 126 126

-19.1

-12.0 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2412.00

*2412.00 4824.00 4824.00 LEVEL

(dBuV/m) 72.1 PK 53.3 AV 104.4 PK 92.5 AV 54.9 PK 42.0 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-1.9

-0.7

-19.1

-12.0 1.28 V 1.28 V 1.28 V 1.28 V 1.00 V 1.00 V 186 186 186 186 33 33

(dBuV) 39.95 21.16 72.13 60.25 16.28 3.30 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.24 32.24 38.66 38.66 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.24 32.24 38.66 38.66 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 20 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 6 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 109.4 PK 77.03 98.3 AV 65.95 52.0 PK 13.23 39.7 AV 0.91 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.11 H 1.11 H 1.00 H 1.00 H 118 118 90 90

-22.0

-14.3 74.0 54.0

(dBuV) RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree)

-19.2

-13.9 1.00 V 1.00 V 1.00 V 1.00 V 189 189 17 17

(dBuV) 75.35 64.52 16.03 1.33 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 LEVEL

(dBuV/m) 107.7 PK 96.9 AV 54.8 PK 40.1 AV LIMIT

(dBuV/m) 74.0 54.0 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 21 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 11 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6

*2462.00

*2462.00 2483.50 2483.50 4924.00 4924.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 107.0 PK 74.59 94.0 AV 61.57 71.6 PK 39.06 53.5 AV 21.01 51.2 PK 12.27 39.3 AV 0.40 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.14 H 1.14 H 1.14 H 1.14 H 1.00 H 1.00 H 148 148 148 148 322 322

-2.4

-0.5

-22.8

-14.7 74.0 54.0 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6

*2462.00

*2462.00 2483.50 2483.50 4924.00 4924.00 LEVEL

(dBuV/m) 105.1 PK 93.2 AV 70.9 PK 52.9 AV 59.9 PK 46.7 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-3.1

-1.1

-14.1

-7.3 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 184 184 184 184 163 163

(dBuV) 72.69 60.72 38.35 20.37 20.99 7.80 CORRECTION FACTOR

(dB/m) 32.43 32.43 32.51 32.51 38.90 38.90 CORRECTION FACTOR

(dB/m) 32.43 32.43 32.51 32.51 38.90 38.90 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 22 of 54 Report Format Version 5.0.0 802.11n (20MHz) EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 1 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 26deg. C, 65%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2412.00

*2412.00 4824.00 4824.00 RAW VALUE TABLE ANGLE

(Degree) EMISSION LIMIT ANTENNA HEIGHT (m)

(dBuV)

-0.9

-1.1

(dBuV/m) 74.0 54.0 MARGIN (dB) LEVEL

(dBuV/m) 73.1 PK 40.91 52.9 AV 20.78 105.3 PK 73.02 94.2 AV 61.91 47.9 PK 9.20 35.0 AV

-3.62 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.12 H 1.12 H 1.12 H 1.12 H 1.01 H 1.01 H 115 115 115 115 6 6

-26.1

-19.0 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2412.00

*2412.00 4824.00 4824.00 LEVEL

(dBuV/m) 68.3 PK 48.1 AV 103.1 PK 93.0 AV 52.8 PK 39.4 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-5.7

-5.9

-21.2

-14.6 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 174 174 174 174 190 190

(dBuV) 36.12 15.96 70.89 60.79 14.12 0.74 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.24 32.24 38.66 38.66 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.24 32.24 38.66 38.66 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 23 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 6 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 110.0 PK 77.69 97.5 AV 65.12 53.1 PK 14.35 38.6 AV

-0.20 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.09 H 1.09 H 1.00 H 1.00 H 116 116 301 301

-20.9

-15.4 74.0 54.0

(dBuV) RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree)

-16.7

-11.6 1.00 V 1.00 V 1.00 V 1.00 V 188 188 191 191

(dBuV) 75.59 63.25 18.48 3.64 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 LEVEL

(dBuV/m) 107.9 PK 95.6 AV 57.3 PK 42.4 AV LIMIT

(dBuV/m) 74.0 54.0 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 24 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 11 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 26deg. C, 65%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6

*2462.00

*2462.00 2483.50 2483.50 4924.00 4924.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 105.9 PK 73.43 93.2 AV 60.78 71.8 PK 39.29 53.6 AV 21.07 50.5 PK 11.56 35.8 AV

-3.09 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.00 H 1.00 H 1.00 H 1.00 H 1.00 H 1.00 H 110 110 110 110 16 16

-2.2

-0.4

-23.5

-18.2 74.0 54.0 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6

*2462.00

*2462.00 2483.50 2483.50 4924.00 4924.00 LEVEL

(dBuV/m) 100.7 PK 90.5 AV 65.5 PK 46.9 AV 49.1 PK 37.3 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-8.5

-7.1

-24.9

-16.7 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 181 181 181 181 6 6

(dBuV) 68.29 58.03 32.96 14.35 10.16

-1.56 CORRECTION FACTOR

(dB/m) 32.43 32.43 32.51 32.51 38.90 38.90 CORRECTION FACTOR

(dB/m) 32.43 32.43 32.51 32.51 38.90 38.90 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 25 of 54 Report Format Version 5.0.0 802.11n (40MHz) EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 3 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2422.00

*2422.00 4844.00 4844.00 RAW VALUE TABLE ANGLE

(Degree) EMISSION LIMIT ANTENNA HEIGHT (m)

(dBuV)

-1.5

-0.3

(dBuV/m) 74.0 54.0 MARGIN (dB) LEVEL

(dBuV/m) 72.5 PK 40.31 53.7 AV 21.54 100.4 PK 68.16 88.6 AV 56.28 51.1 PK 12.42 36.8 AV

-1.93 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.03 H 1.03 H 1.03 H 1.03 H 1.00 H 1.00 H 109 109 109 109 6 6

-22.9

-17.2 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6 2390.00 2390.00

*2422.00

*2422.00 4844.00 4844.00 LEVEL

(dBuV/m) 68.7 PK 50.2 AV 96.6 PK 84.5 AV 49.6 PK 36.7 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-5.3

-3.8

-24.4

-17.3 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 175 175 175 175 16 16

(dBuV) 36.58 18.06 64.32 52.18 10.90

-2.02 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.27 32.27 38.71 38.71 CORRECTION FACTOR

(dB/m) 32.15 32.15 32.27 32.27 38.71 38.71 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 26 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 6 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 104.8 PK 72.49 92.4 AV 60.03 51.6 PK 12.83 40.8 AV 2.02 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.00 H 1.00 H 1.00 H 1.00 H 113 113 234 234

-22.4

-13.2 74.0 54.0

(dBuV) RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree)

-24.2

-16.2 1.00 V 1.00 V 1.00 V 1.00 V 177 177 43 43

(dBuV) 68.28 56.04 11.07

-0.94 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 CORRECTION FACTOR

(dB/m) 32.33 32.33 38.78 38.78 NO. FREQ. (MHz) 1 2 3 4

*2437.00

*2437.00 4874.00 4874.00 LEVEL

(dBuV/m) 100.6 PK 88.4 AV 49.9 PK 37.8 AV LIMIT

(dBuV/m) 74.0 54.0 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 27 of 54 Report Format Version 5.0.0 EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS Channel 9 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE 1 ~ 25GHz DETECTOR Peak (PK) FUNCTION Average (AV) 25deg. C, 57%RH TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6

*2452.00

*2452.00 2483.50 2483.50 4904.00 4904.00 RAW VALUE EMISSION TABLE ANGLE

(Degree) LIMIT ANTENNA HEIGHT (m)

(dBuV)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 101.2 PK 68.76 89.5 AV 57.08 71.2 PK 38.70 53.9 AV 21.36 52.1 PK 13.21 40.4 AV 1.52 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.00 H 1.00 H 1.00 H 1.00 H 1.00 H 1.00 H 108 108 108 108 6 6

-2.8

-0.1

-21.9

-13.6 74.0 54.0 74.0 54.0 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6

*2452.00

*2452.00 2483.50 2483.50 4904.00 4904.00 LEVEL

(dBuV/m) 97.1 PK 85.1 AV 67.5 PK 50.4 AV 48.2 PK 36.5 AV LIMIT

(dBuV/m) 74.0 54.0 74.0 54.0

-6.6

-3.6

-25.8

-17.6 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 1.00 V 108 108 108 108 6 6

(dBuV) 64.74 52.68 34.94 17.92 9.36

-2.41 CORRECTION FACTOR

(dB/m) 32.39 32.39 32.51 32.51 38.86 38.86 CORRECTION FACTOR

(dB/m) 32.39 32.39 32.51 32.51 38.86 38.86 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. 5. * : Fundamental frequency. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 28 of 54 Report Format Version 5.0.0 Channel 11 BELOW 1GHz WORST-CASE DATA802.11g EUT TEST CONDITION CHANNEL INPUT POWER

(SYSTEM) ENVIRONMENTAL CONDITIONS 25deg. C, 57%RH 120Vac, 60Hz MEASUREMENT DETAIL FREQUENCY RANGE Below 1000MHz DETECTOR FUNCTION Quasi-Peak TESTED BY Chad Lee ANTENNA POLARITY & TEST DISTANCE: HORIZONTAL AT 3 M NO. FREQ. (MHz) 1 2 3 4 5 6 74.60 135.19 234.08 323.76 398.42 959.77 RAW VALUE TABLE ANGLE

(Degree) EMISSION LIMIT ANTENNA HEIGHT (m)

(dBuV)

(dBuV/m) MARGIN (dB) LEVEL

(dBuV/m) 25.22 36.8 QP 27.21 40.5 QP 29.89 42.7 QP 21.17 37.5 QP 16.85 35.5 QP 41.7 QP 13.14 ANTENNA POLARITY & TEST DISTANCE: VERTICAL AT 3 M EMISSION 1.55 H 1.69 H 1.84 H 1.74 H 1.63 H 1.22 H

-3.2

-3.0

-3.3

-8.5

-10.6

-4.3 40.0 43.5 46.0 46.0 46.0 46.0 175 127 199 229 289 316 RAW VALUE MARGIN (dB) ANTENNA HEIGHT (m) TABLE ANGLE

(Degree) NO. FREQ. (MHz) 1 2 3 4 5 6 44.06 74.60 135.68 399.39 795.92 959.28 LEVEL

(dBuV/m) 30.5 QP 35.6 QP 37.3 QP 40.0 QP 34.7 QP 37.3 QP LIMIT

(dBuV/m) 40.0 40.0 43.5 46.0 46.0 46.0

-9.5

-4.4

-6.2

-6.1

-11.3

-8.7 1.77 V 1.69 V 1.84 V 1.08 V 1.15 V 1.36 V 94 223 166 286 13 178

(dBuV) 16.41 24.05 23.97 21.33 8.17 8.72 CORRECTION FACTOR

(dB/m) 11.54 13.33 12.85 16.36 18.60 28.55 CORRECTION FACTOR

(dB/m) 14.08 11.54 13.36 18.62 26.51 28.54 REMARKS: 1. Emission level (dBuV/m) = Raw Value (dBuV) + Correction Factor (dB/m). 2. Correction Factor (dB/m) = Antenna Factor (dB/m) + Cable Factor (dB). 3. The other emission levels were very low against the limit. 4. Margin value = Emission level Limit value. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 29 of 54 Report Format Version 5.0.0 4.2 CONDUCTED EMISSION MEASUREMENT 4.2.1 LIMITS OF CONDUCTED EMISSION MEASUREMENT FREQUENCY OF EMISSION (MHz) CONDUCTED LIMIT (dBV) 0.15 ~ 0.5 0.5 ~ 5 5 ~ 30 Quasi-peak 66 to 56 56 60 Average 56 to 46 46 50 NOTE: 1. The lower limit shall apply at the transition frequencies. 2. The limit decreases in line with the logarithm of the frequency in the range of 0.15 to 0.50MHz. 3. All emanations from a class A/B digital device or system, including any network of conductors and apparatus connected thereto, shall not exceed the level of field strengths specified above. 4.2.2 TEST INSTRUMENTS DESCRIPTION &

MANUFACTURER ROHDE & SCHWARZ Test Receiver ROHDE & SCHWARZ Artificial Mains Network

(for EUT) LISN With Adapter

(for EUT) ROHDE & SCHWARZ Artificial Mains Network

(for peripherals) Software Software RF cable (JYEBAO) SUHNER Terminator

(For ROHDE &

SCHWARZ LISN) MODEL NO. SERIAL NO. CALIBRATED DATE CALIBRATED UNTIL ESCS 30 100276 Dec. 31, 2010 Dec. 30, 2011 ESH3-Z5 100219 Nov. 24, 2010 Nov. 23, 2011 AD10 C10Ada-001 Nov. 24, 2010 Nov. 23, 2011 ESH3-Z5 100218 Nov. 24, 2010 Nov. 23, 2011 ADT_Cond_V7.3.7 ADT_ISN_V7.3.7 5D-FB NA NA NA NA NA NA Cable-C10.01 Feb. 22, 2011 Feb. 21, 2012 65BNC-5001 E1-010773 Feb. 26, 2011 Feb. 25, 2012 NOTE: 1. The calibration interval of the above test instruments is 12 months and the calibrations are traceable to NML/ROC and NIST/USA. 2. The test was performed in Shielded Room No. 10. 3. The VCCI Site Registration No. C-1852. 4. Tested Date: Jul. 11 ~ 25, 2011 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 30 of 54 Report Format Version 5.0.0 4.2.3 TEST PROCEDURES a. The EUT was placed 0.4 meters from the conducting wall of the shielded room with EUT being connected to the power mains through a line impedance stabilization network (LISN). Other support units were connected to the power mains through another LISN. The two LISNs provide 50 ohm/ 50uH of coupling impedance for the measuring instrument. b. Both lines of the power mains connected to the EUT were checked for maximum conducted interference. c. The frequency range from 150kHz to 30MHz was searched. Emission levels under (Limit - 20dB) was not recorded. NOTE: All modes of operation were investigated and the worst-case emissions are reported. 4.2.4 DEVIATION FROM TEST STANDARD No deviation. 4.2.5 TEST SETUP Vertical Ground Reference Plan e N B EU T 40c m LISN 80c m Test Receiver Horizontal Groun d Reference Plane Note: 1.Su p p ort units were connected to seco nd LISN . 2.Both of LISNs (AMN) are 80 cm from EUT an d at least 80 from other units and other metal planes For the actual test configuration, please refer to the attached file (Test Setup Photo). 4.2.6 EUT OPERATING CONDITIONS Same as 4.1.6. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 31 of 54 Report Format Version 5.0.0 4.2.7 TEST RESULTS CONDUCTED WORST-CASE DATA 802.11g CHANNEL PHASE Channel 11 Line 1 6dB BANDWIDTH 9kHz No 1 2 3 4 5 6 Freq.

[MHz]

0.198 0.311 0.623 0.982 1.418 3.219 Corr. Reading Value Factor

(dB) 0.17 0.21 0.25 0.27 0.30 0.43

[dB (uV)]

AV. Q.P.

-

46.90

-

34.96 28.69

-

-

31.35

-

34.12 25.95

-

Emission Level

[dB (uV)]

AV. Q.P.

-

47.07

-

35.17 28.94

-

-

31.62

-

34.42 26.38

-

Limit

[dB (uV)]

Q.P. AV. 63.69 53.69 59.93 49.93 56.00 46.00 56.00 46.00 56.00 46.00 56.00 46.00 Margin

(dB) Q.P.

-16.62

-24.76

-27.06

-24.38

-21.58

-29.62 AV.

-

-

-

-

-

-

REMARKS: 1. Q.P. and AV. are abbreviations of quasi-peak and average individually. 2. "-": The Quasi-peak reading value also meets average limit and measurement with the average detector is unnecessary. 3. The emission levels of other frequencies were very low against the limit. 4. Margin value = Emission level - Limit value 5. Correction factor = Insertion loss + Cable loss 6. Emission Level = Correction Factor + Reading Value. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 32 of 54 Report Format Version 5.0.0 CHANNEL PHASE Channel 11 Line 2 6dB BANDWIDTH 9kHz No 1 2 3 4 5 6 Freq.

[MHz]

0.170 0.189 0.271 0.970 1.668 3.499 Corr. Reading Value Factor

(dB) 0.18 0.18 0.20 0.28 0.31 0.43

[dB (uV)]

AV. Q.P.

-

47.88 48.76

-

-

37.47

-

30.83

-

34.58 26.34

-

Emission Level

[dB (uV)]

AV. Q.P.

-

48.06 48.94

-

-

37.67

-

31.11

-

34.89 26.77

-

Limit

[dB (uV)]

Q.P. AV. 64.96 54.96 64.08 54.08 61.08 51.08 56.00 46.00 56.00 46.00 56.00 46.00 Margin

(dB) Q.P.

-16.91

-15.14

-23.41

-24.89

-21.11

-29.23 AV.

-

-

-

-

-

-

REMARKS: 1. Q.P. and AV. are abbreviations of quasi-peak and average individually. 2. "-": The Quasi-peak reading value also meets average limit and measurement with the average detector is unnecessary. 3. The emission levels of other frequencies were very low against the limit. 4. Margin value = Emission level - Limit value 5. Correction factor = Insertion loss + Cable loss 6. Emission Level = Correction Factor + Reading Value. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 33 of 54 Report Format Version 5.0.0 4.3 6dB BANDWIDTH MEASUREMENT 4.3.1 LIMITS OF 6dB BANDWIDTH MEASUREMENT The minimum of 6dB Bandwidth Measurement is 0.5 MHz. 4.3.2 TEST SETUP EUT 4.3.3 TEST INSTRUMENTS SPECTRUM ANALYZER 10dB ATTENUATION PAD DESCRIPTION &

MANUFACTURER R&S SPECTRUM ANALYZER MODEL NO. SERIAL NO. DATE OF CALIBRATION DUE DATE OF CALIBRATION FSP 40 100036 May 9, 2012 May 8, 2013 NOTE: 1. The calibration interval of the above test instruments is 12 months and the calibrations are traceable to NML/ROC and NIST/USA. 2. Tested Date: Jul. 10, 2012. 4.3.4 TEST PROCEDURE a. Set resolution bandwidth (RBW) = approximately 1% of the emission bandwidth b. Set the video bandwidth (VBW) 3 x RBW, Detector = Peak. c. Trace mode = max hold. d. Sweep = auto couple. e. Measure the maximum width of the emission that is constrained by the frequencies associated with the two amplitude points (upper and lower) that are attenuated by 6 dB relative to the maximum level measured in the fundamental emission 4.3.5 DEVIATION FROM TEST STANDARD No deviation. 4.3.6 EUT OPERATING CONDITIONS The software provided by client to enable the EUT under transmission condition continuously at lowest, middle and highest channel frequencies individually. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 34 of 54 Report Format Version 5.0.0 4.3.7 TEST RESULTS 802.11b CHANNEL FREQUENCY

(MHz) 2412 2437 2462 1 6 11 FOR CH 1 BANDWIDTH 6dB

(MHz) 11.6 10.4 10.4 MINIMUM LIMIT

(MHz) PASS / FAIL 0.5 0.5 0.5 PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 35 of 54 Report Format Version 5.0.0 802.11g CHANNEL FREQUENCY

(MHz) 2412 2437 2462 1 6 11 FOR CH 1 BANDWIDTH 6dB

(MHz) 16.3 16.2 16.2 MINIMUM LIMIT

(MHz) PASS / FAIL 0.5 0.5 0.5 PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 36 of 54 Report Format Version 5.0.0 802.11n (20MHz) CHANNEL FREQUENCY

(MHz) 2412 2437 2462 1 6 11 FOR CH 11 BANDWIDTH 6dB

(MHz) 16.7 16.8 16.9 MINIMUM LIMIT

(MHz) PASS / FAIL 0.5 0.5 0.5 PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 37 of 54 Report Format Version 5.0.0 802.11n (40MHz) CHANNEL FREQUENCY

(MHz) 3 6 9 FOR CH 6 2422 2437 2452 BANDWIDTH 6dB

(MHz) 33.0 34.2 33.8 MINIMUM LIMIT

(MHz) PASS / FAIL 0.5 0.5 0.5 PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 38 of 54 Report Format Version 5.0.0 4.4 CONDUCTED OUTPUT POWER 4.4.1 LIMITS OF CONDUCTED OUTPUT POWER MEASUREMENT For systems using digital modulation in the 24002483.5 MHz bands: 1 Watt

(30dBm) 4.4.2 TEST SETUP EUT Power Sensor Power Meter 10dB ATTENUATION PAD 4.4.3 TEST INSTRUMENTS DESCRIPTION &

MANUFACTURER MODEL NO. SERIAL NO. DATE OF CALIBRATION DUE DATE OF CALIBRATION Anritsu Power Sensor Anritsu Power Meter MA2411B 0738404 Apr. 28, 2012 Apr. 27, 2013 ML2495A 0842014 Apr. 28, 2012 Apr. 27, 2013 Note: 1. The calibration interval of the above test instruments is 12 months and the calibrations are traceable to NML/ROC and NIST/USA. 2. Measurement Bandwidth of ML2495A is 65MHz greater than 6dB bandwidth of emission. 3. Tested Date: Jul. 10, 2012. 4.4.4 TEST PROCEDURES A peak power sensor was used on the output port of the EUT. A power meter was used to read the response of the peak power sensor. Record the peak power level. 4.4.5 DEVIATION FROM TEST STANDARD No deviation. 4.4.6 EUT OPERATING CONDITIONS Same as Item 4.3.6. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 39 of 54 Report Format Version 5.0.0 4.4.7 TEST RESULTS 802.11b CHANNEL FREQUENCY

(MHz) 2412 2437 2462

(MHz) 2412 2437 2462

(MHz) 2412 2437 2462

(MHz) 2422 2437 2452 1 6 11 1 6 11 1 6 11 3 6 9 802.11g CHANNEL FREQUENCY 802.11n (20MHz) CHANNEL FREQUENCY 802.11n (40MHz) CHANNEL FREQUENCY PEAK POWER

(mW) 64.6 81.3 61.7 PEAK POWER

(dBm) 18.1 19.1 17.9 LIMIT (dBm) PASS/FAIL 30 30 30 PASS PASS PASS PEAK POWER

(mW) 204.2 177.8 190.5 PEAK POWER

(dBm) 23.1 22.5 22.8 LIMIT (dBm) PASS/FAIL 30 30 30 PASS PASS PASS PEAK POWER

(mW) 151.4 309.0 182.0 PEAK POWER

(dBm) 21.8 24.9 22.6 LIMIT (dBm) PASS/FAIL 30 30 30 PASS PASS PASS PEAK POWER

(mW) 75.9 144.5 63.1 PEAK POWER

(dBm) 18.8 21.6 18.0 LIMIT (dBm) PASS/FAIL 30 30 30 PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 40 of 54 Report Format Version 5.0.0 4.5 POWER SPECTRAL DENSITY MEASUREMENT 4.5.1 LIMITS OF POWER SPECTRAL DENSITY MEASUREMENT The Maximum of Power Spectral Density Measurement is 8dBm. 4.5.2 TEST SETUP EUT SPECTRUM ANALYZER 10dB ATTENUATION PAD 4.5.3 TEST INSTRUMENTS DESCRIPTION &

MANUFACTURER R&S SPECTRUM ANALYZER MODEL NO. SERIAL NO. DATE OF CALIBRATION DUE DATE OF CALIBRATION FSP 40 100036 May 9, 2012 May 8, 2013 NOTE: 1. The calibration interval of the above test instruments is 12 months and the calibrations are traceable to NML/ROC and NIST/USA. 2. Tested Date: Jul. 10, 2012. 4.5.4 TEST PROCEDURE a. Set the RBW = 100 kHz, VBW =300 kHz, Detector = peak. b. Sweep time = auto couple, Trace mode = max hold, allow trace to fully stabilize. c. Use the peak marker function to determine the maximum power level in any 100 kHz band segment within the fundamental EBW. d. Scale the observed power level to an equivalent value in 3 kHz by adjusting

(reducing) the measured power by a bandwidth correction factor (BWCF) where BWCF = 10log(3 kHz/100kHz) 4.5.5 DEVIATION FROM TEST STANDARD No deviation. 4.5.6 EUT OPERATING CONDITION Same as Item 4.3.6 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 41 of 54 Report Format Version 5.0.0 4.5.7 TEST RESULTS FREQ.

(MHz) 2412 2437 2462 802.11b Channel 1 6 11 FOR CH 1 PSD

(dBm/100kHz) 2.56 1.18

-1.03 PSD

(dBm/3kHz)

-12.64

-14.02

-16.23 Limit

(dBm/3kHz) 8 8 8 PASS

/FAIL PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 42 of 54 Report Format Version 5.0.0 FREQ.

(MHz) 2412 2437 2462 802.11g Channel 1 6 11 FOR CH 1 PSD

(dBm/100kHz) 1.78 1.05 0.97 PSD

(dBm/3kHz)

-13.42

-14.15

-14.23 Limit

(dBm/3kHz) 8 8 8 PASS

/FAIL PASS PASS PASS Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 43 of 54 Report Format Version 5.0.0 Channel 802.11n (20MHz) FREQ.

(MHz) 2412 2437 2462 1 6 11 PSD

(dBm/100kHz)

-2.95

-0.56

-2.75 PSD

(dBm/3kHz)

-18.15

-15.76

-17.95 Limit

(dBm/3kHz) 8 8 8 PASS

/FAIL PASS PASS PASS FOR CH 6 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 44 of 54 Report Format Version 5.0.0 Channel 802.11n (40MHz) FREQ.

(MHz) 2422 2437 2452 3 6 9 PSD

(dBm/100kHz)

-9.08

-5.16

-10.37 PSD

(dBm/3kHz)

-24.28

-20.36

-25.57 Limit

(dBm/3kHz) 8 8 8 PASS

/FAIL PASS PASS PASS FOR CH 6 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 45 of 54 Report Format Version 5.0.0 4.6 CONDUCTED OUT OF BAND EMISSION MEASUREMENT 4.6.1 LIMITS OF CONDUCTED OUT OF BAND EMISSION MEASUREMENT Below 20dB of the highest emission level of operating band (in 100kHz Resolution Bandwidth). 4.6.2 TEST SETUP EUT 4.6.3 TEST INSTRUMENTS SPECTRUM ANALYZER 10dB ATTENUATION PAD DESCRIPTION &

MANUFACTURER R&S SPECTRUM ANALYZER MODEL NO. SERIAL NO. DATE OF CALIBRATION DUE DATE OF CALIBRATION FSP 40 100036 May 9, 2012 May 8, 2013 NOTE: 1. The calibration interval of the above test instruments is 12 months and the calibrations are traceable to NML/ROC and NIST/USA. 2. Tested Date: Jul. 10, 2012. 4.6.4 TEST PROCEDURE MEASUREMENT PROCEDURE REF 1. Set the RBW = 100 kHz. 2. Set the VBW 300 kHz. 3. Detector = peak. 4. Sweep time = auto couple. 5. Trace mode = max hold. 6. Allow trace to fully stabilize. 7. Use the peak marker function to determine the maximum power level in any 100 kHz band segment within the fundamental EBW. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 46 of 54 Report Format Version 5.0.0 MEASUREMENT PROCEDURE OOBE 1. Set RBW = 100 kHz. 2. Set VBW 300 kHz. 3. Set span to encompass the spectrum to be examined. 4. Detector = peak. 5. Trace Mode = max hold. 6. Sweep = auto couple. 4.6.5 DEVIATION FROM TEST STANDARD No deviation. 4.6.6 EUT OPERATING CONDITION Same as Item 4.3.6 4.6.7 TEST RESULTS The spectrum plots are attached on the following pages. D1 line indicates the highest level, and D2 line indicates the 20dB offset below D1. It shows compliance with the requirement. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 47 of 54 Report Format Version 5.0.0 802.11b CH 1 CH 6 CH 11 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 48 of 54 Report Format Version 5.0.0 802.11g CH 1 CH 6 CH 11 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 49 of 54 Report Format Version 5.0.0 802.11n (20MHz) CH 1 CH 6 CH 11 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 50 of 54 Report Format Version 5.0.0 802.11n (40MHz) CH 3 CH 6 CH 9 Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 51 of 54 Report Format Version 5.0.0 5. PHOTOGRAPHS OF THE TEST CONFIGURATION Please refer to the attached file (Test Setup Photo). Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 52 of 54 Report Format Version 5.0.0 6. INFORMATION ON THE TESTING LABORATORIES We, Bureau Veritas Consumer Products Services (H.K.) Ltd., Taoyuan Branch, were founded in 1988 to provide our best service in EMC, Radio, Telecom and Safety consultation. Our laboratories are accredited and approved according to ISO/IEC 17025. If you have any comments, please feel free to contact us at the following:

Linko EMC/RF Lab:

Tel: 886-2-26052180 Fax: 886-2-26051924 Hwa Ya EMC/RF/Safety Telecom Lab:

Tel: 886-3-3183232 Fax: 886-3-3270892 Email: service.adt@tw.bureauveritas.com Web Site: www.adt.com.tw Hsin Chu EMC/RF Lab:

Tel: 886-3-5935343 Fax: 886-3-5935342 The address and road map of all our labs can be found in our web site also. Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 53 of 54 Report Format Version 5.0.0 7. APPENDIX A - MODIFICATIONS RECORDERS FOR ENGINEERING CHANGES TO THE EUT BY THE LAB No modifications were made to the EUT by the lab during the test.

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Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 54 of 54 Report Format Version 5.0.0

 

 

PHOTOGRAPHS OF THE TEST CONFIGURATION CONDUCTED EMISSION TEST Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 1 of 2 Report Format Version 5.0.0 RADIATED EMISSION TEST Report No.: RF110701C18D Reference No.: 110701C18 & 120629C22 2 of 2 Report Format Version 5.0.0