FCC ID: NS999P2

Operating Manual 900 MHz Wireless Spread-Spectrum OEM Modem Revision 03 - May 12, 1999 Microhard Systems Inc. has made every effort to assure that this document is accurate and complete. However, the company reserves the right to make changes or enhancements to the manual and/or the product described herein at any time and without notice. Furthermore, Microhard Systems Inc. assumes no liability resulting from any omissions in this document, or out of the application or use of the device described herein. Microhard Systems Inc. Leaders in Wireless Telecom Contents 1. 2. 3. Introduction 1.0 Product Overview ........................................................................................................................................................ 1 1.1 Features........................................................................................................................................................................ 1 1.2 About this Manual ....................................................................................................................................................... 2 Initial Setup and Configuration 2.0 Unpacking and Inspection............................................................................................................................................ 3 2.1 Additional Requirements ............................................................................................................................................. 3 2.2 Connectors and Indicators ........................................................................................................................................... 3 2.3 Configuration............................................................................................................................................................... 5 2.4 Checking the Link......................................................................................................................................................... 6 Configuration Options 3.0 Command Line Interface.............................................................................................................................................. 7 3.1 AT Commands ............................................................................................................................................................. 8 A - Answer.................................................................................................................................................................... 8 D - Dial ........................................................................................................................................................................ 8 E - Command Echo...................................................................................................................................................... 8 I - Identification ........................................................................................................................................................... 8 O - Online Mode.......................................................................................................................................................... 8 Q - Quiet Mode............................................................................................................................................................ 9 V - Result Codes Display............................................................................................................................................. 9 W - Connection Result................................................................................................................................................. 9 Z - Reset Modem and load stored configuration.......................................................................................................... 9

&C - DCD (Data Carrier Detect) ................................................................................................................................. 9

&D - DTR (Data Terminal Ready)............................................................................................................................... 9

&F - Load Factory default configuration ..................................................................................................................... 9

&K - Handshaking ........................................................................................................................................................ 9

&S - DSR (Data Set Ready)....................................................................................................................................... 10

&V - View Configuration ........................................................................................................................................... 10

&W - Write Configuration to memory....................................................................................................................... 10 Sxxx? - Read S register value .................................................................................................................................... 10 Sxxx=yyy - Set S register value ................................................................................................................................. 10 3.2 Command Result Codes............................................................................................................................................. 10 S Registers ................................................................................................................................................................. 11 3.3 S Register 2 - Escape Code......................................................................................................................................... 11 S Register 3 - CR Control Code................................................................................................................................. 11 S Register 4 - Linefeed Control Code........................................................................................................................ 11 S Register 5 - Backspace Control Code ..................................................................................................................... 11 S Register 101 - Operating Mode .............................................................................................................................. 12 S Register 102 - Serial Baud Rate.............................................................................................................................. 13 S Register 103 - Wireless Link Rate .......................................................................................................................... 14 S Register 104 - Network Address............................................................................................................................. 14 S Register 105 - Unit Address.................................................................................................................................... 14 S Register 106 - Hopping Pattern .............................................................................................................................. 14 S Register 107 - Encryption Key ............................................................................................................................... 14 S Register 108 - Output Power Level ........................................................................................................................ 15 S Register 109 - Hopping Interval ............................................................................................................................. 16 S Registers 111 to 113 - Packet Parameters - Point to Point Mode ............................................................................ 16 S Registers 111 to 115 - Packet Parameters - Point to Multipoint Mode................................................................... 17 Appendices A. Modem Command Summary ............................................................................................................................. 19 Serial Interface................................................................................................................................................... 21 B. C. Sample Schematic Diagram ............................................................................................................................... 23 D. Modem Setup Overview .................................................................................................................................... 25 E. Technical Specifications .................................................................................................................................... 27 Glossary ............................................................................................................................................................. 29 F. MHX-900 Operating Manual: Contents i 1. Introduction 1.0 Product Overview Congratulations on choosing the MHX-900 wireless modem module! Your new MHX-900 modem is a state-of-the-art, 900 MHz frequency-hopping spread-spectrum communications transceiver module. When the MHX-900 module is incorporated into the design of new or existing equipment, terminal devices (DTEs) up to 30 km (or more)1 apart will be capable of establishing high-speed2 communications wirelessly. MHX-900 modules provide a practical and reliable alternative to using traditional analog phone-line modems or permanent wire serial cable

(RS-232) connections for data communications between terminal equipment. Moreover, wireless data communications using the MHX-900 module means you will benefit from:

n greater flexibility and freedom to relocate terminal equipment, n eliminated requirement for access to wire-based transfer media such as telephone lines, n the ability to communicate through walls, floors, and many other obstacles. While the MHX-900 module is compact in its design, it delivers power and convenience and offers quality and dependability. The MHX-900 modules versatility makes it the ideal solution for applications ranging from office-

productivity to industrial data control and acquisition. While a pair of MHX-900 modules can link two terminal devices (point-to-

point operation), multiple MHX-900 modules can be used together to create a network of various topologies (point-to-multipoint operation). Multiple independent networks can operate concurrently, so it is possible for unrelated communications operations to take place in the same or a nearby area without sacrificing privacy, functionality, or reliability. 1.1 Features Key features of the MHX-900 module include:

n transmission within a public, license-exempt band of the radio spectrum3 this means there are no conditions on usage of the MHX-900 module, and that it can be used without restrictions or access fees (such as those incurred by cellular airtime);

n a serial I/O data port (TTL levels) with handshaking and hardware flow control, allowing the MHX-900 module to inter-

face directly to any microprocessor with an asynchronous serial interface. 1 Ideal conditions with clear line-of-sight communications, using high-gain antennas. 2 Up to 115,200 bits per second (bps). 3 902-928 MHz, which is license-free within North America; may need to be factory-configured differently for some countries. MHX-900 Operating Manual: Chapter 1 Introduction. 1 n twenty different user-selectable pseudo-random hopping patterns to offer the possibility of separately operating multiple networks while providing security, reliability and high tolerance to interference;

n encryption key with 65536 user-selectable values to maximize security and privacy of communications;

n built-in CRC-16 error detection and auto re-transmit to provide 100% accuracy and reliability of data;

n ease of installation and use the MHX-900 module uses a subset of standard AT style commands making it compatible with most communication packages, such as HyperTerminal. While the typical application for the MHX-900 is to provide a mid- to long-

range wireless communications link between DTEs, it can be adapted to almost any situation where an asynchronous serial interface is used and data intercommunication is required. 1.2 About this Manual This manual has been provided as a guide and reference for installing and using MHX-900 wireless modem modules. The manual contains instructions, suggestions, and information which will help you set up and achieve optimal performance from your equipment using the MHX-900 module. It is assumed that users of the MHX-900 module have either system integration or system design experience. Chapter 2 details the requirements and connections of the MHX-900 module. Chapter 3 describes the AT command register setup and configuration. The Appendices, including the Glossary of Terms, are provided as informational references which you may find useful throughout the use of this manual as well as during the operation of the wireless modem. Throughout the manual, you will encounter not only illustrations that further elaborate on the accompanying text, but also several symbols which you should be attentive to:

Caution or Warning: Usually advises against some action which could result in undesired or detrimental consequences. Point to Remember: Highlights a key feature, point, or step which is worth noting, Keeping these in mind will make using the MHX-900 more useful or easier to use. Tip: An idea or suggestion is provided to improve efficiency or to make something more useful. With that in mind, enjoy extending the boundaries of your communications with the MHX-900 module. 2 MHX-900 Operating Manual: Chapter 1 Introduction 2. Initial Setup and Configuration 2.0 Unpacking and Inspection The following items should be found in the shipping carton. Inspect the contents for any shipping damage. Report damages or shortages to the distributor from which the unit was purchased. Keep all packing materials in the event that transportation is required in the future. Package contents (normal distribution):

1 2 MHX-900 Wireless Modem module Operating Manual (this document) 1 1 2.1 Additional Requirements Since the MHX-900 module is a unique product in a class of its own, it will communicate only with another MHX-900 module which has been compatibly configured. Thus, at least two MHX-900 modules will be required to establish a wireless communications link. Additionally, the following requirements should be taken into consideration when preparing to incorporate the MHX-900 module in new or existing designs. n Relatively small footprint for the MHX-900 module (e.g., 2.1 W x 3.5 L x 0.8 H) on the OEM PCB. n Serial port and control signals from the host microprocessor. See sample application schematics in Appendix C. n +5 Vdc supply from the host OEM electronics (+ 10%). n An external antenna (customer supplied). 2.2 Connectors and Indicators The MHX-900 module connects to the host equipment by a dual row header on the underside of the unit. This enables the MHX-900 module to be directly soldered onto the host equipment manufacturers PCB. The MHX-900 radio deck is attached via a 40 pin header soldered directly to the PCB. The radio deck also has an antenna connector. A suitable antenna must be used to ensure adequate performance of the MHX-900 module. The MHX-900 module is equipped with status LEDs which show the current operating mode for the unit. The LED signals also are also brought out to external connectors to be monitored by the OEM microprocessor. The output drive capability of any output signal pin is approx. 5 mA. The pin description and location of the MHX-900 is shown on the following page. MHX-900 Operating Manual: Chapter 2 Initial Setup and Configuration 3 Vcc Radio Vcc Radio Vcc Logic Vcc Logic Vcc Logic Vcc Logic Vcc Logic N/C

/CONFIG

/RESET GND GND GND GND GND GND GND N/C N/C N/C Top View 1 40 20 21 Antenna Connector N/C N/C N/C N/C N/C N/C N/C Rx Mode LED Tx Mode LED RSSI LED 3 RSSI LED 2 RSSI LED 1 CTS RTS DSR N/C DTR TxD RxD DCD For maximum power, use separate power supplies for the radio and the digital electronics. For OEM design simplicity, connect both the radio and logic VCC connections together. This saves a regulated power supply. Caution: Using any other power supply which does not provide the proper voltage or current could damage the MHX-900 module. The interface connectors and indicator lights are summarized below:

Vcc Radio - These connections supply power for the MHX-900 modules radio deck electronics. For 1 watt maximum output, the required supply rating should be 5.25 VDC +- 5%. Limiting this to 5.0 Vdc will limit the output power slightly. Required current depends on transmit duration and output power. Maximum current at full transmit power is 600 mA DC. Vcc Logic - These connections supply power for the MHX-900 modules digital electronics. To simplify the OEM design, the Radio VCC can be connected to the Logic VCC. Maximum current while transmitting is approx. 100 mA DC. GND - These are the Ground supply connections for the digital and radio electronics.

/RESET - This momentary active low input signal (100 ms typical) resets the digital electronics.

/CONFIG - Leave this pin unconnected. Do NOT ground. Receive Signal Strength Indicator (RSSI) LEDs - These outputs show the quality/strength of the received signal. As the signal strength increases, the number of active outputs increase incrementally. Data Port (DCE) - Pins 21 through 28 inclusive. This port is used to interface the MHX-900 module to a DTE device and operates at 2400 to 115,200 bps. The same port is used to configure the modem by interfacing to the host microprocessor. See Appendix B for details on the serial interface signals. RX Mode LED - This active low output indicates when the modem receives data over the wireless link, as well as during internal carrier search and synchronization operations. TX Mode LED - This active low output indicates that the modem is transmitting data wirelessly. This light flashes during initial startup and carrier synchronization. Antenna Connector - The antenna is attached to this connection. N/C - These pins are reserved for future use. Do not connect to this pins. 4 MHX-900 Operating Manual: Chapter 2 Initial Setup and Configuration 2.3 Configuration Prior to establishing a wireless link, each MHX-900 module that will participate in the link must be correctly configured for compatibility and for the desired mode of operation. The two most common types of networks used are:

n Point-to-point: A Master station communicates with a single Slave station. n Point-to-multipoint: A Master station communications with two or more Slave stations. Within any network, the Master will communicate only with Slave(s) assigned to the same network. Similarly, a Slave will only communicate with the Master of the network to which it is assigned. 2.3.1 Quick Start Approach The minimum configuration requirements for point-to-point and point-to-

multipoint are summarized below. These requirements will get you started and only ensure that a link can be established, but do not necessarily provide the best performance; optimization of the communications link is discussed in later sections. A. Point-to-Point To establish a point-to-point communications link, the following requisites must be satisfied:

n The Operating Mode for one modem must be configured as a Master - Point-to-Point, and the other as a Slave - Point-to-

Point. n The Wireless Link Rate for both modems must be the same. n The Network Address assigned for both modems must be the same. n The Unit Address assigned for both modems must be the same. n The same Hopping Pattern must be selected for both modems. n The same Hopping Interval must be selected for both modems. n Both modems must use the same Encryption Key. MHX-900 Operating Manual: Chapter 2 Initial Setup and Configuration 5 B. Point-to-Multipoint To establish a point-to-multipoint network, the following requisites must be satisfied:

n The Operating Mode for one modem must be configured as a Point-to-Multipoint Master, and the others as Point-to-

Multipoint Slaves. n The Wireless Link Rate for all modems must be the same. n The Network Address assigned to all modems must be the same. n Each Slave must be assigned a unique Unit Address (Unit Address 0 is not supported). n The same Hopping Pattern must be selected for all modems. n The Hopping Interval is determined by the Master modem, and is therefore configured only at the Master. n All modems must use the same Encryption Key. Each of the parameters above are defined by specific S registers. Settings are not immediately stored in non-volatile memory. The command &W writes the current configuration into non-volatile memory, and are therefore retained even after powering down. Each item and the settable parameters within the modem configuration are described in detail in Chapter 3: Configuration Options. 2.4 Checking the Link Once configured properly, a pair or set of communicating modems can be tested to ensure that a link can be successfully established. Connect an appropriate antenna to each MHX-900 module. The modems should indicate the status of the wireless link via the RSSI outputs on each unit:

If the link is good, up to three RSSI outputs should be active; and if the link is absent (due to a fault at one end or another, such as misconfiguration), the outputs will be inactive. It is recommended that if MHX-900 modules will be deployed in a field where large distances separate the units, the modems should be configured and tested in close proximity (e.g., in the same room) first to ensure a good link can be established and settings are correct. This will facilitate troubleshooting, should problems arise. In a multipoint system, only the Slave modems give valid RSSI readings. Microhard Systems Inc. provides a development system which supplies all system power and RS-232 level shifting circuits required to connect a MHX-

900 module to a PC. This can serve as an invaluable aid in OEM system design. Warning: Using an antenna that is inappropriate for use with the MHX-900 module could result in undesired performance, and may damage the unit. It is the users responsibility to ensure the antenna has adequate lightning protection. 6 MHX-900 Operating Manual: Chapter 2 Initial Setup and Configuration 3. Configuration Options 3.0 Command Line Interface The MHX-900 modem module is easily configured to meet a wide range of needs and applications. You can have your modem perform a variety of functions by sending it instructions (in the form of commands). Sending a command overrides the modems operating characteristics. Your modem must be in Command Mode for it to execute a command. If you send characters when the modem is in Data Mode, the modem sends the characters across the Wireless Link. When the modem is initially powered up, the interface will operate in command mode. You can place the modem into Data Mode either by 1. Dialing a remote modem 2. 3. You can place the modem into Command Mode either by 1. Sending the escape sequence 2. Toggling the DTR line, Note: When the connection is lost to the remote modem, the modem will switch to command mode. Issuing the answer command Issuing the online command To enter a command line and have your modem execute it, use the following procedure:

Refer to Appendix A (page 19) for a summary of the modem commands 1. With your modem in the Command Mode, type AT. These characters, known as the attention characters, must be typed at the beginning or each command line. Configuration options are not stored in non-volatile memory until the WRITE command (&W) is executed 2. Type the command(s) in upper-case letters. Include any parameters required by the command. To make the command line more readable, you can insert as many spaces as desired. The command line holds up to 40 characters, not including the AT prefix. 3. Press the ENTER key. Your modem executes the command line and sends you a word response (usually OK). For example, to set the Operating Mode S101 register to Master point to point mode, enter the following command line; AT S101 = 1 <return>. To display what a register is currently set to, enter the following command line; AT Sxxx? <return>. The modem will output the value of the register. MHX-900 Operating Manual: Chapter 3 Configuration Options 7 Note: If you want to send more than one command line, wait for a response before entering the AT prefix at the start of the next command line. To re-execute the previous command, enter A/. The modem will execute the previous command line. For the AT command protocol, an escape sequence consists of three consecutive escape codes preceded and followed by at least 1 second of inactivity. Typically, the + character is used as the escape code.

+++

preceded and followed by 1 second of inactivity Answer 3.1 AT Commands Several AT Commands are supported by the MHX-900 module. The following is a short description of all available commands. * denotes standard factory settings. A The A command causes the modem to attempt to connect with another remote modem. D Using the D command, the modem will set itself for master point to point mode, and then try to synchronize with the modem address specified in the command (Dxxxx). Register S105 is overwritten with value xxxx. Note -

DT or DP are also value (tone dial or pulse dial). E Your modem is preset to return (or echo) commands to the host microprocessor when in Command Mode. Command Echo Dial No Command Echo Command Echo E0

*E1 Identification I The I command returns various modem information settings. Product Code (MHX-900) 3 Digit computed checksum Issue ROM Check (OK or ERROR) Product Identification (Firmware Version) Not Supported Firmware Copyright I0 I1 I2 I3 I4 I5 On-line Mode O The O command attempts to communicate with a remote modem. 8 MHX-900 Operating Manual: Chapter 3 Configuration Options Quiet Mode Q Your modem is preset to send responses when it executes commands, and there after to keep the host informed of its status. Enable modem responses Disable modem responses

*Q0 Q1 Result Codes display V Your modem can either display result codes as words or numbers. Display Result Codes as numbers Display Result Codes as words V0

*V1 Connection Result W The W command returns your modem to the Data Mode from the Command Mode

*W0 W1 Reports computer (DTE) rate as CONNECT xxxx Reports computer (DTE) rate and wireless rate between modems as CARRIER xxxx. Reports modem (DCE) rate as CONNECT xxxx W2 Reset and load stored configuration Z The Z command resets the modem and loads the stored configuration.

&C The &C command controls the modems DCD output signal to the host microprocessor. This command determines when the DCD is active. DCD (Data Carrier Detect) DCD is always ON

&C0

*&C1 DCD on when modems are synchronized DTR (Data Terminal Ready)

&D The &D command controls what action the modem performs when the DTR input line is toggled. The DTR input is controlled by the host microprocessor. DTR line is ignored Not Supported

&D0

&D1

*&D2 DTR disconnects and switches to Command Mode

&D3 Load Factory Default Configuration DTR disconnects and resets modem

&F The &F command resets the modem and loads the default factory configuration.

&K The &K command controls the handshaking between the modem and host microprocessor. Handshaking

&K0

*&K3 Enable hardware handshaking (RTS/CTS) Disable handshaking MHX-900 Operating Manual: Chapter 3 Configuration Options 9 DSR (Data Set Ready)

&S The &S command controls the DSR line for the modem, and determines when it is active DSR is always ON

&S0

*&S1 DSR is ON in Data Mode, OFF in Command Mode View Configuration

&V The &V command displays the current (DTE) baud rate, and all setable modem parameters including S register values.

&W Write Configuration to memory The &W command stores the active configuration into the modems non-

volatile memory. Sxxx? Read S register value This command causes the modem to display the current setting of S register xxx. Sxxx=yyy This command sets the specified S register to a value specified by yyy. 3.2 Command Result Codes The MHX-900 module can either display the results of a command as either text strings or numerical data. The following chart shows resulting text string and corresponding numeric result. Set S register value (see section on S-Registers) 0 1 2 3 4 8 10 11 12 14 17 18 33 OK CONNECT RING NO CARRIER ERROR NO ANSWER CONNECT 2400 CONNECT 4800 CONNECT 9600 CONNECT 19200 CONNECT 38400 CONNECT 57600 CONNECT 115200 10 MHX-900 Operating Manual: Chapter 3 Configuration Options 3.3 S Registers S Register 0 - Number of Rings - Auto Answer If this register is set to zero, the modem will power up in command mode. If this register is non-zero, the modem will power up in data mode. S Register 2 - Escape Code This register contains the ASCII value of the escape character. The default value (decimal 43) is equivalent to the ASCII character +. Values greater than 127 disable the escape feature and prevent you from returning to the Command Mode. Default is + (decimal 43). S Register 3 - CR Control Code This register contains the ASCII value of the carriage return character. This is the character that is used to end the command line and is also the character that appears after the modem sends a response. Default is CR (decimal 13). S Register 4 - Linefeed Control Code Register S4 sets the ASCII value of the linefeed character. The modem sends the linefeed character after sending a carriage return character when sending text responses. Default is LF (decimal 10). S Register 5 - Backspace Control Code Register S5 sets the ASCII value of the backspace character. This character is both the character created by entering BACKSPACE and the character echoed to move the cursor to the left. Default is BS (decimal 8). MHX-900 Operating Manual: Chapter 3 Configuration Options 11 Each unit must be either a Master or Slave. Only one Master can exist for each network. S Register 101 - Operating Mode The Operating Mode (register S101) partly defines the personality of the MHX-900 module. Allowable settings for this register are 1 through 4. Default is 2 (Slave point to point). Each unit should be configured as a Master or Slave. The user should decide, prior to deployment, whether a point-to-point or point-to-multipoint network is appropriate for the application, and how each unit will be assigned to terminals. 1)Master - Point to Point One unit in a point-to-point link should be set as the Master, obligating the other modem to be used as a Slave. During operation, it makes little difference which end is which, especially if data is generally transmitted unidirectionally at any given moment. When both terminals have data to send, more bandwidth is dynamically allocated to the Master; otherwise, the transmitting end, whichever it is at the time, is given the full bandwidth.

* 2)Slave - Point to Point The terminal in a point-to-point network which is not set as the Master, is obligated to be the Slave. The Slave will communicate with the Master, whose network address, unit address, hopping pattern and hopping interval matches its own. In point-to-point operation, the Slave modem acknowledges all packets of data sent by the Master, and vice versa. These acknowledgements, along with CRC error checking ensure that data is passed through exactly once, and that the data is not corrupted. 3)Master - Point to Multipoint In a point-to-multipoint network, one unit should be set as the Master, obligating all other modems to be Slaves. The Master designation is generally given to the station which functions as a hub for all remote nodes, and it is the Master stations responsibility to control communications with Slaves. Point-to-multipoint operation differs from point-to-point operation in many ways. One key difference is that the Slaves cannot acknowledge packets of data sent by the Master. Clearly this would cause conflicts when there are multiple Slaves. The Master does, however, send acknowledgements to all messages it receives from Slaves. The Master initiates communications by sending a broadcast message to all Slaves. All Slaves are free to respond in a Slotted ALOHA fashion, meaning that each Slave can choose one of several windows in which to transmit. If there happens to be two Slaves attempting to talk at the same time, then the Master would not receive the data, and the Slaves therefore would not get an acknowledgement. At this point, the Slaves would attempt to get the information through at random time intervals, thus attempting to avoid any more conflicts. Special parameters related to Point-to-Multipoint operation are set in the Packet Parameters menu, and are described in a later section. 4) Slave - Point to Multipoint Several Slaves exist in a point-to-multipoint network, all of which communicate with the common Master. Slaves cannot directly communicate with other Slaves. 12 MHX-900 Operating Manual: Chapter 3 Configuration Options S Register 102 - Serial Baud Rate The Serial Baud Rate is the current speed that the modem is using to communicate with the DTE. When the AT command prefix is issued, the modem performs an autobaud operation and determines what the current DTE baud rate is set to. The S register value returns the current setting of the DTE baud rate. The possible values are:

115200 57600 38400 28800 19200 14400 9600 7200 4800 3600 2400 1 2 3 4 5 6

*7 8 9 10 11 It is generally advisable to choose the highest rate that your terminal equipment will handle to maximize performance, unless a limitation on the available bandwidth is desired. If the DTE is a personal computer, the port can usually be used reliably at 115200. S Register 103 - Wireless Link Rate The Wireless Link Rate is the speed and optimization method for which modems will communicate over the RF link. The allowable settings are:

* 1 2 3 Turbo Fast Normal Depending on the application requirements, each mode will provide different throughputs and performance optimizations as follows:

Mode Turbo Fast Normal Expected Performance

(Maximum Throughput) 96 kbps 60 kbps 30 kbps Primary Optimization Optimized for Speed Optimized for Distance and Speed Optimized for Distance Generally, the lowest rate which provides sufficient bandwidth should be selected. For example, if DTEs are set to communicate at 19.2 kbps, then the wireless rate can be set to Normal (with the added advantage of slightly greater range). If DTEs require nearly 115.2 kbps of sustained bandwidth, then the wireless rate should be set to Turbo (setting it lower would bottleneck data transmissions in the wireless link). Note that there is a compromise between speed, performance and range. All units in a network must be set to the same wireless link rate. MHX-900 Operating Manual: Chapter 3 Configuration Options 13 Select a Network Address and assign it to all units which will be included in the network. Use the same Unit Address on both units for point-to-

point mode. In multipoint mode, set all Slaves to a unique Unit Address. In Point-to-Point, valid Unit Addresses are 0 to 65535. In Point-to-Multipoint, valid Slave Unit Addresses are 1 to 65535. Ensure that all units within a network use the same hopping pattern, and that multiple concurrent networks each have different hopping patterns. All units within a network must use the same encryption key. S Register 104 - Network Address The Network Address defines the membership to which individual units can be a part of. By establishing a network under a common Network Address, the network can be isolated from any other concurrently operating network using the same hardware. As well, the Network Address provides a measure of privacy and security. Only those units which are members of the network will participate in the communications interchange. Valid values for the Network Address range from 0 to 65535, inclusive. To enhance privacy and reliability of communications where multiple networks may operate concurrently in close proximity, it is suggested that an atypical value be chosen perhaps something meaningful yet not easily selected by chance or coincidence. Default is 0. S Register 105 - Unit Address In point-to-point operation, the Unit Address on both the Master and Slave units must be the same. In point-to-point operation, valid Unit Addresses range from 0 to 65535. In a multipoint system, the Unit Address uniquely identifies each Slave from the others.. In a multipoint system, a Slave can take on any Unit Address between 1 and 65535. Remember that each Slave should have a Unit Address which is unique from any other Slave in the network. Default is 1. S Register 106 - Hopping Pattern Since the MHX-900 is a frequency-hopping modem, the carrier frequency changes periodically according to one of twenty pseudo-random patterns, selected by defining the Hopping Pattern. A value from 1 to 20, inclusive, can be used to select the pattern. It is important that all units which will participate in a network use the same hopping pattern, or the communication link will fail. Default is 1. S Register 107 - Encryption Key The Encryption Key provides a measure of security and privacy of communications by rendering the transmitted data useless without the correct key on the receiver. Valid Encryption Keys range from 0 to 65535. Keep in mind that all units within the network must use the same key for communications to succeed. 14 MHX-900 Operating Manual: Chapter 3 Configuration Options S Register 108 - Output Power Level The Output Power Level determines at what power the MHX-900 transmits. The super-sensitive MHX-900 can operate with very low power levels, so it is recommended that the lowest power necessary is used; using excessive power contributes to unnecessary RF pollution. The allowable settings are:

* 1 2 3 4 1 mW 10 mW 100 mW 1000 mW Ideally, you should test the communications performance between units starting from a low power level and working upward until the RSSI is sufficiently high and a reliable link is established. Although the conditions will vary widely between applications, typical uses for each setting are described below:

Power Use 1 mW For in-building use, typically provides a link up to 300 feet on the same floor or up/down a level. Outdoors, distances of 10 km can be achieved if high-gain (directional) antennas are placed high above ground level and are in direct line-of-sight. Test the communications link using a low power level and work upward. Avoid using a higher power than necessary since performance may actually degrade. 10 mW 200-500 ft indoors, 8-15 km outdoors. 100 mW 400-800 ft indoors, 15-25 km outdoors. 1000 mW

(1 W) Typically provides communications up to a distance of 1000 feet or more in-building on the same floor or up/down a few levels, depending on building construction (wood, concrete, steel, etc.). In ideal line-of-sight conditions, up to 30 km or more can be achieved. Note that only an antenna with a gain of no more 6 dBi may be used. Any higher is a violation of FCC rules. See IMPORTANT warning below. IMPORTANT:

FCC and Industry Canada Regulations allow up to 36 dBi effective radiated power (ERP). Therefore, the sum of the transmitted power (in dBm), the cabling loss and the antenna gain cannot exceed 36 dBi. 1 mW = 0 dBm 10 mW = 10 dBm 100 mW = 20 dBm 1000 mW = 30 dBm For example, when transmitting 1 Watt (30 dBm), with cabling losses of 2 dB, the antenna gain cannot exceed 36 - 30 + 2 = 8 dBi. If an antenna with a gain higher than 8 dBi were to be used, the power setting must be adjusted appropriately. Violation of FCC or IC regulations can result in severe fines. It is the responsibility of the user to understand and ensure compliance with these regulations. MHX-900 Operating Manual: Chapter 3 Configuration Options 15 In a point-to-point network, the master and slave must be set to the same hopping interval. In a point-to-multipoint network, the hopping interval is controlled by the master. The slave units will use the hopping interval setting from the master. S Register 109 - Hopping Interval This option determines the frequency at which the modems change channel. Note that all modems must have the same hopping interval setting. The allowable settings are:

25 msec 50 msec 100 msec 150 msec 200 msec 250 msec 300 msec 350 msec 1 2 3 4

*5 6 7 8 taken In Slave - Point-to-Multipoint operation, this parameter is determined by the Master, and cannot be altered. Packet Parameters Packet Parameters define the characteristics of the internal packets or frames which are transmitted. The settings should be set only by an expert since adequate care must be to maintain reliability and optimum performance. Packet Parameters will vary depending on the modems Operating Mode. S Registers 111 to 113 - Packet Parameters -Point to Point Mode In Point-to-Point (both Master and Slave), the following settings are available:

S Register 111 - Minimum Size This setting has a range of 0 to 255, and defines the number of bytes to accumulate from the DTE before transmitting a packet. Setting this value to 0 ensures that all characters sent by the DTE are immediately transmitted. The value may not exceed the maximum packet size. S Register 112 - Maximum Size This setting has a range of 1 to 255, and defines the maximum number of bytes from the DTE which should be encapsulated in a packet. This value should be greater than the minimum packet size, but not smaller than is necessary for reliable communications. If the wireless link is consistently good and solid, a maximum size of 255 will yield the best throughput

(depending on the higher level protocols of the connected equipment). However, if the link is poor (e.g., experiencing excessive interference) and data is frequently retransmitted, the maximum packet size should be reduced. This decreases the probability of errors within packets, and reduces the amount of traffic in the event that retransmissions are required. Since a smaller packet size results in a proportionally higher overhead and lower overall throughput on a good connection, this should only be reduced if many errors are being detected by CRC (see Radio Statistics option of configuration). 16 MHX-900 Operating Manual: Chapter 3 Configuration Options S Register 113 - Retry Limit This setting has a range of 0 to 255, and determines the number of attempts that will be made to retransmit data which failed the CRC checksum. Once the limit is reached, the modem will give up and discard the data. If the wireless connection is poor and data often needs to be retransmitted, a modem could be tied up trying to retransmit, thus holding up pending data. S Registers 111 to 115 - Packet Parameters - Point-to-

Multipoint Mode If the Operating Mode is Slave - Point-to-Multipoint, the default values for the S registers are:

S111 Minimum Size S112 Maximum Size S113 Retry Limit S115 Repeat Interval

(not used)

(not used) 4 8 In Master - Point-to-Multipoint mode, the default values for the S registers are:

S111 Minimum Size S112 Maximum Size S113 Retransmissions S114 Address Header 0 255 255 Disabled S Register 111 - Minimum Size The Minimum Size parameter prevents the Slave from sending data until it has buffered a minimum number of bytes. The Master determines this parameter and passes the information to all Slaves in a Multipoint system. S Register 112 - Maximum Size Packet sizes in excess of the minimum size are limited by the Maximum Size parameter. If the Slave is sending more than the minimum, the unit will wait until it has buffered the maximum packet size or until a packet timeout of two characters occurs on the serial port. The Master unit tells all Slaves which maximum and minimum packet values to use. In addition, the Master tells all Slaves which Hopping Interval to use (see Section 3.11). S Register 113 - Retry Limit (Slave Point to Multipoint) Similar to the Retry Limit in Point-to-Point, the Slaves in a multipoint system will reattempt to send a packet of data until it receives an acknowledge or until it reaches the Retry Limit. MHX-900 Operating Manual: Chapter 3 Configuration Options 17 S Register 113 - Retransmissions (Master Point to Multipoint) In a multipoint system, the Master does not receive acknowledgments from Slaves, and therefore has a slightly modified parameter called Retransmissions. The Master will retransmit each data packet exactly the number of times defined by the Retransmissions parameter. The Master retransmits once per hopping interval until the limit is reached. S Register 114 - Address Header A packet parameter unique to Master - Point-to-Multipoint is the Address Header parameter. The allowable settings are:

*1 2 3 Disabled Binary Text When the Master receives a packet from a Slave, it has the option of attaching an address header at the beginning of each packet. Option 2 will attach two bytes of binary data that represent the Slave Unit Address. The first byte is MSB. Option 3 will attach five bytes of data that represent the text version of the Slave Unit Address. The Maximum Packet Size includes the Address Header. For example, if the Maximum Packet Size is set to 128 and the Text Address Header option is selected, then the Master will tell the Slave to send a maximum of 123 bytes. No address header is attached when Option 1) is used. In this case, it is up to the equipment connected to the Slave to attach an address header of some sort so that the Master equipment can determine the source of the data transmission. S Register 115 - Packet Repeat Interval A parameter that is specific to the Slave in multipoint operation is the Repeat Interval. The allowable settings are:

1 2 3 4 5 6 7

*8 1...1 1...3 1...7 1...15 1...31 1...63 1...127 1...255 This parameter defines a range of random numbers that the Slave will use as the next slot in which it will attempt to send the packet. For example, if Option 3 (1...7) is selected, and the random number generator picks 5, then the Slave will transmit after five time slots. A Slave will transmit a maximum of once per hopping interval. The Slave will transmit more frequently when a Repeat Interval with a smaller range is selected. Choose 1) for the most frequent repeats and choose 8) for the least frequent repeats. 18 MHX-900 Operating Manual: Chapter 3 Configuration Options A. Modem Command Summary The following provides a command summary for the MHX-900 module. Factory settings are denoted with a *. I O Q V W Z

&C

&D

&F

&K

&S AT Commands A D E Answer Dial Command Echo E0 No Echo

* E1 Command Echo Identification I0 Product Code I1 Checksum I2 ROM Checksum I3 Product ID I4 Not Supported I5 Firmware Version On-line Mode Quiet Mode

* Q0 Enables Result Codes Q1 Disables Result Codes Result Codes Display V0 Display as Numbers

* V1 Display as Words Connection Result

* W0 Reports DTE as CONNECT xxxx W1 Reports computer (DTE) rate and wireless rate between modems as CARRIER xxxx. W2 Reports DCE as CONNECT xxxx Reset and load stored configuration DCD (Data Carrier Detect)

&C0 DCD is always on

* &C1 DCD is on when modems are synchronized DTR (Data Terminal Ready)

&D0 DTR ignored

* &D2 DTR disconnects and switches to command

&D3 DTR disconnects and resets modem Load Factory Default Handshaking

&K0 Disable Handshaking

* &K3 Enable Handshaking DSR (Data Set Ready)

&S0 DSR is always on

* &S1 DSR on in data, off in command mode View Configuration Write configuration to memory Read S register value

&V

&W Sxx?

Sxx=yy Set S register value Result Codes OK 0 CONNECT 1 2 RING NO CARRIER 3 ERROR 4 NO ANSWER 8 CONNECT 2400 10 11 CONNECT 4800 CONNECT 9600 12 CONNECT 19200 14 CONNECT 38400 17 CONNECT 57600 18 33 CONNECT 115200 S Registers S0 S2 S3 S4 S5 S101 Number of Rings - Auto Answer [0...255]

Escape code [0...255] default +

CR character [0...255] default <cr>

Line Feed [0...255] default <lf>

Backspace [0...255] default <bs>

Operating Mode 1 - Master point to point

* 2 - Slave point to point 3 - Master point to multipoint 4 - Slave point to multipoint Serial Baud Rate 1 = 115200, 2 = 57600, 3 = 38400 4 = 28800, 5 = 19200, 6 = 14400

* 7 = 9600, 8 = 7200, 9 = 4800, 10 = 3600, 11 = 2400 Wireless Link Rate

*1 = Turbo, 2 = Fast, 3 = Normal Network Address [0...65535]

Unit Address [0...65535]

Hopping Pattern [1...20]

Encryption Key [0...65535]

Output Power Level

* 0 = 1 mW, 1 = 10 mW, 2 = 100 mW 3 = 1000 mW Hopping Interval 1 = 25 msec, 2 = 50 msec, 3 = 100 msec, 4 = 150 msec, * 5 = 200 msec, 6 = 250 msec, 7 = 300 msec, 8 = 350 msec Packet Minimum Size [0...Maximum Size]

Packet Maximum Size [1...255]

Packet Retry Transmissions [0...255]

Address Header

* 0 = Disabled, 1 = Binary, 2 = Text Packet Repeat Interval 1 = 1...1, 2 = 1...3, 3 = 1...7, 4 = 1...15 5 = 1...31, 6 = 1...63, 7 = 1...127, * 8 = 1...255 S102 S103 S104 S105 S106 S107 S108 S109 S111 S112 S113 S114 S115 MHX-900 Operating Manual: Appendix A Modem Command Summary 19 20 MHX-900 Operating Manual: Appendix A Modem Command Summary B. Serial Interface The MHX-900 module uses 8 pins on the 40 pin connector for asynchronous serial I/O. The interface conforms to TTL level RS-232 signals (ie. without level shifting), so direct connection to a host microprocessor is possible. The signals in the asynchronous serial interface are described below:

DCD Data Carrier Detect - Output from Modem - When asserted (TTL low), DCD informs the DTE that a communications link has been established with another MHX-900. Receive Data - Output from Modem - Signals transferred from the MHX-

900 are received by the DTE via RX. Transmit Data - Input to Modem - Signals are transmitted from the DTE via TX to the MHX-900. RX TX DTR Data Terminal Ready - Input to Modem - Asserted (TTL low) by the DTE to inform the modem that it is alive and ready for communications. Signal Ground - Provides a ground reference for all signals transmitted by both DTE and DCE. SG DSR Data Set Ready - Output from Modem - Asserted (TTL low) by the DCE to inform the DTE that it is alive and ready for communications. DSR is the modems equivalent of the DTR signal. RTS Request to Send - Input to Modem - A handshaking signal which is asserted by the DTE (TTL low) when it is ready. When hardware handshaking is used, the RTS signal indicates to the DCE that the host can receive data. CTS Clear to Send - Output from Modem - A handshaking signal which is asserted by the DCE (TTL low) when it has enabled communications and transmission from the DTE can commence. When hardware handshaking is used, the CTS signal indicates to the host that the DCE can receive data. Notes:

It is typical to refer to RX and TX from the perspective of the DTE. This should be kept in mind when looking at signals relative to the modem (DCE); the modem transmits data on the RX line, and receives on TX. DCE and modem are often synonymous since a modem is typically a DCE device. DTE is, in most applications, a device such as a host microprocessor. Modem

(DCE) 21 22 23 24 17 26 27 28 Signal DCD RX TX DTR SG DSR RTS CTS Host Microprocessor

(DTE) IN IN OUT OUT IN OUT IN Arrows denote the direction that signals are asserted

(e.g., DCD originates at the DCE and tells the DTE that a carrier is present). MHX-900 Operating Manual: Appendix B Serial Interface 21

22 MHX-900 Operating Manual: Appendix B Serial Interface C. Sample Schematic Diagram The following is a sample microprocessor implementation with a MICROCHIP PIC 16C74 and the MHX-900. The MHX-900 performs no level shifting on the serial port, so direct connection to the host microprocessor is possible. DO NOT CONNECT THE MHX-900 TO RS 232 DRIVER OUTPUTS. DAMAGE TO THE UNIT MAY RESULT. On this implementation, the onboard SCI of the PIC 16C74 is directly connected pins 22 and 23 of the MHX-900. The bi-

directional Port D is used for asserting or monitoring control signals from the MHX-900. The RESET signal is a momentary active low signal asserted by the host microprocessor. RESET initializes the MHX-900 and places the system in a known state. This signal should be set high after the host microprocessor has been reset. PIC16C74 MHX-900 RC7 RC6 RD0 RD1 RD2 RD3 RD4 RD6 RXD TXD DCD DTR DSR RTS CTS RESET 22 23 21 24 26 27 28 10 Power Connections are not shown MHX-900 Operating Manual: Appendix C Sample Schematic Diagram 23 24 MHX-900 Operating Manual: Appendix C Sample Schematic Diagram D. Modem Setup Overview The required commands required to setup an MHX-900 module for point-to-point and point-to-multipoint are summarized below. These requirements will get you started and only ensure that a link can be established, but do not necessarily provide the best performance. Point-to-Point To establish a point-to-point communications link, the following commands must be issued by the host EOM microprocessor:

n The Operating Mode S Register (S101) for one modem must be configured as a Master - Point-to-Point

(1), and the other as a Slave - Point-to-Point (2). n The Wireless Link Rate S Register (S103) value for both modems must be the same. n The Network Address S Register (S104) value assigned for both modems must be the same. n The Unit Address S Register (S105) value assigned for both modems must be the same. n The same Hopping Pattern S Register (S106) value must be selected for both modems. n The same Hopping Interval S Register (S109) value must be selected for both modems. n The same Encryption Key S Register (S107) value must be selected for both modems. The master can now attempt to synchronize with the slave using the D<slave address> command. Point-to-Multipoint To establish a point-to-point communications link, the following commands must be issued by the host OEM microprocessor:

n The Operating Mode S Register (S101) for one modem must be configured as a Point-to-Multipoint Master (3), and the other as a Point-to-Multipoint Slave (4). n The Wireless Link Rate S Register (S103) value for both modems must be the same. n The Network Address S Register (S104) value assigned for both modems must be the same. n Each Slave must be assigned an unique Unit Address S Register (S105) value (Unit Address 0 is not supported). n The same Hopping Pattern S Register (S106) value must be selected for both modems. n The same Hopping Interval S Register (S109) value must be selected for both modems. n The same Encryption Key S Register (S107) value must be selected for both modems. The master can now attempt to synchronize with the slave using the D<slave address> command. MHX-900 Operating Manual: Appendix D Modem Setup Overview 25 26 MHX-900 Operating Manual: Appendix D Modem Setup Overview E. Technical Specifications Data Interface RS-232 Signals Other Signals User Interface Bandwidth / Data Rate Communications Range Power Requirements Power Consumption Operating Frequency System Gain Sensitivity Output Power Spreading Code Hopping Patterns Error Detection Dimensions (WxDxH) Weight Operating Environment Electrical/Physical Asynchronous Serial Port, TTL Levels Sig. Gnd, TX, RX, DCD, DSR, DTR, RTS, CTS Reset, RxMode, TxMode, RSSI1, RSSI2, RSSI3

(All except Reset are status signals) AT Command line interface 2,400 - 115,200 bps, uncompressed half-duplex, Approx. 100 kbps sustained in intelligent asymmetrical full-duplex transmission mode Up to 30 kilometres (19 miles) line of sight 4.75 to 5.5 VDC 5500 mA at 1 W transmit, 220 mA receive 902 - 928 MHz 135 dB

-105 dBm 1mW, 10mW, 100mW, 1W (user-selectable) Frequency Hopping 20 pseudo-random, user-selectable CRC-16 with auto re-transmit Encl: 2.1 x 3.5 x 0.75 (53 mm x 89 mm x 19 mm) 75 grams Temperature: -40 to +65C Humidity: 5 to 95%, non-condensing MHX-900 Operating Manual: Appendix E Technical Specifications 27 28 MHX-900 Operating Manual: Appendix E Technical Specifications Terminology Used in the MHX-900 Operating Manual F. Glossary Asynchronous communications A method of telecommunications in which units of single bytes of data are sent separately and at an arbitrary time

(not periodically or referenced to a clock). Bytes are padded with start and stop bits to distinguish each as a unit for the receiving end, which need not be synchronized with the sending terminal. Attenuation The loss of signal power through equipment, lines/cables, or other transmission devices. Measured in decibels (dB). Bandwidth The information-carrying capacity of a data transmission medium or device, usually expressed in bits/second (bps). Baud Unit of signaling speed equivalent to the number of discrete conditions or events per second. If each signal event represents only one bit condition, then baud rate equals bits per second (bps) this is generally true of the serial data port, so baud and bps have been used interchangeably in this manual when referring to the serial port; this is not always the case during the DCE-to-DCE communications, where a number of modulation techniques are used to increase the bps rate over the baud rate. Bit The smallest unit of information in a binary represented by either a 1 or 0. system, Abbreviated b. Bits per second (b/s or bps) A measure of data transmission rate in serial communications. Also see baud. Byte A group of bits, generally 8 bits in length. A byte typically represents a character of data. Abbreviated B. Characters per second (cps) A measure of data transmission rate for common exchanges of data. A character is usually represented by 10 bits: an 8-

bit byte plus two additional bits for marking the start and stop. Thus, in most cases (but not always), cps is related to bits per second (bps) by a 1:10 ratio. CRC (Cyclic Redundancy Check) An error-detection scheme for transmitted data. Performed by using a polynomial algorithm on data, and appending a checksum to the end of the packet. At the receiving end, a similar algorithm is performed and checked against the transmitted checksum. Crossover cable (Also known as rollover, null-

modem, or modem-eliminator cable) A cable which allows direct DTE-to-DTE connection without intermediate DCEs typically used to bridge the two communicating devices. Can also be used to make cabled DCE-to-DCE connections. The name is derived from crossing or rolling several lines, including the TX and RX lines so that transmitted data from one DTE is received on the RX pin of the other DTE and vice-versa. to connection Data Communications Equipment (DCE, also referred as Data Circuit-Terminating Equipment, Data Set) A device which facilitates a communications between Data Terminal Equipment (DTEs). Often, two or more compatible DCE devices are used to bridge DTEs which need to exchange data. A DCE performs and conversion of data sent/received by the DTE, and transmits/receives data with another DCE. Common example is a modem. decoding, encoding, signal Data Terminal Equipment (DTE) An end-

device which sends/receives data to/from a DCE, often providing a user-interface for information exchange. Common examples are computers, terminals, and printers. dBm Stands for Decibels referenced to one milliwatt (1 mW). A standard unit of power level commonly used in RF and communications work. n dBm is equal to 10(n/10) milliwatt, so 0dBm = 1mW, -10dBm = 0.1mW, -20dBm =

0.01mW, etc. DCE See Data Communications Equipment. DTE See Data Terminal Equipment. Flow Control A method of moderating the transmission of data so that all devices within the communications link (DTEs and DCEs) transmit and receive only as much data as they can handle at once. This prevents devices from sending data which cannot be received at the other end due to conditions such as a full buffer or hardware not in a ready state. This is ideally handled by hardware using flow-control and handshaking signals, but MHX-900 Operating Manual: Appendix F Glossary 29 many newer devices use a compact 9-pin connector with only the essential signaling lines used in asynchronous serial communications. Lines have two possible states: high (on, active, asserted, carrying +3 to +25 V) or low (off, inactive, disasserted, carrying -3 to -25 V). RTU (Remote Terminal Unit) A common term describing a DTE device which is part of a wide-

area network. Often a RTU performs data I/O and transmits the data to a centralized station. Serial communications A common mode of data transmission whereby character bits are sent sequentially, one at a time, using the same signaling parallel communications where all bits of a byte are transmitted at once, usually requiring a signal line for each bit. Contrast with line. Shielded cable Interface medium which is internally shrouded by a protective sheath to minimize external electromagnetic interference

(noise). Slave A station which is controlled and/or polled by the Master station for communications. Typically represents one end of a point-to-point connection, or one of the terminal nodes in a point-to-

multipoint network. Often a RTU is linked by a Slave DCE. Spread spectrum A method of transmitting a signal over a wider bandwidth (using several frequencies) than the minimum necessary for the originally narrowband signal. A number of techniques are used to achieve spread spectrum telecommunications, including frequency hopping. Spread spectrum provides the possibility of sharing the same band amongst many users while increasing the tolerance to interference and noise, and enhancing privacy of communications. Throughput A measure of the rate of data trans-

mission passing through a data communication system, often expressed as bits or characters per second (bps or cps). can be controlled also by software using X-ON/X-

OFF (transmitter on/off) commands. Frequency-hopping A type of spread spectrum communication whereby the carrier frequency used between transmitter and receiver changes repeatedly in a synchronized fashion according to a specified algorithm or table. This minimizes unauthorized and interception of telecommunications.

(interference) jamming Full-duplex Where data can be transmitted, bi-

independently, and simultaneously directionally. Half duplex Exists when the communications medium supports bi-directional transmission, but data can only travel in one direction at the same time. Handshaking A flow-control procedure for establishing communications whereby data devices indicate that data is to be sent and await appropriate signals that allow them to proceed. Line-of-sight Condition in which a transmitted signal can reach its destination by travelling a straight path, without being absorbed and/or bounced by objects in its path. Master The station which controls and/or polls one or more Slave stations in a point-to-point or point-

to-multipoint network. Often functions as a server or hub for the network. Non-volatile memory Memory which retains information which is written to it. Null modem cable See Crossover cable. Point-to-point A simple communications network in which only two DTEs are participants. Point-to-multipoint A communications network in which a Master DTE communicates with two or more Slave DTEs. Repeater A device which automatically amplifies or restores signals to compensate for distortion and/or attenuation prior to retransmission. A repeater is typically used to extend the distance for which data can be reliably transmitted using a particular medium or communications device. RS-232

(Recommended Standard 232; more accurately, RS-232C or EIA/TIA-232E) Defined by the EIA, a widely known standard electrical and physical interface for linking DCEs and DTEs for serial data communications. Traditionally specifies a 25-pin D-sub connector, although 30 MHX-900 Operating Manual: Appendix F Glossary

MHX-900 SN: 0100073 Microhard Systems, Inc. FCCID: NS999P2 This device complies with Part 15 of the FCC Rules Operation of this device is subject to the following conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. TOP VIEW FCCD LABEL

May 12, 1999 Federal Communications Commission 7435 Oakland Mills Road Columbia, MD 21046 ATTN: Applications Examining Division RE: Microhard Systems, Inc., Certification Application;

FCCID: NS999P2 Gentlemen:

Please find the enclosed application for Certification of a Part 15 Frequency Hopping Spread Spectrum Transmitter module. The Model MHX-900 Embedded Wireless Modem is designed to meet the FCC definition of a SST module. These aspects include RF shielding, buffered data input, power regulation (operates off existing +5 volts rail), unique antenna connector (12" length cable with SMC to reverse gender TNC connectors provided with antenna), FCC testing performed with module in stand-alone configuration and outside of case, and properly labeled with FCCID and interference statement. The MHX-900 does not have a data I/O connector attached to the module, but rather a connection header. Although it contains a modem module along with the radio module, it is up to the actual finished product into which this device is embedded, to provide a data connector. Therefore the MHX-900 is not considered to be a Digital Device Peripheral. The 0.23 meter safe distance limit for 1 mW/cm RF exposure, to be referenced in the user manual page 27, was calculated from FCC OET 65 Appendix B, Table 1B Guidlines for General Population/Uncontrolled Exposure. This calculation was based on the highest EIRP possible from the system, considering maximum power and antenna gain. The formula used was:

S = (Po*G)/(4*pi*r^2) Your consideration is much appreciated. Sincerely, Steven Dayhoff Chief Engineer

The following statement will be presented in the MHX-900 User Manual, page 27:

WARNING In order to comply with the FCC adopted RF exposure requirements, this transmitter system will be installed by the manufacturer's resaler professional. Installation of the high gain yagi antennas must be performed in a manner that will provide at least 0 .23 meters clearance from the front radiating apperature, to any personnel such as employee or member of the public.

NATIONAL CERTIFICATION LABORATORY 8370 Court Avenue, Suite B-1 Ellicott City MD 21043

(410) 461-5548 FCC REPORT OF RADIO INTERFERENCE for Microhard Systems Inc

#209 - 12 Manning Close N.E. Calgary, Alberta Canada FCC ID: NS999P2 May 13, 1999 TABLE OF CONTENTS Application Form 731 FCC Label Drawing and Location Introduction Summary Description of Equipment Under Test (EUT) Test Program Test Configuration Conducted Emissions Scheme Radiated Emissions Scheme 1.0 1.1 2.0 3.0 4.0 5.0 6.0 TABLES Table 1. Table 2. Table 3. EXHIBITS Support Equipment Interface Cables Measurement Equipment Exhibit 1. Exhibit 2. Exhibit 3. Exhibit 4. EUT Photographs Schematic Diagram User Manual Explanation of 15.247(1)/(1)i NCL PROJ.# MICROHARD-500 1.0 Introduction This report has been prepared on behalf of Microhard Systems, Inc., to support the attached Application for Certification of a Part 15 Spread Spectrum Transmitter module. The Equipment Under Test was the Model MHX-900 Wireless Modem Transceiver OEM Module. Radio-Noise Emissions tests were performed according to FCC Public Notice 54797, titled "Guidance on Measurements for Direct Sequence SST". The measuring equipment conforms to ANSI C63.2 Specifications for Electromagnetic Noise and Field Strength Instrumentation. Testing was performed at National Certification Laboratory in Ellicott City, MD. Site description and site attenuation data have been placed on file with the FCC's Sampling and Measurements Branch. FCC acceptance was granted on May 26, 1993. 1.1 Summary The Microhard Systems, Inc. Model MHX-900 complies with the FCC limits (15.247) for a Frequency Hopping SST. 2.0 Description of Equipment Under Test (EUT) The EUT Features:

Reverse TNC Antenna Connector per 15.203

+ 30 dBm RF Output Max. 902 - 928 MHz Freq. Range 350 kHz 20 dB Emission Bandwidth 64 Hopping Channels 400 Khz Channel Separation 172.8 kbps Data Rate (Radio Link) 3 FCC ID #: NS999P2 115.2 kbps Max Data Rate (DCE) 3.0 Test Program This report contains measurement charts and data as evidence for the following tests performed:

1. (15.247 b) Peak RF output power. 2. (15.247 c) Field strength of harmonics and spurious out-of-band emissions. 3. (15.247 c) RF Antenna Conducted of harmonics and spurious out-of-band emissions. 4. (15.247 a) 20 dB Emission Bandwidth. 5. (15.207) Power Line Conducted Emissions. 4.0 Test Configuration RF antenna conducted output tests such as Bandwidth, Spurious/Harmonics, and Power output, were taken with the transmitter antenna connector feeding directly into the spectrum analyzer via external 30 dB attenuator. The analyzer's internal attenuator was adusted to prevent overloading of the front end. The transmitter is modulated at 115.2 kbps which is the highest available data rate. Field strength measurements were taken with the transmitter feeding a yagi, or omni antenna aimed at the receiving measurement antenna. Testing was performed using the highest gain antenna from each design family (yagi, omni) with the power setting at 1 watt for the omni antenna, and 100 mW for the higher gain yagi. 4 FCC ID #: NS999P2 A list of all possible antennas that will be sold with the MRX-900 Wireless Modem is included in Table 1 of this report. PEAK POWER TEST RESULTS Limit: 1.0 watts (30 dBm) Condition: Transmitter is set to a single FM modulated channel Readings from spectrum analyzer with 1 MHz Resolution BW setting:

Channel 1:

902.5 MHz - +29.4 dBm Channel 32: 915.0 MHz - +29.8 dBm Channel 64: 927.8 MHz - +29.2 dBm 5 FCC ID #: NS999P2 SEE FOLLOWING 3 PLOTS OF MODULATED CARRIER

/

PEAK POWER MEASUREMENTS - MODULATED WITH 1 MHZ RES. BW 6 FCC ID #: NS999P2 7 FCC ID #: NS999P2 PEAK POWER MEASUREMENTS - MODULATED WITH 1 MHZ RES. BW 8 FCC ID #: NS999P2 20 dB EMISSION BANDWIDTH Maximum 20 dB BW: 0.500 MHz RBW Setting on S.A.: 10 kHz Condition: Transmitter is set to a single channel FM modulated at 9 FCC ID #: NS999P2 115.2 kbps Readings from spectrum analyzer:

Channel 1:

902.5 MHz - 196 kHz Channel 32: 915.0 MHz - 196 kHz Channel 64: 927.8 MHz - 204 kHz SEE FOLLOWING PLOT 3 PLOTS OF MODULATED CARRIER 10 FCC ID #: NS999P2 20 DB EMISSION BANDWIDTH - MODULATED WITH 10 KHZ RES. BW 11 FCC ID #: NS999P2 20 DB EMISSION BANDWIDTH - MODULATED WITH 10 KHZ RES. BW 12 FCC ID #: NS999P2 13 FCC ID #: NS999P2 RF ANTENNA CONDUCTED SPURIOUS/HARMONICS EMISSIONS Limit: 20 dB below Carrier Level Measured with 100 kHz RBW RBW Setting on S.A.: 100 kHz Condition: Transmitter is set to a single FM modulated channel. RF power = 30 dBm Three separate Measurements are performed to show harmonic and spurious emissions generated with the transmitter tuned to low, 14 FCC ID #: NS999P2 middle, and high parts of the spectral range. SEE FOLLOWING 3 PLOTS & DATA TABLES 15 FCC ID #: NS999P2 FCC PART 15.247(c) - CONDUCTED SPURIOUS EMISSIONS Frequency of Carrier = 902.5 MHz Limit = 20 dBc Condition: Transmitter is set to a single FM modulated channel. TEST RESULTS LIMIT: -20 dB FROM PEAK CARRIER COMPONENT FREQUENCY (MHZ) RESULT (dB FROM PEAK) HARMONIC 1805.00 HARMONIC HARMONIC 2707.50 3610.00 HARMONIC 4512.50 HARMONIC 5415.00

- 58.4

- 62.0

- 73.0

- 73.0

- 74.0 HARMONIC 6317.50

- 75.0 HARMONIC 7220.00 HARMONIC 8122.50 HARMONIC 9025.00

- 75.0

- 75.0

- 75.0 16 FCC ID #: NS999P2 FCC PART 15.247(c) - CONDUCTED SPURIOUS EMISSIONS Frequency of Carrier = 915.00 MHz Limit = 20 dBc Condition: Transmitter is set to a single FM modulated channel. TEST RESULTS LIMIT: -20 dB FROM PEAK CARRIER COMPONENT FREQUENCY (MHZ) RESULT (dB FROM PEAK) HARMONIC 1830.00 HARMONIC HARMONIC 2745.00 3660.00 HARMONIC 4572.00 HARMONIC 5490.00

- 56.8

- 67.0

- 71.0

- 72.0

- 70.0 HARMONIC 6405.00

- 73.0 HARMONIC 7320.00 HARMONIC 8235.00 HARMONIC 9150.00

- 74.0

- 75.0

- 75.0 17 FCC ID #: NS999P2 FCC PART 15.247(c) - CONDUCTED SPURIOUS EMISSIONS Frequency of Carrier = 927.8 MHz Limit = 20 dBc Condition: Transmitter is set to a single FM modulated channel. TEST RESULTS LIMIT: -20 dB FROM PEAK CARRIER COMPONENT FREQUENCY (MHZ) RESULT (dB FROM PEAK) HARMONIC 1855.60 HARMONIC HARMONIC 2783.40 3711.20 HARMONIC 4639.00 HARMONIC 5566.80

- 57.0

- 69.0

- 72.0

- 73.0

- 71.0 HARMONIC 6494.60

- 74.0 18 FCC ID #: NS999P2 HARMONIC 7422.40 HARMONIC 8350.20

- 74.0

- 75.0 HARMONIC 9278.00

- 75.0 CONDUCTED HARMONICS EMISSIONS - MODULATED WITH 100 KHZ RES. BW LOW CHANNEL 19 FCC ID #: NS999P2 0 Fc 2Fc 3Fc 4Fc CONDUCTED HARMONICS EMISSIONS - MODULATED WITH 100 KHZ RES. BW MID CHANNEL 20 FCC ID #: NS999P2 0 Fc 2Fc 3Fc 4Fc 21 FCC ID #: NS999P2 CONDUCTED HARMONICS EMISSIONS - MODULATED WITH 100 KHZ RES. BW HIGH CHANNEL 22 FCC ID #: NS999P2 0 Fc 2Fc 3Fc 4Fc 4.0 Test Configuration RADIATED EMISSIONS The EUT was set up on the center of the test table, in a manner which follows the general guidelines of ANSI C63.4, Section 6

"General Operating Conditions and Configurations". This is described below:

23 FCC ID #: NS999P2 5.0 Conducted Emissions Scheme 24 FCC ID #: NS999P2 The EUT is placed on an 80 cm high 1 X 1.5 m non-conductive table. Power to the RF modem is provided through a Solar Corporation 50

/50 H Line Impedance Stabilization Network bonded to a 2.2 X 2 meter horizontal ground plane, and a 2.2 X 2 meter vertical ground plane. The LISN has its AC input supplied from a filtered AC power source. A separate LISN provides AC power to the peripheral equipment. I/O cables are moved about to obtain maximum emissions. The 50 output of the LISN is connected to the input of the spectrum analyzer and emissions in the frequency range of 450 kHz to 30 MHz are searched. The detector function is set to quasi- peak and the resolution bandwidth is set at 9 kHz, with all post-detector filtering no less than 10 times the resolution bandwidth for final measurements. All emissions within 20 dB of the limit are recorded in the data tables. FCC CLASS B CONDUCTED EMISSIONS DATA EUT: MHX-900 CLIENT: MICROHARD 25 FCC ID #: NS999P2 6.0 Radiated Emissions Scheme The EUT is placed on an 80 cm high 1 X 1.5 meter non-conductive motorized turntable for radiated testing on the 3-

meter open area test site. The emissions from the EUT are measured continuously at every azimuth by rotating the turntable. Guided horn and log periodic broadband antennas are mounted on an antenna mast to determine the height of maximum emissions. The height of the antenna is varied between 1 and 4 meters. Both the horizontal and vertical field components are measured. 26 FCC ID #: NS999P2 The RF spectrum is searched from 30 MHz - 9.280 GHz. The output from the antenna is connected to the input of the preamplifier. The preamp out is connected to the spectrum analyzer. The detector function is set to Peak. The resolution bandwidth of the spectrum analyzer is set at 120 kHz, for the frequency range of 30-1000 MHZ, and 1 MHz for the range of 1 GHz-9 GHz. A 10 Hz video BW setting is used to average readings above 1 GHz. All emissions within 20 dB of the limit are recorded in the data tables. To convert the spectrum analyzer reading into a quantified E-field level to allow comparison with the FCC limits, it is necessary to account for various calibration factors. These factors include cable loss (CL) and antenna factors (AF). The AF/CL in dB/m is algebraically added to the Spectrum Analyzer Voltage in dbV to obtain the Radiated Electric Field in dBV/m. This level is then compared with the FCC limit. Example:

Spectrum Analyzer Volt: VdBuV Composite Factor: AF/CLdB/m Electric Field: EdBV/m = VdBV + AF/CLdB/m Linear Conversion: EuV/m = Antilog (EdBV/m/20) FCC CLASS B RADIATED EMISSIONS DATA CLIENT: MICROHARD EUT: MHX-900 27 FCC ID #: NS999P2 CARRIER: 902.5 MHZ @ 1000 mW ANTENNA: 5 dB OMNI CARRIER: 915 MHZ @ 1000 mW ANTENNA: 5 dB OMNI 28 FCC ID #: NS999P2 CARRIER: 927.8 MHZ @ 1000 mW ANTENNA: 5 dB OMNI CARRIER: 902.5 MHZ @ 100 mW ANTENNA: 14 dB YAGI 29 FCC ID #: NS999P2 CARRIER: 915 MHZ @ 100 mW ANTENNA: 14 dB YAGI CARRIER: 927.8 MHZ @ 100 mW ANTENNA: 14 dB YAGI 30 FCC ID #: NS999P2 Table 1 Support Equipment 14 dB Yagi Antenna - Sinclabs - SUY-90213 12 dB Yagi Antenna - Sinclabs - SUY-90211 8 dB Yagi Antenna - Sinclabs - SUY-90207 2.5 dB Omni Antenna - 900 MHz Rubber Ducky 5 dB Omni Antenna - Sinclabs 31 FCC ID #: NS999P2 Host PC - Toshiba 740C Pentium Notebook Table 2 Interface Cables Used 1. A 1.2 meter RS-232 serial shielded cable is used to connect the EUT to the Host computer. 2. 1 feet of low-loss coaxial cable used to connect the EUT to the TX antenna (Reverse TNC to SMC connectors). 32 FCC ID #: NS999P2 Table 3 Measurement Equipment Used The following equipment is used to perform measurements:

HP 435A RF Peak Power Meter

- Serial No. 1362016 EMCO Model 3110 Biconical Antenna

- Serial No. 1619 Antenna Research MWH-1825B Horn Antenna

- Serial No. 1005 EMCO Model 3115 Ridged Horn Antenna

- Serial No. 3007 HP 8348A Preamplifier

- Serial No. 197-2564A Solar 8012-50-R-24-BNC LISN

- Serial No. 924867 Bird 8306-300-N 30dB Attenuator

- S/N: 29198391515 HP 14IT w/8555A Spectrum Analyzer

- Serial No. 6-95-1124 4 Meter Antenna Mast Motorized Turntable Heliax FSJ1-50A 1/4" Superflex Coax Cable (12 Ft.) FCC ID #: NS999P2 FCC ID #: NS999P2

RF Exposure Calculations:

The following information provides the minimum seperation distance for each of the antennas provided with the MHX-900 module, as calculated from FCC OET 65 Appendix B, Table 1B Guidlines for General Population/Uncontrolled Exposure. This calculation is based on the highest EIRP possible from the system, considering maximum power and antenna gain. The formula used was:

S = (Po*G)/(4*pi*r^2) S = 0.6 mW/cm^2 for 902 MHz (from F/1500) Where Where Po = 100 mW for Yagi antennas (max. power set at factory) Where Po = 1.0 Watt for Omni antennas (max. power user configurable) For: 14 dB Yagi Antenna - Sinclabs - SUY-90213 ....... r = 18 cm 12 dB Yagi Antenna - Sinclabs - SUY-90211 ....... r = 15 cm 8 dB Yagi Antenna - Sinclabs - SUY-90207 ....... r =

9 cm 2.5 dB Omni Antenna - 900 MHz Rubber Ducky ...... r = 15 cm 5 dB Omni Antenna - Sinclabs ....................r = 20 cm The following statement will be presented in the MHX-900 User Manual, page 27:

WARNING In order to comply with the FCC adopted RF exposure requirements, this transmitter system will be installed by the manufacturer's resaler professional. Installation of the high gain yagi antennas must be performed in a manner that will provide at least 18 cm clearance from the front radiating apperature, to any personnel such as employee or member of the public. Installation of the omni whip antennas must be performed in a manner that will provide at least 20 cm clearance from the whip, to any personnel such as employee or member of the public.

May 12, 1999 Federal Communications Commission 7435 Oakland Mills Road Columbia, MD 21046 ATTN: Applications Examining Division RE: Microhard Systems, Inc., Certification Application;

FCCID: NS999P2 Gentlemen:

Please find the enclosed application for Certification of a Part 15 Frequency Hopping Spread Spectrum Transmitter module. The Model MHX-900 Embedded Wireless Modem is designed to meet the FCC definition of a SST module. These aspects include RF shielding, buffered data input, power regulation (operates off existing +5 volts rail), unique antenna connector (12" length cable with SMC to reverse gender TNC connectors provided with antenna), FCC testing performed with module in stand-alone configuration and outside of case, and properly labeled with FCCID and interference statement. The MHX-900 does not have a data I/O connector attached to the module, but rather a connection header. Although it contains a modem module along with the radio module, it is up to the actual finished product into which this device is embedded, to provide a data connector. Therefore the MHX-900 is not considered to be a Digital Device Peripheral. The 0.23 meter safe distance limit for 1 mW/cm RF exposure, to be referenced in the user manual page 27, was calculated from FCC OET 65 Appendix B, Table 1B Guidlines for General Population/Uncontrolled Exposure. This calculation was based on the highest EIRP possible from the system, considering maximum power and antenna gain. The formula used was:

S = (Po*G)/(4*pi*r^2) Your consideration is much appreciated. Sincerely, Steven Dayhoff Chief Engineer

RF Exposure Calculations:

The following information provides the minimum seperation distance for each of the antennas provided with the MHX-900 module, as calculated from FCC OET 65 Appendix B, Table 1B Guidlines for General Population/Uncontrolled Exposure. This calculation is based on the highest EIRP possible from the system, considering maximum power and antenna gain. The formula used was:

S = (Po*G)/(4*pi*r^2) S = 0.6 mW/cm^2 for 902 MHz (from F/1500) Where Where Po = 100 mW for Yagi antennas (max. power set at factory) Where Po = 1.0 Watt for Omni antennas (max. power user configurable) For: 14 dB Yagi Antenna - Sinclabs - SUY-90213 ....... r = 18 cm 12 dB Yagi Antenna - Sinclabs - SUY-90211 ....... r = 15 cm 8 dB Yagi Antenna - Sinclabs - SUY-90207 ....... r =

9 cm 2.5 dB Omni Antenna - 900 MHz Rubber Ducky ...... r = 15 cm 5 dB Omni Antenna - Sinclabs ....................r = 20 cm The following statement will be presented in the MHX-900 User Manual, page 27:

WARNING In order to comply with the FCC adopted RF exposure requirements, this transmitter system will be installed by the manufacturer's resaler professional. Installation of all antennas must be performed in a manner that will provide at least 20 cm clearance from the front radiating apperature, to any personnel such as employee or member of the public.