FCC ID: AZP-FDQ02T2 Wireless Modem with Serial Interface

 

WIRELESS DATA COMMUNICATION MODEM FDQ02T Wireless Modem with Serial Interface Instruction Manual i Futaba Corporation Industrial Radio Control I Notice I.I FCC Notice 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, and (2) this device must accept any interference received, including interference that may cause undesired operation. This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. Any unauthorized changes or modifications to this device not expressly approved by Futaba Corporation could void the users authority to operate the device and possibly result in damage to the equipment and/or cause serious or fatal injuries to the operator or nearby personnel. This device is intended to be installed and used in accordance with the instructions contained in this manual. Failure to comply with these instructions could void the users authority to operate the device and possibly result in damage to the equipment and/or cause serious or fatal injuries to the operator or nearby personnel. I.II IC Notice This device complies with Industry Canada license-exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device. This equipment complies with IC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance 20cm between the radiator and your body.

(French) Cet appareil radio est conforme au CNR-210 dIndustrie Canada. Lutilisation de ce dispositif est autorise seulement aux deux conditions suivantes : (1) il ne doit pas produire de brouillage, et (2) lutilisateur du dispositif doit tre prt accepter tout brouillage radiolectrique reu, mme si ce brouillage est susceptible de compromettre le fonctionnement du dispositif. Cet quipement est conforme aux limites dexposition aux rayonnements IC tablies pour un environnement non contrl. Cet quipement doit tre install et utilis avec un minimum de 20 cm de distance entre la source de rayonnement et votre corps. ii II Important Safety Information The list of dangers, warnings and cautions in this section contain important information that will help ensure safe operation of the system. Please read carefully and understand all of these items. All installers, operators and maintenance personnel should read and understand this information before installation, use, or maintenance of the FDQ02T system. The FDQ02T system by itself is not inherently dangerous. HOWEVER, WHEN THE FDQ02T IS CONNECTED TO OTHER EQUIPMENT FOR THE PURPOSE OF CONTROL, SAFETY AND ALL POSSIBLE ASSOCIATED DANGERS MUST ALWAYS BE GIVEN THE UTMOST CONSIDERATION DURING SYSTEM INTEGRATION, DESIGN, INSTALLATION, AND USE. The FDQ02T system may be used in virtually unlimited applications. Many of these associated systems can, by themselves, pose a mechanical, electrical or other hazard to operators and other persons or equipment. To address all possible applications and associated safety hazards in this manual would be impossible. The warnings below and throughout this manual give information that will allow safe installation and use the modem system applications. If you have questions regarding the safety of your specific application, please contact the appropriate people for help. Your Futaba sales representative, representatives of the equipment being controlled, and the technical support staff at local branch of Futaba Corporation are among those who can provide assistance with your safety concerns. The following warnings are included in the lists that follow but warrant repetition here:

In installations where the FDQ02T system is used to control motion or operation of potentially dangerous equipment, it is imperative for safety that all operators and installers be thoroughly trained in the normal function of that equipment before attempting to control it remotely with the FDQ02T system. To help ensure safe operation of the equipment, the FDQ02T system must be connected so that it will operate in a fail-safe way. In other words, the equipment being controlled should stop or return to its safest state in the absence of a control signal or total loss of RF transmission from the FDQ02T system. Our system uses one of the most reliable methods available to transmit data using radio signals. Many factors can affect a radio signal that may block it or interfere enough to disrupt regular transmission. Because of this, equipment motion or dangerous electrical current, for example, that continues during a loss-of-signal condition could be very dangerous. iii Four symbols are used in the margin of the following section and throughout the manual to indicate the level of hazard or information listed. The symbols are defined as follows:

Indicates a hazard that will cause severe personal injury, death, or substantial property damage if the warning is ignored. Indicates a hazard that can cause severe personal injury, death, or substantial property damage if the warning is ignored. Indicates a hazard that will or can cause minor personal injury, or property damage if the warning is ignored. Indicates installation, operation, or maintenance information that is important but not hazard-related. Please read the following safety information carefully. Some of these notices are duplicated throughout the manual, in areas of associated content, for your benefit. II.I General Safety Hazards and Notes Improper installation and/or operation of the FDQ02T system can cause serious or fatal injuries to the operator or nearby persons and cause damage to the FDQ02T system, and any equipment it is used to control. Please read and understand this manual completely and the manual of all equipment being controlled before attempting to operate or install this system. Always keep this manual at a location readily accessible to anyone operating the system and related equipment. Ensure that all operators have read and understood this manual, especially all safety and operation procedures contained in it. Please refer to the section in this manual titled How to Obtain Help for the contact that can supply additional manuals or answers to questions not covered in this manual. If this product is passed on to a different user, be sure that this manual accompanies the product. Be certain that the installer of this equipment reads and understands the instruction manual of the equipment that is being connecting to before attempting this installation. The FDQ02T should NOT be used in a manner in which failure of the product or loss of the radio signal could cause damage to the iv equipment being controlled, or to anything in the area in which such equipment is located. All integrated control systems should be designed for fail-safe operation so that a temporary or permanent loss of signal will not endanger any person, critical process, or equipment (refer to the beginning of the safety section for further explanation). The system design should ensure that the equipment being controlled will default to its safest state in the event of signal loss. The FDQ02T contains no user serviceable parts. If the unit requires service, contact your sales representative or local branch of Futaba Corporation per instructions the section titled How To Obtain Help. Do not disassemble or attempt to repair the FDQ02T yourself. Doing so could void your warranty and may void the users authority to operate the device. Contact Futaba before using the FDQ02T in safety critical applications such as medical equipment, aircraft, hazardous materials handling, etc. II.II Installation Safety Hazards and Notes When mounting the FDQ02T, use M2.6 (ISO) screws. Use only the proper regulated DC voltage supplied to the FDQ02T. Use of any other voltage may permanently damage the modem and/or cause the modem to malfunction and create a shock or fire hazard. Be certain that all AC power outlets used the power adapters have been properly installed, grounded, and fused. An electrical shock hazard may exist if this unit is powered by a faulty power outlet or source. If such a situation is discovered, immediately discontinue use until the power source and outlet have been properly installed, grounded, and fused by an electrician or other authorized person. Be sure to wire the power and serial connections correctly. Incorrect wiring can damage the system, cause it to malfunction and/or create a shock and fire hazard. Ensure that the FDQ02T power and the power to the equipment to be controlled is turned off before connecting or disconnecting the cable between them. This will help prevent accidental damage to the system and unexpected operation and/or injury. v Be sure the FDQ02T power, the power to the equipment that is being connecting to it, and the DC power source are all turned off before wiring and connecting the power cable. Be sure that the supplied power is within the specified range (3.5 to 7.0 VDC). Voltages outside the specified range may damage the FDQ02T. Be sure that the power source has sufficient current capacity. Insufficient current may cause the unit to malfunction. Securely attach the antenna cable, and serial communication connector to the FDQ02T and equipment/power source to which it is connected. Failure to do so could cause an unexpected system failure. II.III Antenna Installation Hazards and Notes This radio transmitter (identify the device by certification number or model number if Category II) has been approved by Industry Canada to operate with the antenna types listed below with the maximum permissible gain indicated. Antenna types not included in this list, having a gain greater than the maximum gain indicated for that type, are strictly prohibited for use with this device.

(1)ANTB18-096A0

(2)TK-1619A

(3)TRAB24003 Be sure to keep all systems and antennas clear of power lines. Permanent equipment damage and severe shock injury or death can occur if the system contacts power lines. This device has been designed to operate with an antenna having a maximum gain of 2.14 dB. Antenna having a higher gain is strictly prohibited for use with this device. The required antenna impedances 50 ohms. Contact Futaba before connecting any antenna not provided by Futaba specifically for the FDQ02T. Attaching any non-authorized antenna may be in violation of FCC regulations. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that permitted for successful communication. vi Before each use, verify that the antenna (and antenna cable, if used) is securely attached and in good condition. A loose antenna or cable may severely reduce the operating range of the system. The FDQ02T operates at frequencies in the 2.4 GHz band. These frequencies are more directional than lower frequencies and are easily reflected. If there are metal structures nearby, the effective range may be shortened or the directional properties may be further narrowed. To help avoid this, mount the antenna as far away as possible from surrounding metallic structures. Multipath problems occur easily at frequencies in the 2.4 GHz band. When multipath problems are present, moving the antenna as little as 10 cm may result in improved communication or, conversely, worsened or complete loss of communication. Futaba recommends that the mounting position of the antenna be determined after testing and verifying optimal communication conditions. When installing multiple FDQ02T systems that will use different frequency pattern number in the same area, these antennas must be mounted at least 6 feet (2 meters) apart. Failure to do so may severely reduce the modem operating range. Please contact Futaba for information about antenna separation when using the FDQ02T and other wireless products in the same area. vii II.IV Environmental Safety Hazards and Notes If the FDQ02T has been stored at a temperature beyond the specified operating temperature range for the system, it may not function properly. Allow it to return to normal temperatures before use. Refer to APPENDIX A TECHNICAL SPECIFICATIONS for the actual operating temperature range. The FDQ02T is a precision electronic device with a rugged design that is intended for industrial applications. However, do not install it where it will encounter excessive vibrations. In some cases, isolation mounts may be used to isolate the modem from the equipments vibration. Excessive vibration can permanently damage the modem and/or cause it to malfunction. Do not operate the FDQ02T in environments where it will be subjected to excessive moisture (such as rain or water spray), dust, oil, or other foreign matter (such as metal particles). Doing so may permanently damage the modem and/or cause it to malfunction. If it does become wet or contaminated, correct the situation, verify proper operation and have any problems corrected before using it to control other equipment. If necessary, the modem can be mounted inside a protective or waterproof enclosure. If the enclosure is metallic, the antenna must be mounted externally or the effective operating range will be severely limited. The FDQ02T is designed for indoor use. When using it outdoors, the modem should be mounted in a waterproof enclosure and the ambient temperature range should be checked to insure that it is within the modems specifications. Always use the modem within its specified environmental ranges. II.V Other Notice Italicized gothic word used in this manual shows functional and technical term especially important for the FDQ02T. The device must contain the following permanent labeling on the exterior of the device as follows:

Contains: FCC ID:AZP-FDQ02T2 Contains: ID : 2914D-FDQ02T2 viii Operational Safety Hazards and Notes Before each use of the FDQ02T, ensure that the area where the equipment will be operated is clear of people or obstacles that may affect its safe operation. Before each use of the FDQ02T, verify that both the equipment being controlled and the modem are in proper operating condition. When rewriting the FDQ02Ts memory registers, do not turn its power off until it returns a P0 response. If the power is interrupted before a P0 response is returned, the memory contents may be lost or corrupted and it operation will be unpredictable. If the memory contents are lost or corrupted, they may be restored to original default settings by reinitializing them. (See p.25 Memory REGISTER INITIALIZATION for more details.) Do not attempt to operate remotely controlled equipment outside the communication range of the FDQ02T system. Doing so could cause loss of control of the equipment. Without implementing proper serial communication flow control settings, the baud rate between the modem and its terminal equipment (wire linked) can exceed the wireless link data rate and cause the modem buffer to overflow. This can result in malfunction of the systems being controlled and/or data corruption. Ensure that the appropriate flow control settings are being used for your upper layer application protocol. Exposure to Radio Frequency Radiation For FCC RF safety requirements a minimum of 20 cm separation distance should be kept between the antenna and the user. ix III System Identification For future reference, please take a moment to fill in the information below. This information will help us respond as quickly as possible should your FDQ02T modem ever need repair or replacement. Model Name and Number:

FDQ02T Serial Number:

Date of Purchase:

Distributor Name:

Distributor Address:

Distributor Phone Number:

x IV Limited Warranty ANY IMPLIED DISCLAIMS WARRANTY FUTABA WARRANTS ONLY THAT THE INDUSTRIAL RADIO CONTROL SYSTEM GOODS OR PRODUCTS FURNISHED HEREWITH SHALL BE FREE FROM DEFECTS IN MATERIAL AND WORKMANSHIP UNDER NORMAL CONDITIONS OF USE AND SERVICE FOR A PERIOD OF ONE (1) YEAR FROM THE DATE OF SALE TO THE PURCHASER WHO IS THE FIRST BUYER OF THE GOODS FOR USE OR CONSUMPTION AND NOT FOR RESALE OTHER THAN AS A COMPONENT OF ANOTHER PRODUCT MANUFACTURED FOR SALE BY SUCH PURCHASER

(CONSUMER). FUTABAS LIABILITY, WHETHER BASED ON BREACH OF WARRANTY OR NEGLIGENCE, SHALL BE LIMITED, AT FUTABAS ELECTION, TO REPLACEMENT OR REPAIR OF ANY SUCH NONCONFORMING GOODS, F.O.B. FUTABAS U.S.A. PLANT, OR, AT FUTABAS ELECTION, CREDIT FOR THE NET PURCHASE PRICE OF SUCH GOODS. ALL CLAIMS HEREUNDER MUST BE MADE IN WRITING DURING THE WARRANTY PERIOD, AND FUTABA SHALL HAVE THE RIGHT PRIOR TO ANY RETURN OF GOODS TO INSPECT ANY GOODS CLAIMED TO BE NONCONFORMING, AND IN ANY EVENT RESERVES THE RIGHT TO REJECT CLAIMS NOT COVERED BY WARRANTY. THIS LIMITED WARRANTY CONSTITUTES FUTABAS SOLE WARRANTY. FUTABA MAKES NO OTHER WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, AND EXPRESSLY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. FUTABAS WARRANTY SHALL NOT APPLY IF, AMONG OTHER LIMITATIONS CONTAINED HEREIN OR FURNISHED WITH THE PRODUCT, BUYER, OR CONSUMER, OR ANY USER OF THE PRODUCT (A) ALTERS SUCH PRODUCT, OR (B) REPLACES ANY PART OF SUCH PRODUCT WITH ANY PART OR PARTS NOT FURNISHED BY FUTABA FOR THAT PURPOSE, OR IF, AMONG SUCH OTHER LIMITATIONS, PRODUCT FAILS TO OPERATE PROPERLY OR IS DAMAGED DUE TO ATTACHMENTS OR COMPONENTS THAT ARE NOT FURNISHED BY FUTABA FOR USE WITH OR REPAIR OF THE PRODUCT UNLESS SUCH USE IS AUTHORIZED IN WRITING IN ADVANCE BY FUTABA. THIS LIMITED WARRANTY EXTENDS ONLY TO THE CONSUMER AND IS NOT ASSIGNABLE OR TRANSFERABLE. This limited warranty shall not apply to fuses, lamps, batteries, or other items that are expendable by nature, unless otherwise expressly provided. This limited warranty does not cover any defect or damage to any of the goods caused by or attributable to force, accident, misuse, abuse, faulty installation, improper maintenance, improper electrical current, failure to install or operate in accordance with Futabas written instructions, repair or alteration by unauthorized persons, or leaking batteries. THE GOODS ARE SENSITIVE ELECTRONIC DEVICES REQUIRING SPECIAL HANDLING, AND THIS LIMITED WARRANTY DOES NOT APPLY TO PRODUCTS NOT HANDLED IN ACCORDANCE WITH INSTRUCTIONS SET FORTH IN THE MANUAL. THIS LIMITED WARRANTY DOES NOT COVER INDUSTRIAL RADIO CONTROL PRODUCTS PURCHASED OR USED OUTSIDE OF THE UNITED STATES WITHOUT FUTABAS PRIOR APPROVAL. xi V Returns Futabas authorization must be obtained prior to return of any item for warranty or other repair or replacement or credit and will reflect Futabas warranty service procedure. Consumers warranty rights are governed by the terms of Futabas Limited Warranty, as above described. Products returned for warranty repair or replacement or credit must be carefully and securely packed for return, preferably in the original carton or equivalent. The Consumer must also include in the carton a legible copy of the bill of sale or invoice which shows the date of sale and the original Buyers and Consumers names, and also a letter which gives the Consumers return address and contact telephone number, the model and serial numbers of the product(s) returned, and a brief explanation of the problem or claimed defect. Any returned products that are replaced by Futaba shall become the property of Futaba. If after inspection Futaba determines the defect is not covered by its limited warranty, Futaba will notify Consumer of its determination and will not undertake any repairs or product replacement until Consumer agrees to pay for all necessary parts and materials, labor (to be charged at Futabas standard repair rate then in effect), and other expenses including all shipping charges and insurance. Futaba reserves the right to retain possession of any product returned by Consumer because of defects not covered by Futabas warranty until Futaba receives Consumers agreement as above noted or, if Consumer wants the product returned without repair or replacement, Consumer reimburses Futaba for all shipping and handling charges incurred by Futaba. Issuance of credit for returned items shall be made at Futabas unfettered discretion. Consumer will not be entitled to return defective goods for cash refunds. Consumer must inspect goods immediately and no rejection or revocation of acceptance shall be permitted more than ten

(10) days after delivery to, or first use by, Consumer of the goods, whichever occurs first. VI Patents Copyrights Trademarks Proprietary Rights If this product was manufactured according to designs or processes specified by Consumer, Consumer shall indemnify and save Futaba, its affiliates, officers, agents, and employees, harmless from any expense, loss, attorneys fees, costs, damages, or liability which may be incurred as a result of actual or alleged infringement of patent, copyright, or trademark rights. Furnishing of these products does not convey a license, implied or otherwise, under any patent, copyright, or trademark right in which Futaba has an interest, nor does it convey rights to trade secrets or any other proprietary information of Futaba. VII Limitation of Damages and Action IN NO EVENT SHALL FUTABA BE LIABLE TO CONSUMER, OR ANY OTHER PERSON FOR ANY INCIDENTAL, CONSEQUENTIAL, OR SPECIAL DAMAGES RESULTING FROM THE USE OF OR INABILITY TO USE THIS PRODUCT, WHETHER ARISING FROM BREACH OF WARRANTY OR NEGLIGENCE OF FUTABA, OR OTHERWISE. Any action hereunder must be commenced within one (1) year of accrual of cause of action or be barred and forever waived. No modification or alteration of Futabas Limited Warranty or any other provision of this paragraph or the above paragraphs shall result from Futabas acknowledgment of any purchase order, shipment of goods, or other affirmative action by Futaba toward performance following receipt of any purchase order, shipping order, or other form containing provisions, terms, or conditions in addition to or in conflict or inconsistent with any such provisions. xii TABLE OF CONTENTS 1 INTRODUCTION ............................................................................................. 1 1.1 1.2 1.3 Special Features .................................................................................................. 2 How To Obtain Help ............................................................................................. 3 Physical Description............................................................................................. 4 2 SYSTEM INSTALLATION ............................................................................... 5 2.1 2.2 2.3 2.4 Communication Cable Connection ....................................................................... 6 Reset signal ......................................................................................................... 8 Initialization time .................................................................................................. 8 Other Installation Precautions .............................................................................. 9 3 SYSTEM OPERATION .................................................................................. 11 3.1 3.2 3.3 3.4 3.5 3.6 Packet transmission mode ................................................................................. 12 Header-less Stream mode ................................................................................. 14 Extended Reception mode ................................................................................. 15 Communication time .......................................................................................... 17 Repeater function .............................................................................................. 19 Frequency Channel............................................................................................ 20 4 FUNCTION CONTROL METHODS ............................................................... 21 4.1 4.2 4.3 4.4 4.5 Interface ............................................................................................................ 22 Serial Interface Setting ....................................................................................... 23 Terminal Software Setup for Memory Register Control ....................................... 24 Memory Register Setting.................................................................................... 24 Command Control .............................................................................................. 26 5 MEMORY REGISTER DESCRIPTION .......................................................... 27 5.1 Memory Register Description ............................................................................. 28 6 COMMAND SET DESCRIPTION................................................................... 39 6.1 Command Set Description ................................................................................. 40 7 APPENDIX .................................................................................................... 57 7.1 7.2 7.3 7.4 Conversion Circuit ............................................................................................. 58 Specification of the Connectors .......................................................................... 59 Specification ...................................................................................................... 60 Outline View ...................................................................................................... 62 xiii 1 INTRODUCTION 1 1SECTION 1.1 Special Features The following list highlights some of the special features of the FDQ02T. For more complete system specifications please refer to p.60 SPECIFICATIONS. Approved under FCC Part 15.247 rules -- no special user license required Operating range greater than 3000 feet, line-of-sight -- configurable as a repeater for extended range of application service area 2.4 GHz Direct Sequence Spread Spectrum (DSSS) communication system provides unsurpassed immunity to interference and RF noise Fast switching Time-Division-Duplex (TDD) provides virtual full-duplex communication between terminal equipments at rates up to 115.2kbps User selectable frequency pattern number Supports 1:1, 1:n, and n:m wireless network topology Serial communication interface allows direct connection to a micro controller chip. By converting its level by the external interface circuit, conformable to RS232C, RS422 and RS485 Small size allows easy integration with many systems Supply voltage range is DC voltage in 3.5 to 7.0 V DC (modem) / 6.0 to 9.0 V DC

(Amp.) 2 1.2 How To Obtain Help Please contact your local sales representative or local branch of Futaba Corporation at the address shown below for help with the following:

Application information regarding the FDQ02T or other Futaba products Technical assistance or training Answers to safety questions and issues Additional manuals or other documentation Repair or service Comments regarding the product or this manual Japan Futaba Corporation Radio Control Equipment Group 1080 Yabutsuka, Chosei, Chiba, 299-4395 JAPAN Tel: +81 (475) 32-6173, Fax: +81(475) 32-6179 Internet: www.futaba.co.jp Europe PENDING When requesting repairs, please provide as much detail as possible regarding the failure and its cause or symptoms. Doing so will help our service department find the problem quickly, resulting in a shorter repair time. The FDQ02T contains no user serviceable parts. If the unit requires service, contact your sales representative or local branch of Futaba Corporation as per instructed in this section. Do not disassemble or attempt to repair the modem yourself. Doing so could void your warranty and may void the users authority to operate the device. 3 CAUTION 1.3 Physical Description Please review the following section and take a moment to familiarize yourself with the FDQ02T wireless modem. Communication Connector A Antenna Communication Connector B Mounting Hole Figure 11: Upper View

(1) Used to connect to the DTE(Data Terminal Equipment) with interface cable. Also controlling functions such as hardware reset and RS232C/RS485 selecting pins are available. Signal is CMOS level. Communication Connector A Communication Connector B

(2) It is a power supply of power amplifier input. The control signal is input from the Communication Connector A.

(3) Used to connect to antennas for transmit and receive functions.

(4) Mounting Hole Used to install a modem from the front surface. It is easy to install a modem, however, only three holes are available. Antenna Connector 4 2 SYSTEM INSTALLATION 5 2SECTION 2.1 Communication Cable Connection Use the serial communication cable prepared by Futaba to connect the FDQ02T to the external terminal equipment. For the connection of the modem, see PIN ASSIGNMENT. The signal level of the FDQ02T is CMOS. If the interface of the equipment to be connected is RS232C or RS485, the level conversion circuit is required. Please connect connector A-12pin and B-2pin. Communication Connector A Communication Connector B No.14 No.1 No.1 No.3 Table 2-1 : PIN ASSIGNMENT ( Communication Connector A ) Figure 2-1: PIN ASSIGNMENT Pin No. Name I/O Meaning Terminal treatment STAND-BY Input Standby mode transition/return C-MOS RxD TxD Output Output received data C-MOS Input Input transmitted data 47k pull down Reserved Input Do not use. GND DSR RTS CTS Reserved VCC Signal ground Output Initialization completed Input Flow control Output Flow control Input Do not use. 3.5V ~ 7.0V POWER-ON Input Power on/reset 47k pull down C-MOS 47k pull down C-MOS 47k pull down 47k pull down RX/TX Output Set external amplifier to C-MOS receiver or transmitter

/INIT Input Memory register initialization 47k pull up Reserved Input Do not use 47k pull up

(1) The terminals of the radio modem are based on the DCE (Data Communication Equipment) mode. Accordingly, the transmission corresponds to the input, while the reception corresponds to the output.

(2) Only supplying the power to the number 10-pin does not activate the MODEM. Raise the number 11-pin to the Hi-level to turn on the modem. This operation works as a reset function as well.

(3) The number 1-pin is used for controlling the standby mode. Lo: Communication mode / Hi: Standby mode 6 Be sure to add a pull-down circuit externally. (Refer to the Standby mode)

(4) The level of the number 6-pin turns to Hi-level when the modem gets ready to accept commands after the modem is turned on or reset. To use this function, add a pull-down circuit externally. (Refer to the Standby mode)

(5) The number 12-pin is used to control the external amplifiers transmission and reception. Lo: Transmission / Hi: Reception

(6) If the number 13-pin is at Lo-level when the modem is turned on or reset, the pin initializes the memory register and makes the modem start working.

(7) Do not connect anything to the number 14-pin.

(8) As the input terminals accept 5V, users can use this interface for 5V-systems. Table 2-2Signal definition Logic 0ON 1OFF Voltage Lo Hi Signal Space Mark Table 2-3 : PIN ASSIGNMENT ( Communication Connector B ) Pin No. Name I/O Meaning Terminal treatment VCC RX/TX GND Input 6.0V ~ 9.0V Set receiver or transmitter Signal ground C-MOS Ensure that the FDQ02T modem power and the power to the equipment to be controlled is turned off before connecting or disconnecting the cable between them. This will help prevent accidental damage to the system and unexpected operation and/or injury. In addition to this manual, read the operation manual of a PC

(Personal Computer) and PLC (Programmable Logic Controller) to be connected. 7 CAUTIONWARNING 2.2 Reset signal The reset signal at the number 11-pin (POWER-ON) is shown in the figure bellow. The reset conducted by the reset signal is equivalent to rebooting the power. 1ms Min Hi Lo Figure 2-2Reset signal 2.3 Initialization time

(1)The initialization time, which is between the time to turn on the modem and the time to accept the first command, is 150ms maximum.

(2)When using the RST command to carry out the software-reset, it takes 100ms to reset the modem and accept the first command after entering the RST command. Note: This is based on the premise that the modem accepts the RST command while it is in the standby mode for reception.

(3)When using the INT command to initialize the memory register, it takes 150ms or less to reset the modem and accept the first command after entering the INT command. Note: This is based on the premise that the modem accepts the INT command while it is in the standby mode for reception.

(4)When using the /INIT pin to initialize the memory register, it takes 250ms or less to accept the first command after turning on the modem. The next figure shows the boot-up sequence to initialize the modem by the /INIT pin. VCC 0ms Min POWER-

ON Note: Min 100ms for initialization (1000ms is recommended. Never use the modem with this level at Lo.)

/INIT Note Max 20ms for no initialization Figure 2-3Initialization sequence 8 2.4 Other Installation Precautions 2.4.1 Modem Installation Precautions Securely attach the antenna cable, and serial communication connector to the FDQ02T and equipment/power source to which it is connected. Failure to not do so could cause an unexpected system failure. The FDQ02T is a precision electronic device. Its rugged design is intended for industrial applications. However, do not install it where it will encounter excessive vibrations. In some cases, isolation mounts may be used to isolate the modem from the equipment vibration. Excessive vibration could permanently damage the modem and/or cause it to malfunction. If the FDQ02T has been stored at a temperature beyond the specified operating temperature range for the system, it may not function properly. Allow it to return to normal temperatures before use. Refer to p.60 SPECIFICATION for the actual operating temperature range. Do not operate the FDQ02T in environments where it will be subjected to excessive moisture (such as rain or water spray), dust, oil or other foreign matter (such as metal particles). Doing so may permanently damage the modem and/or cause it to malfunction. If it does become wet or contaminated, correct the situation, verify proper operation and have any problems corrected before using it to control other equipment. If necessary, the modem can be mounted inside a protective or waterproof enclosure. If the enclosure is metallic, the antenna must be mounted externally or the effective operating range will be severely limited. The FDQ02T is designed for indoor use. When using it outdoors, the modem should be mounted in a waterproof enclosure and the ambient temperature range should be checked to insure that it is within the modems specifications. Always use the modem within its specified environmental ranges. 9 WARNINGWARNINGWARNINGWARNINGWARNING 2.4.2 Antenna Installation Precautions Before each use, verify that the antenna (and antenna cable, if used) is securely attached and in good condition. A loose antenna or cable may severely reduce the operating range of the system. Avoid mounting the antenna near large metallic objects or inside metal enclosures. Such objects can severely reduce the operating range of the system. The FDQ02T operates at frequencies in the 2.4 GHz band. These frequencies are much directional than lower frequencies and are easily reflected. If there are metal structures nearby, the effective range may be shortened or the directional properties may be further narrowed. To help avoid this, mount the antenna as far away as possible from surrounding metallic structures. Multipath problems occur easily at 2.4 GHz frequencies. When multipath problems are present, moving the antenna as little as 10 cm may result in improved communication or, conversely, a further diminished or total loss of communication. Futaba recommends that the mounting position of the antenna be determined after testing and verifying optimal communication conditions. Please contact Futaba for information about antenna separation when using the FDQ02T and other wireless products in the same area. 10 WARNINGWARNINGCAUTIONCAUTION 3 SYSTEM OPERATION 11 3SECTION 3.1 Packet transmission mode 3.1.1 Abstract In the Packet Transmission mode, the communication is carried out by the follows procedure:

(1) Once the power of the modem is turned on, the modem becomes the State for Reception.

(2) The transmission command TXT or TBN makes the MODEM to the State for Transmission.

(3) One transmission command can send one packet. The maximum length of the users message is 255 bytes for a packet.

(4) Receiving a packet, the destination modem returns an ACK to the sender modem. Receiving the ACK, the sender modem ends the communication. The sender modem returns its response, which depends on the cause of success or failure in the communication. Meanwhile, the packet of a message that has failed to be transmitted will be destroyed.

(5) Prior to sending messages consecutively, the modem checks the responses whether the previous transmission has been successful or not.

(6) The modem returns to the State for Reception after finishing the transmission. 3.1.2 T Transmission command and reception header The transmission commands used for the Packet Transmission mode are TXT, TXR, TBN or TBR. Depending on the transmission commands, there are four different formats that are used to output received data to external equipment. The external equipment can find the data format by its reception deader. The TXR and TBR commands via repeater are not utilized for the modem, but are explained here for the future upgrade. Table 3-1Transmission command and reception header Transmission Reception Function command TXT TXR TBN TBR header RXT RXR RBN RBR Transmit text data Transmit text data via repeater Transmit binary data Transmit binary data via repeater The followings are the input format of transmission data from the external equipment to the modem and the reception format from the modem to the external equipment.

(1) Text data transmission Transmission Example Reception

: @TXT[destination address] [message] [CRLF]

: @TXT012HELLO [CRLF]

: RXT[sender address] [message] [CRLF]

12 Example

: RXT0015HELLO [CRLF]

(2) Text data transmission via repeater

: @TXT[repeater address] [destination address][message][CRLF]

: @TXT003012HELLO [CRLF]

: RXT[repeater address] [sender address][message][CRLF]

: RXT003015HELLO [CRLF]

Transmission Example Reception Example

(3) Binary data transmission

: @TBN012005HELLO [CRLF]

Transmission : @TBN[destination address] [the number of bytes of the message]

[message] [CRLF]

Example Reception

[CRLF]

Example

: RBN[sender address] [the number of bytes of the message] [message]

: RBN015005HELLO [CRLF]

(4) Binary data transmission via repeater

: @TBN003012005HELLO [CRLF]

Transmission : @TBN[repeater address] [destination address]

[the number of bytes of the message] [message] [CRLF]

Example Reception

[the number of bytes of the message] [message] [CRLF]

Example

: RBN[repeater address] [destination address]

: RBN003015005HELLO [CRLF]

3.1.3 Broadcast communication If the destination address is set to 255, the sender modem broadcasts to all the other modems, which is called broadcast communication. In the broadcast communication, the sender modem can transmit its data to multiple modems simultaneously. However, the modem cannot determine whether all the other modems have received the data without a failure because ACK is not returned from any of them in the broadcast communication. In the broadcast communication, the sender modem repeats retransmission inevitably up to the predetermined count and then returns an end response to its external equipment. Meanwhile, if the receiver modems have received data properly, the modems output the data to their external equipment. However, the modems do not output the retransmitted data to their external equipment if the data has been once accepted properly. 13 3.2 Header-less Stream mode 3.2.1 Abstract The Header-less Stream mode, a special Packet Transmission mode, does not require the procedures for transmission commands that are necessary in the Packet Transmission mode, but requires only inputting transmission data directly.

(1) The destination address can be set in memory register or by command.

(2) The transmission triggers such as terminator, timeout and a specified number of bytes can be set in the memory register.

(3) The maximum length of the message in a packet is 255 bytes , and the number is including terminator.

(4) Receiving a packet, the destination modem returns an ACK to sender modem. Receiving the ACK, the sender modem ends the communication.

(5) The sender modem does not return any response regardless of success or failure in the communication. It is necessary for application software to checking the establishment of the communication.

(6) Since the modem has a transmission buffer inside, you can enter transmission data consecutively without waiting the end of transmission like in the Packet Transmission mode.

(7) This mode is compatible and can communicate with the Packet Transmission mode. 3.2.2 Format The Header-less Stream mode does not out put the responses such as P1, P0 and N1 in response to transmission commands. In addition, it doesnt output the reception header or CRLF code, which is used in the Packet Transmission mode, but outputs instead special characters (terminators), which are used as packet separators, as part of data. The followings are the transmission and reception formats in the Header-less Stream mode. Packet Transmission modeReference Transmission Reception

: @TXT002HELLO [CRLF]

: RXT001HELLO [CRLF]

Header-less Stream mode (When terminator is CRLF.) Transmission Reception

: HELLO [CRLF]

: HELLO [CRLF]

Transmission in the Header-less Stream mode, Reception in the Packet Transmission modetext mode Transmission Reception

: HELLO [CRLF]

: RXT001HELLO [CRLF] [CRLF]

Transmission in the Header-less Stream mode, Reception in the Packet Transmission modebinary mode Transmission Reception

: HELLO [CRLF]

: RBN001007HELLO [CRLF] [CRLF]

Transmission in the Packet Transmission mode, Reception in the Header-less Stream mode Transmission Reception

: @TXT002HELLO [CRLF]

: HELLO 14 3.2.3 Transmission trigger In the Header-less Stream mode, transmission starts under the following conditions.

(1) Terminator mode A designated terminator or data of 255 bytes or larger is entered.

(2) Timeout mode No data has been entered for more than the specified time or data of 255 or larger is entered. 3.3 Extended Reception mode Extended Reception is a function to avoid transmission errors and response delays due to repetition of retransmissions when multiple modems transmit messages at the same time accidentally like contention mode in the Packet Transmission or Header-less Stream mode. 3.3.1 Operations in the Extended Reception mode P1 P1 DTE1 DTE2 Modem2 Modem1 TXT command TXT command Simultaneous transmission In the Extended Reception mode, once a modem has started receiving data during retransmission (during ACK-wait, Random-wait and Carrier-sense), the modem will fully complete the data reception, return its ACK and then resume the retransmission. The following figure shows steps of operations in Extended Reception while the two modems transmit messages at the same time. Output received message after outputting P0 response Stop random-wait and start Extended Reception End random-wait beforehand Return ACK and then transmit Transmissi on received message Output ACK ACK P0 P0 Figure 3-1Operations in the Extended Reception mode 15

(1) The modem1 and 2 transmit messages at the same time.

(2) Both modems wait for ACK, but they time-out.

(3) Of the two modems, the one that has finished the random-time earlier (modem2 in this case) retransmits its message.

(4) Receiving a message retransmitted during the random-wait, the modem1 receives the whole message and then returns ACK.

(5) The modem1 does not output but keep its received message and transmits its own message.

(6) The modem2 returns ACK.

(7) Receiving ACK, the modem1 outputs P0 response and the received message. 3.3.2 Contention between transmission and reception P1

@TXT**

@TXT**

DTE2 DTE1 Modem1 Modem2 If a modem receives a transmission command during reception, the modem completes the reception, returns ACK and then starts processing the transmission command. Like the Extended Reception mode, the modem outputs the received message only after completing its transmission and outputting P0 response. Output received message after outputting P0 response Wait until transmission ends Message Message RXT***

RXT**

ACK ACK P1 P0 P0 Figure3-2Contention between reception and transmission 16 3.4 Communication time The time consumed for each communication sequence in the Packet Transmission mode is as follows.

(1) Time for entering a transmission command The time consumed for entering a transmission command to the modem from its terminal depends on the communication parameters between them. Parameters are:

Transmission rate (300ps to 115.2kbps) Data length (7 or 8 bits) Parity bit (yes or none) Stop-bit length (one or two bits) Start-bit length (one bit) For example, in the case of 9600bps for transmission rate, 8 bits for data length, no parity, one stop bit and one start bit, the time consumed for sending one bit will be 104s. And the time for sending the data of a byte that consists of 10 bits will be 1.04ms. In the case of sending a message data of ten bytes by TXT command, the time consumed for sending the message will be 19.8ms because the transmission format becomes

@TXT001ABCDEFGHIJ [CRLF], which is 19 bytes.

(2) Time to generate a transmission packet The internal processing time to generate a transmission packet after accepting a command is 1ms or less even though the length of the message data varies from 1 to 255 bytes. In the Header-less Stream mode, it takes 2ms or less.

(3) Time for carrier sense Prior to transmission, the modem checks SS correlation. If any SS correlation is detected within 0.1ms, the modem does not transmit any data.

(4) Time to switch between transmission and reception The internal processing time consumed for switching transmission to reception or vice versa is approximately 0.07ms.

(5) Transmission time via radio Depending on the number of bytes of a message data (1 to 255), the time consumed to transmit the message is obtained from the following calculation. 1.74ms + (the number of bytes in the message) 0.06ms

(6) Waiting time for ACK This is the time consumed for waiting for ACK after completing transmission via radio. The waiting time is 2ms. The modem determines that the transmission has failed if it could not receive ACK packet in that period of time. Then the modem waits for the random-wait time and then repeats the above steps starting from the carrier sense if the number of retransmissions has not reached the predetermined number. If there is no remaining number of retransmissions, the modem ends its transmission, outputting the response of transmission failure.

(7) Time to transmit ACK or NAK The time consumed for transmitting ACK or NAK is 1.74ms.

(8) Time for random-wait When SS correlation has been detected by carrier sense, or when retransmission is required due to the transmission failure, carrier sense will start only after waiting for the random time in order to avoid collisions between packets. The time for random-wait is from 1ms to 7ms. 17 P1 DTE2 DTE1 Modem1 Modem2

@TXT***: 20ms

(9) Time for reception process Approximately 0.2ms is consumed for the receiver modem to check the address in the data and other information sent from the sender modem. The receiver modem recognizes the data having passed the check and outputs it to its terminal. The next example shows an approximate time necessary for sending a message of 10 bytes when the parameters are 9600bps for transmission rate, 8 bits for data length, no parity, one stop bit and one start bit. In this example that includes one retransmission, the modem1 enters into the Retransmission Routine because of no response from the modem2 after waiting for ACK. In Retransmission Routine, the modem1 does a random-wait of 1ms to 7ms in order to avoid collisions between packets, and then restarts transmission. Packet generation:

0.1ms Carrier-

sense/transmission switch: 0.17ms 1ms ~ 7ms Carrier-

transmission: 0.07ms sense/transmission ACK transmission:

processing: 0.2ms processing: 0.2ms Reception switch:

processing 0.1ms ACK-wait: 2ms Random-wait:

switch: 0.17ms RXT***: 19ms transmission:

transmission:

Command Change to Reception Reception Message Message P0: 2ms 1.74ms 0.07ms 2.34ms 2.34ms Figure 3-3Communication time in the Packet Transmission mode (an example) 18 3.5 Repeater function This function is not installed in the modem at present. This section is only for explanation for the future upgrade. 3.5.1 Abstract Using repeaters is useful in extending communication area and eliminating dead-point area where radio signal intensity is insufficient. The repeater function can coexist with the modem function. If a modem receives a packet whose destination address matches with the modems address, the modem outputs the received data to its external equipment. (Modem operation) If a modem receives a packet whose repeater address matches with the modems address, the modem transfers the packet. (Repeater operation) If a modem is used as a repeater, there is no need for the modem to have its external equipment. When a conflict occurs between a transmission command and a transfer operation, the priority will be given to the one that emerged first. If a transfer request occurred afterward, the transfer is carried out after transmission. In contrast, if a transmission request occurred afterward, the transmission is carried out after transmission. A repeater station, for its installation purpose, should be used as a master station. (Not mandatory) Repeater = Master Obstacle Sender Destination Figure 3-4: Repeater 3.5.2 Repeater address In the Packet Transmission mode, the repeater address is set by transmission command. In the Header-less Stream mode, there are two ways bellow:

(1) Setting by memory register

(2) Setting by PAS command 3.5.3 Communication time via repeater The communication time through a repeater is about twice as long as the time consumed in the direct communication. 19 3.6 Frequency Channel The FDQ02T can operate on 22 available frequencies between 2405.376 MHz and 2475.008 MHz with 2.048 MHz separation between each frequency. See the table below for the exact frequency assignments. Table 3-2 Frequency Channel Channel Frequency(MHz) Channel Frequency (MHz) 2 4 6 8 10 12 14 16 18 20 22 2405.376 2407.424 2409.472 2411.520 2413.568 2415.616 2417.664 2419.712 2421.760 2423.808 2425.856 24 26 28 30 32 34 36 38 40 42 70 2427.904 2429.952 2432.000 2434.048 2436.096 2438.144 2440.192 2442.240 2444.288 2446.336 2475.008 20 4 FUNCTION CONTROL METHODS 21 4SECTION 4.1 Interface 4.1.1 Pin Assignment The figure below shows the pin location of the serial communication connector, following the DCE (Data Communication Equipment) specification. Communication Connector A No.14 No.1 No.3 No.1 Communication Connector B Figure 41: Serial Communication Connector Location Pin No. Name I/O Meaning Terminal treatment STAND-BY RxD TxD Input Output Output received data Standby mode transition/return C-MOS C-MOS Input Input transmitted data 47k pull down Reserved Input Do not use. GND DSR RTS CTS Reserved VCC Output Signal ground Initialization completed Input Flow control Output Flow control Input Do not use. 3.5V ~ 7.0V POWER-ON Input Power on/reset 47k pull down C-MOS 47k pull down C-MOS 47k pull down 47k pull down RX/TX Output Set external amplifier to C-MOS receiver or transmitter

/INIT Input Memory register initialization 47k pull up Reserved Input Do not use 47k pull up Table 41: Pin Descriptions

(1) The terminals of the radio modem are based on the DCE (Data Communication Equipment) mode. Accordingly, the transmission corresponds to the input, while the reception corresponds to the output.

(2) Only supplying the power to the number 10-pin does not activate the MODEM. Raise the number 11-pin to the Hi-level to turn on the modem. This operation works as a reset function as well. 22

(3) The number 1-pin is used for controlling the standby mode. Lo: Communication mode / Hi: Standby mode Be sure to add a pull-down circuit externally. (Refer to the Standby mode)

(4) The level of the number 6-pin turns to Hi-level when the modem gets ready to accept commands after the modem is turned on or reset. To use this function, add a pull-down circuit externally. (Refer to the Standby mode)

(5) The number 12-pin is used to control the external amplifiers transmission and reception. Lo: Transmission / Hi: Reception

(6) If the number 13-pin is at Lo-level when the modem is turned on or reset, the pin initializes the memory register and makes the modem start working.

(7) Do not connect anything to the number 14-pin.

(8) As the input terminals accept 5V, users can use this interface for 5V-systems. Table 2-2Signal definition Logic 0ON 1OFF Voltage Lo Hi Signal Space Mark 4.2 Serial Interface Setting For connecting the FDQ02T modem with an external terminal equipment, RS232C is appropriate for 1 to 1 topology. And set the RS485 mode to make RS485 multi-dropping topology for multiple equipment connection. Interface configuration can be made with Pin 12 (/RS485ENB) of the serial communication connector. To configure the RS485 mode, pull down Pin 12 with 10k ohm register. In this case, do NOT connect this pin DIRECTLY to the GND. This is because in RS485 mode, this pin will be as an output pin, after the initialization completes, to control the output buffer of the RS485 driver IC chip. As for the RS232C interface, no connection is required because it is pulled up inside. Since the interface level of the FDQ02T modem is CMOS, the level conversion circuit must be provided outside for connecting it with the RS232C or RS485 interface. FDQ modem RS-232C PC Converter Figure 41: Connection Example to PC 23 4.3 Terminal Software Setup for Memory Register Control bit rate: 9600 bps Communication or terminal software is necessary to set the memory registers. Nearly any PC communication software can be used. Launch the communication software and set the terminals communication parameters as shown below. Refer to your specific communication software instructions how to set these parameters. data length: 8 bits stop bits: 1 bit parity bit: none flow control: none local echo: yes terminator: carriage return + line feed 4.4 Memory Register Setting Memory registers set the operation mode and communication parameters of the modem and retain them in memory. All of the settings of the modem are made by these memory registers. Since the memory register is based on rewritable non volatile memories, these memories can be readily rewritten by external terminal equipment such as PC and their contents will be kept even after the power is turned off. This non volatile memory can be rewritten about 1 million times. 4.4.1 Memory Register Referencing and Setting Memory registers are referenced and set with the REG command. (For more information, refer to REG section at p.39 COMMAND SET DESCRIPTION) Example procedure:

1. To view the current value of register 00, enter: @REG00 CR/LF 2. Modem responds with 00H CR/LF (REG00 is assumed to be 00H in this case and varies in each setting case) 3. To set register REG00 to 0FH, enter: @REG00:0FH CR/LF 4. Modem responds with P0 CR/LF 5. Enter @RST CR/LF or cycle the modem power, to activate new values

@ = command header (specify following characters are command) CR/LF Terminator (carriage return + line feed) When rewriting the modems memory registers, do not turn the modems power off until the modem returns P0 response. If the power is interrupted before P0 is returned, the memory contents may be lost or corrupted and the modem operation will be unpredictable. 24 CAUTION If the memory contents are lost or corrupted, they can be restored to original default settings by reinitializing them. (See the section below titled p.25 MEMORY REGISTER INITIALIZATION) Input character arrays of commands quickly and sequentially. Too slow input (taking more than 5 seconds in the initial setting) results in command error. 4.4.2 Memory Register Initialization The memory registers can be restored to the factory default values at any time by using one of the following two methods. 1) Memory Register Initialization by hardware:

Use either methods stated below, in which the modem attempts to read Pin 13

(/DefParam) of the serial communication connector at the startup and starts initializing the memory registers when it is L. Method 1. Set L level to Pin 13 (/INIT) of the serial communication connector with the power turned off. When the power is re-supplied, the memory registers are initialized and the modem starts operation in the factory default state. Method 2. Set L level to Pin 13 (/INIT) of the serial communication connector while the power turned on. In this state, force L to Pin 11 (POWER ON) of the serial communication connector more than 1ms, then return the level to H. The modem once becomes the Shutdown mode and returns to Active mode. Since this sequence is the same as the reset, the memory registers are initialized and the modem starts operation in the factory default state. 2) Memory Register Initialization by Command:

1. With the modem power is on and the communication software running, enter @INI CR/LF at the terminal prompt. 2. The modem responds with P0 response and immediately begins to operate using the initialized factory default state. While initializing the memory registers, do not turn the modems power off. It take about 1 sec. to initialize the memory registers. 25 CAUTIONCAUTION 4.5 Command Control Some FDQ02T parameters can be changed by issuing commands from the terminal equipment. Various applications can be supported with the flexibility that command control offers. Command Entry When a command is issued to the modem from the terminal equipment, a command header (one byte character) should be used the modem to acknowledge the command from ordinary data. The command header is initially set to @ (40H) but can be changed to another character by changing the value stored in the memory register REG10. Commands must use all upper case letters (A to Z). The modem does not recognize lower case letters (a to z) in commands. A two byte terminator (carriage return (0DH) + line feed (0AH)) is used to terminate a command. CR/LF shows the terminator in this manual. PC can send this two byte character with pressing ENTER key once using a communication software. But some setting is necessary in the software. The modem immediately executes a command once its recognized. If the command requires a response, the modem returns the response to the terminal equipment when its internal processing is completed. The following is an example of a command entry and response:

@BCL CR/LF :command issued from the terminal equipment

: successive completion response is returned P0 CR/LF 26 5 MEMORY REGISTER DESCRIPTION 27 5SECTION 5.1 Memory Register Description The FDQ02T modem contains 28 memory registers which are used to control and store communication parameters and operation mode settings. After rewriting new register settings, the power must be cycled, a hardware reset asserted, or a software RST command is issued to validate the new settings. The following table briefly lists each register, register function and default value:

Register REG00 REG01 REG02 REG03 REG04 REG05 REG06 REG07 REG08 REG09 REG10 REG11 REG12 REG13 REG14 REG15 REG16 REG17 REG18 REG19 REG20 REG21 REG22 REG23 REG24 REG25 REG26 REG27 Function Own (sender) address Reserved Destination address Special mode ID code 1low-order digits ID code 2 (high-order digits) Frequency Pattern Reserved Repeater address Reserved Command header Retransmission count Reserved Buffer data timeout Command input timeout Command recognition interval Terminator 1 Terminator 2 Radio communication setting 1 Radio communication setting 2 Wired communication setting 1 Wired communication setting 2 Wired communication setting 3 Wired communication setting 4 Special communication setting 1 Special communication setting 2 Data input timeout reserved Default Value Meaning 00H F0H 00H F0H 00H 00H 00H 05H FFH 13H 40H 32H B4H 1EH 32H 00H 0DH 0AH 8CH 00H 05H 09H 00H 00H C0H 40H 00H 00H Address 0 Address 0 Communication mode Refer to REG04 Refer to REG05 Pattern 0 Repeater invalid 50 times 30 seconds 5 seconds 0 second Refer to REG18 Refer to REG19 Refer to REG20 Refer to REG21 Refer to REG22 Refer to REG23 Refer to REG24 Refer to REG25 Terminator valid Table 51: Memory Registers Suffix H of each default value denotes HEX radix expression in the value. 28 REG00: Own (sender) address

[default value: 000]

This register is used to set the address of a modem. Valid values are from 000 to 254. The value in this register is used as a sender address in every data packet being sent. When the address-check function is used, it is possible to receive a packet if the packet contains such value as a destination address. REG01: Reserved

[default value: 240]

The FDQ02T does not use this register. Keep the default value as it is. REG02: Destination Address

[default value: 000]

In the Header-less Stream mode, this register is used to set the address of a destination modem. Valid values are from 000 to 255. This destination address is attached to every data packet to be sent. When using the address-check function, set the destination address in this register. When using the DAS command, however, the address defined by the DAS command is always prioritized. The destination address 255 represents the broadcast communication. REG03: Special mode

[default value: F0H]

This register is used to set a special operating mode. The default is the Communication mode. REG04: ID Code 1

[default value: 00H]

Used with ID code 2 (REG05), set the ID code. Valid values are 000 to 255. Together with ID code 2, up to 65535 ID codes can be set. The ID code identifies the group of the modems works in the same group. The ID code is used to prevent erroneous connection with other systems and for communication security. Before transmission, radio data packets are scrambled using a pseudo-random data sequence generated with this ID code as the seed. During reception, the original data is restored by de-scrambling it with the pseudo-random data sequence. The modems with different ID codes cannot communicate with each other. REG05: ID Code 2

[default value: 00H]

Used with ID code 1 (REG04), set the ID code. Valid values are 000 to 255. Together with ID code 1, up to 65535 ID codes can be set. In case plural modems are used as a single system, always set the same ID code for all modems and repeaters. 29 REG06: Frequency pattern

[default value:00H]

This register is used to set a frequency pattern. The valid values are from 00H to 15H. To establish communication in a system, the same frequency pattern should be used. In contrast, to let multiple systems operate in the same area, each system should have different frequency patterns. When using multiple systems in the same area, frequencies may periodically match and interfere with each other even if the systems are using different frequency patterns. REG07: Reserved

[default value: 05H]

The FDQ02T does not use this register. Keep the default value as it is. REG08: Repeater Address

[default value: FFH]

This register is used to set repeater address when using repeater in the Header-less Stream mode. When not using repeater, set FFH at this register, making the communication direct. REG09: Reserved

[default value: 13H]

The FDQ02T does not use this register. Keep the default value as it is. REG10: Command Header

[default value: 40H]

Sets the character that identifies the start of a command. The default is character @ (40H). When this character is input from the terminal equipment after no character is received for the command recognition interval (REG15) or longer, subsequent input character is recognized as a command for the modem. REG11: Retransmission Count

[default value: 32H]

Sets the maximum number of packet retransmission attempts. Valid values are 000 to 255. When retransmission exceeds the retransmission count (retransmission count plus one), the modem outputs an error response to the terminal equipment. REG12: Reserved

[default value: B4H]

The FDQ02T does not use this register. Keep the default value as it is. 30 REG13: Buffer Data Timeout

[default value: 1EH]

This register is used to set the waiting time to clear the content of the buffer after the last change in the buffer. Valid values are from 000 to 255 seconds with an increment of 1 second. The default value is 30 seconds. If the Buffer Data Timeout is not necessary, set it at 0. This value should be longer than the Data Input timeout (REG26). REG14: Command Input Timeout

[default value: 32H]

Sets the character input timeout interval for command input. It is used as the timeout between the command header and the character following it and between each character of the command. At the timeout, the modem operation transits from command-input-state to data-

wait-state. Valid values are 000 to 255, representing tenths of seconds in 0.1 second increments.

(Set an integer value equal to ten times the number of seconds desired.) A setting of 000 disables this timeout function REG15: Command Recognition Interval

[default value: 00H]

When a message data contains a command header character (in case of binary data or data in two-byte Chinese characters), data following the command header character will be interpreted as a command, the message does not transmit properly. Sets the necessary vacant duration time interval to discriminate between ordinary data character and a command header character. Input a command after a longer interval than time interval setting. Valid values are 0.1 to 25.4 sec., representing tenths of seconds in 0.1 second increments. (Set an integer value equal to ten times the number of seconds desired.) When set to 000, the command header is recognized at any time, and when set to 255, all command header character are ignored. REG16: Terminator 1

[default value: 0DH]

Set an arbitrary 1 byte terminator. In case of a 2-byte terminator, set the first byte character of the terminator. REG17: Terminator 2

[default value: 0AH]

Set another arbitrary 1 byte terminator. In case of a 2-byte terminator, set the last character of the terminator . 31 REG18: Communication Setting 1

[default value: 8CH]

Bits 7 6: Protocol bit 7 0 0 1 1 bit 6 Setting 0 Data transparent mode 1 Reserved 0 1 Headerless stream mode Packet transmission mode Table 57: Protocol Bits 5: Reserved The FDQ02T does not use this register. Keep the default value as it is. Bit 4 Transmission format 0 1 transmit in the text form (default value) transmit in the binary form Table 74 Transmission format Selects the transmission format. When data are transmitted to the destination station which is set to the normal packet transmission mode, output text format

(RXT, RBN) from the receiver modem (destination station) differs depend on this setting. This setting does not effect in the receiver modem set as headerless stream mode. Bits 3 2 Terminator Setting bit 3 bit 2 0 0 1 1 0 1 0 1 setting two kinds of arbitrary 1 byte code (REG16, REG17) arbitrary 1 byte code (REG16) a wild card (any character) arbitrary 2 byte code (REG16 + REG17) carriage return (CR) line feed (LF) (default value) Table 75 Terminator setting Sets the terminator to identify the breakpoint of a packet. The modem transmits data considering this character as the breakpoint of a packet. In case of using an arbitrary terminator, set it to REG16 and 17. Bit 1: Source address check 0 1 Inhibit source address checking (default value) Activate source address checking Table 54: Source Address Check Settings 32 When the source address checking is active and the source address in the received packet header does not match the destination address setting (REG02), the data is discarded (data cannot be received). Bit 0: Destination address check 0 1 Inhibit destination address checking on receipt (default) Activate destination address checking on receipt Table 55: Destination address check When the destination address checking is active and the destination address in the received packet header does not match the received modems local station address (REG00), the data is discarded (data cannot be received). REG19: Communication Setting 2

[default value: 00H]

Bit 7 - 6: Reserved The FDQ02T does not use this register. Keep the default value as it is. Bit 5: Broadcast Reception 0 1 Enable broadcast transmission reception (default value) Disable broadcast transmission reception Table 57: Broadcast Reception Settings Enable/disable reception of broadcast transmission in packet transmission mode

(Mode 3 and 5). Bit 4 - 2: Reserved The FDQ02T does not use this register. Keep the default value as it is. Bit 1: Master/Slave 0 1 Slave station (default) Master station Table 511: Master/Slave There should be no more or no less than one master station among a group of modems that communicate each other. The number of slave stations can be up to the number defined by the REG00. (253 Max) The master station transmits beacon as a reference. Bit 0: Reserved The FDQ02T does not use this register. Keep the default value as it is. 33 REG20: Wired communication Setting 1

[default value: 05H]

Bit 7: Data Length 0 1 8 bit data bytes (default value) 7 bit data bytes Table 513: Data Length Settings Bit 6: Parity Bit 0 1 No parity bit (default value) Parity bit Table 514: Parity Settings Bit 5: Even/Odd Parity 0 1 Even parity (default value) Odd parity Table 515: Odd/Even Parity Settings Invalid when bit 6 is set to 0, without parity. Bit 4: Stop Bit 0 1 1 stop bit (default value) 2 stop bits Table 516: Stop Bit Settings Bits 3 0: Baud rate setting Bit 3 Bit 2 Bit 1 Bit 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 Setting 300 bps 600 bps 1200 bps 2400 bps 4800 bps 9600 bps (default) 19200 bps 38400 bps Reserved Reserved Reserved Reserved 57600 bps 115200 bps Reserved Reserved Table 517: Baud Rate 34 REG21: Wired communication Setting 2

[default value: 09H]

Bits 7 5: Reserved The FDQ02T does not use this register. Keep the default value as it is. Bit 4: Command Header 0 1 Use REG 10 character Use Break signal Table 516: Command Header Bit 3 - 2: Reserved The FDQ02T does not use this register. Keep the default value as it is. Bit 1: Flow Control 0 1 Software flow control (default value) Hardware flow control Table 518 Software/Hardware Flow Control Settings Selects the flow control method. This setting must match the connected terminal equipments setting. Hardware flow control uses the two control lines RTS and CTS. When using with the RS485 interface, be sure to set to 0. Software flow control uses XON and XOFF codes. Bit 0: Reserved The FDQ02T does not use this register. Keep the default value as it is. REG22: Wired communication Setting 3

[default value: 00H]

Bit 7: Enable and Disable Reception 0 1 Enable reception at the initial state (default value) Disable reception at the initial state Table 519: Enable/Disable Reception The initial state is in reception enable. Depending on an usage of the modem, the initial state of the modem may be better in the reception disable state. In such a case, use this setting. Issue the REN command to enable reception. Bit 6 - 0: Reserved The FDQ02T does not use this register. Keep the default value as it is. 35 REG23: Wired communication Setting 4

[default value: 00H]

Bit 7 - 5: Reserved The FDQ02T does not use this register. Keep the default value as it is. Bit 4 : CR/LF addition/deletion

(1) Setting at the headerless stream mode 0 1 does not add CR/LF code to the received data (default value) adds CR/LF code to the received data Table 76: Addition of CR/LF code In the headerless stream mode, setting is made whether the CR/LF character is added to the received data or not. In the communication between the modems set to the headerless packet mode, this setting is invalid because the terminator is originally added to the transmit data. However, when a packet is received from the modem in the packet transmission mode, there is no addition of the CR/LF terminator. In this case, set this bit to 1. Then the received packet is output with the CR/LF character is added.

(2) Setting at the packet transmission mode 0 1 adds the CR/LF to the received data (default value) does not add the CR/LF to the received data Table 77: Deletion of CR/LF character In the packet transmission mode, setting is made whether the CR/LF character is added to the received data or not. At the receiver modem (set to the packet transmission mode), the sender (set to the headerless stream mode) side terminator (CR/LF character as default) plus packet transmission mode terminator (CR/LF) are output. To avoid such redundant outputs, set this bit of the modem in the normal packet transmission mode to 1. Bit 3 - 0: Reserved The FDQ02T does not use this register. Keep the default value as it is. 36 REG24: Reserved

[default value: C0H]

The FDQ02T does not use this register. Keep the default value as it is. REG25: Reserved

[default value: 40H]

The FDQ02T does not use this register. Keep the default value as it is. REG26: Data input timeout

[default value: 00H]

Sets the vacant duration time interval to recognize as the end of the message data input in the headerless stream mode. REG27: Reserved

[default value: 00H]

The FDQ02T does not use this register. Keep the default value as it is. 37 6 COMMAND SET DESCRIPTION 39 6SECTION 6.1 Command Set Description This section provides a description of each command available in the FDL command set. The table below lists each command and it applicability in each operation mode. Command Function 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 ARG BCL DAS DBM HOP Reference All Memory Resisters Clear Transmit and Receive Buffers Reference and Set the Destination Address Read Signal Strength Refer to or set frequency pattern INI Initialize All Memory Resisters ODA OEN PAS RDA REG REN RID RNO ROF RON RST SAS STS TBN TBR TID TS2 TXR TXT VER Disable Received Data Output Enable Received Data Output Reference and Set Repeater Address Disable Wireless Reception Reference and Set Memory Resisters Enable Wireless Reception Display Received Serial ID Reference and Set Retransmission Count RF Circuit Block Power Down RF Circuit Block Power Up Reset Reference and Set Local Station Address Read Status Transmit Binary Data Transmit Binary Data Through Repeater Display Local Station Serial ID Test radio link Transmit Text Data Through Repeater Transmit Text Data Reference Version Information Table 61: Command to Mode Availability Input character from the terminal equipment to the modem The symbols used in this section have the following meaning:

:

: Output from the modem to the terminal equipment

: Command header

: Terminator (carriage return + line feed)

: Required input parameter/s Be sure to input.

: Optional input parameter/s May be omitted

: 485 mode local station address (REG00). Be sure to

>

<

@

CR/LF

[ ]

( )

{}

input at 485 mode In the Syntax and Response segments of the following command descriptions the terminator symbol (CR/LF)has been omitted for clarity. 40 ARG Reference All Memory Registers ARG{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to 999). Response All settings are indicated (REG00 to REG27) N0: command error (Except 485 mode) Function Recalls the contents of all 28 memory registers.

: Recall the contents of all the memory registers

: Consecutive output of register contents

: Register values output in hexadecimal codes

>@ARG CR/LF

<REG00 : 001 CR/LF

<REG01 : 240 CR/LF

<REG02 : 002 CR/LF

<REG03 : F0H CR/LF Example

|

|

<REG26 : 00H CR/LF

<REG27 : 00H CR/LF BCL Clear Transmit and Receive Buffers BCL{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0 Function

: command accepted

: command error (Except 485 mode) On headerless stream mode , clears the contents of the transmit and receive buffers of the modem. Example

>@BCL CR/LF

<P0 CR/LF

: clear the buffer contents

: command accepted Example

>@BIV025 CR/LF

<P0 CR/LF

>@BIV CR/LF

<025 CR/LF

: Set the receiving (transmission) interval at 250 ms

: command accepted

: Refer the current value

: 025 (25 0ms) returns Notes Values set by the BIV command will be lost by turning the power on or resetting. Generally, this parameter is no need to modifying. Use with the default value. 41 DAS Reference and Set Destination Address DAS(set destination address) Syntax set destination address

: the desired destination address (000 to A23) Response xxx P0 N0

: current value (reference)

: command accepted (setting)

: command error Function References or sets the destination address of the modem connection established with in the data transparent mode and headerless stream mode The current DAS value can be referenced by entering the command with no parameter. The DAS command is used for temporary modifying destination address. Change the value of REG02 to change the default value. Example

>@DAS002 CR/LF

<P0 CR/LF

>@DAS CR/LF

<002 CR/LF

: set the destination address to 002

: command accepted

: reference the destination address

: current value output (002) Notes This command cannot be used in packet transmission mode. DBM The local station address (REG00) must be set to communicate with the remote modem. Communication cannot be established unless the addresses coincide with each other. This command is not arrowed to use in 485 mode. Read Signal Strength DBM{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to 999). Response

-xxxdBm N0

: signal strength

: command error (Except 485 mode) Function Reads the received signal strength and outputs the value in dBm. Higher values represent stronger signal strength and better receiving conditions. Example

>@DBM CR/LF

<-78dBm CR/LF

: read signal strength

: signal strength is -78dBm. 42 Notes The range available for measurement is 40 dBm to 100 dBm. Since the signal strength indication has a slight error in its value, use this result for your rule of a thumb reference. This command outputs the strength of last received packet. HOP Refer to or set frequency pattern Syntax HOP HOP(:pattern number) Pattern number

: 00 ~ 21 Response xx P0 N0

: when referring

: normal end (when setting)

: command error Function This command refers to or sets frequency pattern. To refer to the current setting, enter this command alone. To set a pattern number, enter this command with the pattern number. Setting frequency pattern once releases synchronization. The setting by this command is temporarily effective. It returns to the value defined by the REG06 after resetting. Example

>@HOP CR/LF

<00 CR/LF

>@HOP:21 CR/LF : set pattern number to 21.

<21 CR/LF

: reference the pattern number

: output value (pattern number 00)

: output value (pattern number 21) INI Initialize All Memory Registers INI{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Sets the all contents of the memory registers to the factory default values. Example

>@INI CR/LF

<P0 CR/LF

: initialize all memory registers

: command accepted 43 Notes Custom settings of all memory registers are lost when this command is executed. If the group address (REG01) is designated while RS485 multi-drop connection is being made in the RS485 mode, the local station address of all modems will be initialized to 000. Exercise care when issuing this command. For a list of the factory default values, see the section titled p.27 MEMORY REGISTER DESCRIPTION. ODA Disable Received Data Output ODA{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Disables output of any data received via the wireless link to the terminal equipment. Data received, while output is disabled, is stored in the receive buffer. When the modems power is turned on (or a reset), the modem is in the state to enable the received data output.

>@ODA CR/LF

<P0 CR/LF

: disable the output of received wireless data

: command accepted

(Data is not output during this period even if received.)

>@OEN CR/LF

<P0 CR/LF

<RXT002HELLO CR/LF

<RXT003MAIL CR/LF

: enable the output of received wireless data.

: command accepted

: outputs data stored in the receive buffer

:

OEN Enable Received Data Output OEN{Local Station Address}

Local Station Address : local station address for 485 mode (000 to A22). Response P0

: command accepted 44 Example Syntax N0

: command error (Except 485 mode) Function Enables output of any data received via the wireless link to the terminal equipment. This command enables serial data output after it has been disabled with the ODA command. When the modems power is turned on (or a reset), the modem is in the state to enable the received data output.

>@ODA CR/LF

<P0 CR/LF

: disable serial output of received wireless data

: command accepted

(Data is not output during this period even if received.)

>@OEN CR/LF

<P0 CR/LF

<RXT002HELLO CR/LF

<RXT003MAIL CR/LF

: enable serial output of received wireless data.

: command accepted

: outputs data stored in receive buffer

: and any new data received Example PAS Reference and Set Repeater Address Syntax PAS (:Repeater Address1 :Repeater Address2) Repeater Address : repeater address to pass through Response xxx : xxx P0 N0

: current address (reference)

: command accepted (setting)

: command error Function In the headerless stream mode , references and sets the repeater address to pass through When no repeater address is set, the current setting can be referenced. This command is used to temporarily change repeater address. To change the default value, change REG13. Example

>@PAS CR/LF

<004 : A00 CR/LF

<P0 CR/LF

< @PAS:002:A00 CR/LF

<P0 CR/LF

: references the current repeater address

: current repeater address is 004

: command accepted

: sets the repeater address to 002

: command accepted Notes This command is not allowed to be used in 485 mode. 45 RDA Disable Wireless Reception RDA{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Disables wireless reception in the packet transmission mode. The status when the modem is powered ON or reset follows bit 7 of REG22. Example

>@RDA CR/LF

<P0 CR/LF

>@REN CR/LF

<P0 CR/LF

: disable wireless reception

: command accepted

: enable wireless reception

: command accepted REG Reference and Set Memory Register REG[register number](: value) {;Local Station Address}

Syntax register number value

: register number to be set (00 to 27)

: value to be set. Input 2 hexadecimal digits (0 through 9 and A through F) followed by the number radix designator H. Local Station Address

: local station address for 485 mode (000 to A22 ). Response xxx P0 N0 N6

: current value (reference)

: command accepted (setting)

: command error (Except 485 mode)

: memory register write error Function References or sets memory registers. The current register value is referenced by omitting the value parameter. Example

>@REG00 CR/LF

<01H CR/LF

>@REG00 : 023 CR/LF

<P0 CR/LF

: reference the contents of register 00

: displays current value

: set value of memory register 00 to 023 (decimal)

: command accepted Notes The register can be rewritten sequentially. However, to make its parameter valid after rewriting it, re-supply the power, reset the modem or use RST command. 46 While rewriting the memory register, do not turn off the power until response is output. Otherwise, the memory registers content may be collapsed. When the response of the memory register write error is output, set the values after initializing the memory register. REN Reception Enable REN{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Enables wireless reception in the packet transmission mode. The status when the modem is powered ON or reset follows bit 7 of REG22. Use this command to enable wireless reception after reception is disabled with the RDA command. Example

>@RDA CR/LF

<P0 CR/LF

>@REN CR/LF

<P0 CR/LF

: disable wireless reception

: command accepted

: enable wireless reception.

: command accepted RID Display Received Serial ID RID{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to 999). Response XXXXXXXXXXXX N0

:

:

displays the received serial ID code12 digits command error (Except 485 mode) Function Outputs the serial ID code in the received packet and displays it. The serial ID code consists of 12 digits; upper three digits are 0 and the lower 9 digits are the product serial number of the transmitted-end modem. Be noted that the serial ID code of the packet received last is displayed. When packets are received from multiple stations and their data are stored in the receiving buffer, those data may not be corresponding to the serial ID code readout with RID command. 47 To use it more securely, it is recommended to readout the local serial ID code with TID command and pad it (either all or a part of it) in the transmitting packet. When no packet is received, All Zero is displayed as the result of this command execution. The serial ID code is no relation with ID code setting of REG04 and 05. Example

: requests the received remote stations serial ID code

>@RID CR/LF

< XXXXXXXXXXXX CR/LF :outputs the received remote stations serial ID code RNO Reference and Set Retransmission Count Syntax RNO (:Retransmission count) {; Local Station Address}

Retransmission count Local Station Address

: maximum number of retransmissions (000 to 255)

: local station address for 485 mode (000 to A22). Response xxx P0 N0

: current set value

: command accepted

: command error (Except 485 mode) Function This command references or sets the number of retransmissions (retransmission count) to attempt before making decision as transmission failure. The current value can be referenced by issuing the command with no parameter. RNO command is used to temporarily change the retransmission count. To change the default value, change the setting of REG11. Example

>@RNO CR/LF

<050 CR/LF

>@RNO010 CR/LF

<P0 CR/LF

: reference the retransmission count

: output the current set value (50 times)

: set the retransmission count to 10 times

: command accepted ROF RF Circuit Block Power Down ROF{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Turn off the power of RF circuit block and stops RF operation. 48 This function is used to save the current consumption when no transmit/receive are required. Example

>@ROF CR/LF

<P0 CR/LF

>@RON CR/LF

<P0 CR/LF

: turn off RF circuit block

: command accepted

: turn on RF circuit block

: command accepted RON RF Circuit Block Power Up ROF{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Turn on the power of RF circuit block and activates RF operation. Use this command to activate RF circuit block after its power down state set by the ROF command. The status when the modem is powered ON or reset, the RF circuit block is in the operation state. Example

>@ROF CR/LF

<P0 CR/LF

>@RON CR/LF

<P0 CR/LF

: turn off RF circuit block

: command accepted

: turn on RF circuit block

: command accepted RST Reset RST{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to A22). Response P0 N0

: command accepted

: command error (Except 485 mode) Function Resets the modem to restore the power on state. When any memory register is rewritten with REG command before issuing this command, the value rewritten becomes valid and active. Temporary settings like DAS and FRQ command become invalid and the memory register settings is loaded. 49 Example

>@RST CR/LF

<P0 CR/LF Note

: reset the modem

: command accepted When a serial communication parameter in memory register is changed with REG command, the response of P0 returns according to the changed setting parameter, which may cause communication error. In such a case, set the communication parameter of the terminal equipment in correspondence with the new setting immediately after the issuance of RST command. SAS Reference and Set Local Station Address Syntax SAS (:set value){Local Station Address}

set value Local Station Address : local station address for 485 mode (000 to 999).

: new local station address (000 to 999) Response xxx P0 N0

: current value (reference)

: connection established (setting)

: command error Function References or sets the local station address. The current value can be referenced by entering this command with no parameter. For setting, input the desired value to set. The SAS command is for temporary local address and setting. To more permanently change the local station address value, use REG00. Example

>@SAS001

<P0

>@SAS

<001 STS

: set the station address to 001

: connection established

: reference the local station address

: output the current value (001) Read Status STS{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to 999). Response xxxxxxxx N0 Function

: modems current status (x = 0 or 1)

: command error (Except 485 mode) Reads the modem status register. (Represented with an 8-bit binary number.) 50 X X X X X X X X Bit Name 0 1 2 3 4 5 6 7 Connection Reception Output message Receive buffer Transmit buffer Reserved Reserved Reserved Status 1 0 Connected Disconnected Disabled Disabled Data exist Data exist Data empty Data empty Enabled Enabled

-

-

-

-

-

-

Figure 62: Modem Status Bit Description Example

>@STS CR/LF

<00001010 CR/LF

: read the current status

: Received data exist, Output message enabled, Reception disabled ,Disconnected. TBN Transmit Binary Data Syntax TBN[destination address][message byte length]{Local Station Address}[message]

Destination address Message byte length Local Station Address Message byte

: address of the transmission (000 to A23)

: message length (001 to 255)

: local station address for 485 mode (000 to A22).

: arbitrary binary data (255 or less) Response P0 P1 N0 N1 N2 N3

: data transmission succeeded

: command accepted, data being transmitted

: command error (Except 485 mode)

: data transmission failed -- no response from destination station

: data transmission failed -- destination station is in the reception disabled state

: data transmission failed -- destination station cannot receive because its receive buffer is full Function Transmits binary data in the packet transmission mode. Any message length between 1 to 255 bytes is accepted. The modem counts the number of message characters and transmits the message. For broadcasting messages to multiple modems, set the destination address to 255. In this case, the modem retransmits the message the number of times of the Retransmission count plus 1, and then it will return P0. In case the global addressing command is issued to plural modems connected by RS485 multi-dropping interface, the transmission stops when any modem outputs P0, N2 or N3 response to the RS485 line. Example

>TBN002005HELLO CR/LF

<P1 CR/LF

<P0 CR/LF

>@TBN003004MAIL CR/LF

: transmit HELLO from station 001 to station 002

: data being transmitted

: data transmission succeeded.

: retransmit MAIL from station 001 to station 003 51

<P1 CR/LF

<N1 CR/LF

: data being transmitted

: transmission failed, no response from destination station Notes Set the message length to 255 byte or less. The message length exceeding 255 byte will be command error. Message must be terminated with 2 byte (CR/LF) character, others will be command error. In broadcast transmission, the receiving result of the destination station cannot be confirmed at the sender side. TBR Transmit Binary Data through Repeater Syntax TBR [repeater address] [destination address] [message byte length]{Local Station Address}[message]

Repeater address Destination address Message byte length Local Station Address Message byte

: repeater address to pass through (000 to 999)

: address of destination station (000 to A23)

: message byte length (001 to 255)

: local station address for 485 mode (000 to A22).

: arbitrary binary data (255 or less) Response P0 P1 P2 N0 N1 N2 N3

: data transmission succeeded

: command accepted, data being transmitted

: data packet reached to repeater

: command error (Except 485 mode)

: data transmission failed -- no response from destination station

: data transmission failed -- destination station is in the reception disabled state

: data transmission failed -- destination station cannot receive because its receive buffer is full Function In the packet transmission mode, transmits binary data through repeater. Any message length between 1 to 255 bytes is accepted. The modem counts the number of message characters and transmits the message. For broadcasting messages to multiple modems, set the destination address to 255. In this case, the modem retransmits the message the number of times of the Retransmission count plus 1, and then it will return P0. In case the global addressing command is issued to plural modems connected by RS485 multi-dropping interface, the transmission stops when any modem outputs P0, N2 or N3 response to the RS485 line. Example

>TBR100002005HELLO CR/LF : transmit HELLO from station 001 to station 002

<P1 CR/LF

<P2 CR/LF

<P0 CR/LF

: data being transmitted

: data packet reached to repeater

: data transmission succeeded Notes Set the message length to 255 byte or less. The message length exceeding 255 byte will be command error. Message must be terminated with 2 byte (CR/LF) character, others will be command error. In broadcast transmission, the receiving result of the destination station cannot be confirmed at the sender side. 52 TID Display Local Station Serial ID TID{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to 999). Response XXXXXXXXXXXX N0

: displays the local serial ID code (12 digits)

: command error (Except 485 mode) Function Readout the local serial ID code of the modem and display it. This command corresponds to RID command. The local serial ID code consists of 12 digits; upper three digits are 0 and the lower 9 digits are the product serial number of the modem. Be noted the usage of RID command, the serial ID code of the packet received last is displayed. When packets are received from multiple stations and their data are stored in the receiving buffer, those data may not correspond to the serial ID code readout with the RID command. To use it more securely, it is recommended to readout the local serial ID code with the TID command and pad it (either all or a part of it) in the transmitting packet. The serial ID code is no relation with ID code setting of REG04 and 05. Example

: requests the modems local serial ID code

>@TID CR/LF

< XXXXXXXXXXXX CR/LF :outputs the modems local serial ID code TS2 Teat radio link TID{Local Station Address}

Syntax Local Station Address : local station address for 254mode (000 to 254). Response

: command accepted

: connect link, start measurement P0 Connect oooooooooooooooooooooooooooooooooo BER=0.0E-3 PER=0.00 PWR=-060dBm : read out Disconnect : disconnect link N0 N2 N7

: command error

: destination modem rejects reception

: the modem is trying to establish synchronization and cannot start the test Function To help evaluate the radio link condition, this command measures and outputs the Bit Error Rate, Packet Error Rate and Signal Intensity. 53 The command accompanying a destination address requests a connection to the destination address. The command without a destination address requests a connection to the address defined by the DAS command. The modem that has received a connection request starts actions of the TS2 immediately. The modem to which the command is entered is called TS2 master. The destination modem is called TS2 slave. The TS2 slave does not output any measurement results. Ten-consecutive failures in reception disconnect the radio link. Meanwhile, the TS2 master keeps outputting connection request. The TS2 master modem renews the measurement result approximately every 0.27second and continues outputting the measurement results until the TS2 command is terminated. To stop measurement, enter the command RST or turn off the modem. The radio modem, being turned into a special mode by this TS2 command, may output command error or irrelevant responses against all commands except RST command. The TS2 command always conducts address check. TXR Transmit Text Data through Repeater Syntax TXR [repeater address] [destination address]{Local Station Address}[message]

repeater address destination address Local Station Address message

: address of repeater to pass through (000 to 999)

: address of destination station (000 to A23)

: local station address for 485 mode (000 to A22).

: any text data (255 or less) Response P0 P1 P2 N0 N1 N2 N3

: data transmission succeeded

: command accepted, data being transmitted

: data packet reached to repeater

: command error (Except 485 mode)

: data transmission failed -- no response from the destination station

: data transmission failed -- destination station is in the reception disabled state

: data transmission failed -- destination station cannot receive because its receive buffer is full. Function Transmits text data in the packet transmission mode through repeater. Any message length between 1 to 255 bytes is accepted. The completion of data input is recognized by the terminator. For broadcasting messages to multiple modems, set the destination address to 255. In this case, the modem retransmits the message the number of times of the Retransmission count plus 1, and then it will return P0. In case the global addressing command is issued to plural modems connected by RS485 multi-dropping interface, the transmission stops when any modem outputs P0, N2 or N3 response to the RS485 line. Example

>@TXR100002HELLO CR/LF

: transmits HELLO from station 001 to station 002 through

<P1 CR/LF repeater 100

: data being transmitted 54

<P2 CR/LF

<P0 CR/LF

: data packet reached to repeater

: data transmission succeeded Notes Set the message length to 255 byte or less. The message length exceeding 255 byte will be command error. When the same character as the terminator (CR/LF) is contained in a message, the modem distinguishes it as the end of a command and ignore the subsequent data. In such a case, use TBR command. In broadcast transmission, the receiving result of the destination station cannot be confirmed at the sender side. TXT Transmit Text Data Syntax TXT [destination address]{Local Station Address}[message]

: address of destination station (000 to A23) destination address

: local station address for 485 mode (000 to A22). Local Station Address message

: any text data (255 or less) Response P0 P1 N0 N1 N2 N3

: data transmission succeeded

: command accepted, data being transmitted

: command error (Except 485 mode)

: data transmission failed - no response from the destination station

: data transmission failed - destination station is in the reception disabled state

: data transmission failed destination station cannot receive because its receive buffer is full. Function Transmits text data in the packet transmission mode. Any message length between 1 to 255 bytes is accepted. The completion of data input is recognized by the terminator (CR/LF). For broadcasting messages to multiple modems, set the destination address to 255. In this case, the modem will retransmit the message the number of times of the Retransmission count plus 1, and then it will return P0. In case the global addressing command is issued to plural modems connected by RS485 multi-dropping interface, the transmission stops when any modem outputs P0, N2 or N3 response to the RS485 line. Example

>@TXT002HELLO CR/LF

<P1 CR/LF

<P0 CR/LF

>@TXT003MAIL CR/LF

<P1 CR/LF

<N1 CR/LF

: transmits HELLO from station 001 to station 002

: data being transmitted

: data transmission succeeded

: transmits MAIL from station 001 to station 003

: data being transmitted

: transmission failed. no response from destination station Notes Set the message length to 255 byte or less. The message length exceeding 255 byte will be command error. When the same character as the terminator (CR/LF) is contained in a message, the modem distinguishes it as the end of a command and ignores the subsequent data. In such a case, use TBN command. 55 In broadcast transmission, the receiving result of the destination station cannot be confirmed at the sender side. VER Reference Version Information VER{Local Station Address}

Syntax Local Station Address : local station address for 485 mode (000 to 999). Response Program Version x.xxx N0

:Hardware system version

: command error (Except 485 mode) Function Reads the modems hardware system version. Example

>@VER CR/LF

<Ver 1.000 CR/LF

: read the version information

: this modem firmware is version 1.000 56 SECTION 7 7 APPENDIX Futaba Corporation Rev. 120626-02 7.1 Conversion Circuit Examples of the level conversion circuit are shown as a reference, which is just for the confirmation of system operation. This example does not guarantee the operation under users actual operation environment. 7.1.1 RS-232C Level Converter Wire the control line when necessary. Tie down unused input pin(s) to GND and leave the 485ENB pin open. Figure B1: RS-232C Level Conversion Circuit 7.1.2 RS422 Level Converter Wire the output terminator (100 ohm) of the RS422 line driver, the input terminator (100 ohm) of the receiver, the input pull-up (1k ohm) and the input pull-down (1k ohm), when necessary. Provide a surge absorber (e.g. Z2012 made by Ishizuka Denshi) when long RS422 line is used or there is much noisy environment, etc. 7.1.3 RS485 Level Converter Wire the terminator of the RS485 bus (100 ohm), the input pull-up (1k ohm) and the input pull-down (1k ohm), when necessary. When long RS485 line is used or there is much noise, provide the surge absorber (e.g. Z2012 made by Ishizuka Denshi) according to the situation. 58 1596STAND_BYDSRRxDRTSTxDCTSDTRDCDinGNDDSUB 9pinRS232CDriver/receiver1234567891011121314Vcc10uF0.1uFRxDTxDGNDDSRRTSCTSVccPOWER ONRX/TX/INITReserveSTAND_BYReserveReserve 7.2 Specification of the Connectors

(1) Serial Communication connector A Connector:

MOLEX 53780-1490 (14 pins)

(2) Serial Communication connector B Connector:

JST SM03B-SRSS-TB(LF)(SN) (3pin)

(2) Antenna connector RF connector: HIROSE U.FL-R-SMT The antenna connector is guaranteed for 30 times of plugging in/out. When plugging out the antenna connector, use the specially prepared tool of E.FL-LP-N, provided by HIROSE (HIROSE Product No. CL331-0441-9). Futaba Corporation Rev. 120626-02 7.3 Specification 7.3.1 Radio Characteristics Engineering standard RF power output Modulation Communication scheme Frequency band Frequency channel Data barer rate Oscillation Service area RF connector In/out of connector FCC Part 15.247 (no user license required)

>FCC ID : AZP-FDQ02T2 RSS-210 ISSUE6 (no user license required)

>CERTIFICATION No. 2914D-FDQ02T2 22.7mW max. Direct sequence spread spectrum Single communication 2405.376 to 2475.008 MHz 22 channels 134 kbps PLL synthesizer In an outdoor environment: more than 3000 feet (line-of-sight) Hirose U.FL-R-SMT 30 times max. using E.FL-LP-N extractor (for exclusive use) 7.3.2 Communication Control Radio link control Error checking Error handling Multi-access function Command control CRC-CCITT (16 bit) ARQ (Automatic Retransmission Request) Connect on clearest channel from selected frequency group 7.3.3 Data Terminal Interface Physical interface Interface specification Communication Synchronization Transmit/receive buffer Baud rate Flow control Data length Stop bit Parity Molex 53780-1470 (14 pins) JST SM03B-SRSS-TB(LF)(SN) (3pin) Serial communication Input CMOS level (5V tolerant with hysteresis) Output CMOS level Full-duplex or half-duplex system Asynchronous Approx. 3 k bytes in total 300 / 600 / 1200 / 2400 / 4800 / 9600 / 19200 / 38400 / 57600 / 115200 bps Hardware flow / Software flow 7 or 8 bit 1 or 2 bit Even, odd, or none 7.3.4 Power Supplying 7.3.4.1 Modem (Connector A) Supply voltage Current consumption 3.5 to 7.0 V DC 110 mA or less in the active mode 35 mA or less in the RF stop mode 1mA or less in the standby mode 7.3.4.2 Power Amp. (Connector B) Supply voltage Current consumption 6.0 to 9.0 V DC 150 mA or less in the transmitter mode 5 mA or less in the receiver mode 60 7.3.5 Environmental Operating temperature Storage temperature Operating humidity Storage humidity Vibration resistance Shock resistance

-20 to +50

-30 to +60 90%RH max. (no condensation) 90%RH max. (no condensation) JIS-C-60068-2-6:1999 (50m/s2, 10 to 150 Hz, 15 cycles JIS-C-60068-2-27:1995 (500m/s2)

(JIS specification is Japanese Industry Standard) 7.3.6 Miscellaneous Memory register Case Outer dimensions Weight Rewritable times: approx. 1 million times Ni plated steel plate 60 (W)50(D)8(H)mm Aprox. 30g Operating distances depend on the conditions such as obstructions and electrical interference. Under ideal, line-of-

sight conditions, reliable operating distances greater than specified may be achieved. Optional, directional antennas can significantly increase the operating range.

* Specifications and appearance are subject to change without prior notice. Futaba Corporation Rev. 120626-02 No.3 No.1 Communication Connector B 7.4 Outline View 7.4.1 FDQ02T No.14 Communication Connector A No.1 7.4.2 Communication Cable A 62 7.4.3 Antenna Type A 7.4.4 Antenna Type B 7.4.5 Antenna Type C Futaba Corporation Rev. 120626-02 Futaba Corporation Electronic Systems Business Center 1080 Yabutsuka Chosei Chiba, 299-4395 JAPAN Tel: +81 (475) 32-6173, Fax: +81(475) 32-6179 Internet: www.futaba.co.jp In the United States Futaba Corporation of America Industrial Radio Control Department 1605 Penny Lane Schaumburg, IL 60173 Tel: (847) 884-1444, Fax: (847) 884-1635 Internet: www.futaba.com 64