Alligator Communications 2888 Data Transport Radio User Manual 2888A Man V1

Alligator Communications Inc Data Transport Radio 2888A Man V1

Users Manual 2888A

 I   Alligator Model 2888 895 - 960 MHz   1200 Baud Data Transport Radio  MANUAL  Version 1.10               Alligator Communications, Inc. 317 Brokaw Road Santa Clara, CA  95050 Telephone: (408) 327-0800 Fax: (408) 327-0808   Copyright  2005 Alligator Communications All Rights Reserved
 II     CHARTER 1: GENERAL INFORMATION        1.1 General Description    1 1.2 Applications    1 1.3 Technical Specifications    1 1.4 Warranty    3 1.5 Claim for Damage in Shipment    4 1.6 Information to User As Required by FCC Section 15.21    4 1.7 RF Exposure Information    4      CHARTER 2: Radio Configuration and Operational Checkout        2.1               General Discussion    5 2.2               Operational Bench Test    5 2.2.1            Antenna Connector    5 2.2.2            Power Connector    6 2.2.3            Initial Checkout    6 2.2.3A         Power Checkout    7 Figure 2.1    LED Display    7 2.2.3B          LED Checkout    7 Table 2.2     LED Description Table    7 2.2.3C         Transmitter Test    8 2.2.3D         Receiver Test    8 2.2.3E          Deviation Test    9 2.2.5            Squelch Adjustment    10 2.2.7            Deviation Adjustment    12 2.2.10          Field Simulation Test    13 Figure 2.3    DB-9 Description and Pin Locator    15 Table 2.4     DB-9 Pin Function     15 Figure 2.4    2888 Internal Circuit Board    16 Figure 2.6    Diagnostic Computer Interface Port    17 Table 2.6     Diagnostic Computer Interface Port Pin Functions    17 2.6               Diagnostic Personal Computer Interface     18 2.6.1            Model 2888 Remote Radio Local Connect    18 2.6.2            Model 1800A Master Station Link Connect    19 2.6.3            Model 1800A Master Station Phone Dial-up Connect     20    Table of Contents
 III     CHAPTER 3: INSTALLATION        3.1      Mechanical Installation    21 3.2      Location    21 3.3      Electrical Interconnection    22           CHAPTER 4: THEORY OF OPERATION        4.1      General Discussion    23 4.2      Microprocessor Operation    23 4.3      Functions of the 2888 Radio    23 4.3.1   Diagnostic Parameters    23 4.3.2   Alarm Limits and Conditions    24 4.3.3   Operating Parameters    24 4.3.4   Communication Parameters    26           CHAPTER 5: MAINTENANCE        5.1     General Discussion    28 5.2     Test Equipment    28           CHARPTER 6: ALLIGATOR DIAGNOSTIC SOFTWARE      6.1 General Description    29 6.2 Theory of Operation    31
 1    1.1   GENERAL DESCRIPTION  The Alligator Communications Model 2888 is a microprocessor-controlled data radio transceiver designed to operate in accordance with FCC rules, Part 101, and in Canada under RSS-116 Issue 6.  The 2888 data radio is frequency synthesized and programmable to individual transmitter and receiver frequencies in the 928-929 MHz frequency band (US), and in the 896-929 MHz frequency band (Canada).  The transceiver is a fixed channel, half-duplex radio available with channel bandwidths of 12.5 kHz and 25.0 kHz.     1.2   APPLICATIONS  The 2888 data radio is designed for point-to-multipoint or point-to-point licensed operations in the 900 MHz band.   Some of the most common applications are:  Electric Utility Substation SCADA  Pipeline Flow Monitors Energy Distribution & Metering Applications Gas or Petroleum Production Well Head Control and Monitoring Water Distribution and Waste Water Collection Control and Monitoring Petroleum Production, Transmission, Storage and Distribution   1.3   TECHNICAL SPECIFICATIONS  GENERAL     Frequency Agility: 895.00 – 960.00 MHz, 6.25 kHz per Step Channel Spacing: Available in 12.5, 25.0 KHz Bandwidths Data Rates: 1200 bps Input Voltage: 13.2 Vdc Nominal (11-16 Vdc) Current Consumption:   * Receive Mode: 100 mA * Transmit Mode (5.00 Watts): < 1.75 A    Connectors:   * Antenna: Type “N” Female * Data: DB-9F, Subminiature 1.0 General Information
 2* Power: 2 Pin Captive Rectangular *Diagnostics: RJ-45 Jack Environment:   * Temperature: -30°C to +60°C * Humidity: 95% @ +40°C Dimensions: 6.5”W x 1.35”H x 5.5”D Weight: 1.5 Pounds    TRANSMITTER     RF Power: 5.0 Watt (+ 37 dBm) Impedance: 50 Ù Duty Cycle: Continuous Transmitter Attack Time: Less than 1msec Frequency Stability: +/-0.00015%, -30°C to +60°C Modulation Deviation:   * 12.5 kHz Band: +/- 3.0 kHz * 25.0 kHz Band: +/- 5.0 kHz Spurious and Harmonic Emissions: -60 dB Tx Timeout Timer (Programmable) 1-255 Seconds, or 0 for no Timeout    RECEIVER     Type: Double Conversion Superheterodyne Frequency Stability: +/-0.00015%,  -30°C to +60°C Sensitivity: -117 dBm minimum discernable signal 10E6 BER Threshold: -97 dBm  Selectivity: -100 dB Minimum at Adjacent Channel Desensitization:   * at 12.5 kHz Spacing: -60 dB * at 25.0 kHz Spacing: -70 dB Intermodulation: -70 dB (EIA) Spurious/Image Rejection: -80 dB Desensitization:   * at 12.5 kHz Spacing: -60 dB * at 25.0 kHz Spacing: -70 dB Intermodulation: -70 dB (EIA) Spurious/Image Rejection: -80 dB          Note: If other frequencies or power levels are required but are not listed, please contact factory.
 3 OPTIONS      INTERNAL MODEM: Emission Type: FSK     1200 BPS, Direct Interface, Asynchronous: RS-232    FCC INFORMATION     FCC Rules: Part 101 FCC Identifier: JIL2888 FCC Emission Designators: 12.5 KHz 8K00F1D    25.0 KHz 15K1F1D     1.4   WARRANTY  Alligator Communications, Inc., warrants each of the instruments of its manufacture to meet the specifications when delivered to the BUYER; and to be free from defects in material and workmanship.  Alligator Communications will repair or replace, at its expense, for a period of one year from the date of delivery of equipment, any parts that are defective from faulty material or poor workmanship.  Instruments found to be defective during the warranty period shall be returned to the factory with transportation charges prepaid by the BUYER.  It is expressly agreed that replacement and repair shall be the sole remedy of the SELLER with respect to any defective equipment and parts hereof and shall be in lieu of any other remedy available by applicable law. All returns to the factory must be authorized by the SELLER, prior to such returns.  Upon examination by the factory, if any instrument is found to be defective, the unit will be repaired and returned to the BUYER, with transportation charges prepaid by the SELLER.  NO OTHER WARRANTY IS EXPRESSED OR IMPLIED.  ALLIGATOR COMMUNICATIONS IS NOT LIABLE FOR CONSEQUENTIAL DAMAGES.
 41.5 CLAIM FOR DAMAGE IN SHIPMENT  The instrument should be inspected and tested as soon as it is received.  If the instrument is damaged in any way, or fails to operate properly, a claim should immediately be filed with the freight carrier, or if insured separately, with the insurance company.  WE PLEDGE OUR IMMEDIATE AND FULLEST COOPERATION TO ALL USERS OF OUR ELECTRONIC EQUIPMENT.  PLEASE ADVISE US IF WE CAN ASSIST IN ANY MANNER:  Alligator Communications, Inc.   317 Brokaw Road   Santa Clara, CA 95050   Phone: (408) 327-0800   FAX: (408) 327-0808   E-mail: sales@alligatorcom.com   Website: www.alligatorcom.com     1.6   INFORMATION TO USER AS REQUIRED BY FCC SECTION           15.21  Changes or modifications not expressly approved in writing by Alligator Communications, Inc. may void the user’s authority to operate this equipment.    In accordance with FCC Rules Section 15.21, the user of this equipment is advised that changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment.   1.7 RF EXPOSURE INFORMATION  FCC Rules 1.11307 and Industry Canada RSS-102 regulations contain limits on human RF exposure from transmitters. To meet these requirements, during operation, the antenna of this device must be kept at a minimum distance of 112 cm from all persons.
 5     2.1   GENERAL DISCUSSION  Prior to customer installation and electrical connection of the customer’s terminal equipment to the 2888 radio, it is recommended that the installing technician conduct a brief operational checkout of the 2888 radio and confirm that all operating parameters are set as desired.    This initial checkout and possible reprogramming is generally performed on the maintenance shop test bench before the radio is installed and commissioned in a link application.  The following parts of this section provide guidance in this checkout process, and illustrate alternate configurations and paths to perform the initial checkout.  Please refer to Figure 2.2 (DB-9 Locator), Table 2.3 (DB-9 Pin Functions), Figure 2.3 (Locations of Adjustment Components on Main P.C. Board  For a definition of all 2888 radio functions and possible configurations, see Section 4.3.   2.2   OPERATIONAL BENCH TEST  To ensure that the 2888 radio is functional prior to installation at the desired site, it is highly recommended that the following tests be performed in sequence (please refer to Figure 3.1, Model 2888 External Connectors, Page 3-2):  2.2.1 ANTENNA CONNECTOR  The 2888 radio antenna port (RF Connector) is a coaxial, female, type N connector.  This connector mates with a cable connector male, type N such as Amphenol 3900, Andrew L44N, or MIL Type UG-21.  Under most circumstances, bench tests are conducted with a service monitor (manufactured by IFR Inc., Marconi Instruments Ltd., Hewlett-Packard, Motorola, etc.).2.0 Radio Configuration and Operational Check
 6 CAUTION The transmitter should not be keyed on or placed in the transmit mode without a load on the antenna port to prevent damage to the 2888 radio Power Amplifier due to long periods (more than 10 minutes) of severely high SWR.  An antenna, service monitor, or dummy load should be attached to the antenna port.  The 2888 radio power output is approximately 5.0 watt maximum, so if a service monitor is connected to the antenna port, ensure that the service monitor’s input port can handle at least 10 watt input to avoid damaging the service monitor.   2.2.2   POWER CONNECTOR  The dc power input connector to the 2888 radio is a rectangular two-pin locking connector.  The radio unit is normally powered upon connection to a DC power source delivering  +11 to +16 Vdc, +13.8 Vdc nominal.  The red conductor is positive; the black conductor is negative and is internally grounded to the chassis.    2.2.3   INITIAL CHECKOUT  Alligator wireless data transport products are factory configured according to customer configuration information received prior to shipment from the factory, thereby minimizing customer field configuration requirements.   To verify that 2888 radio parameters are correct, we recommend the following minimal tests be conducted with regards to the transmitter and receiver settings of the 2888 radio.   With the service monitor connected to the antenna port, proceed to conduct the following preliminary tests:
 7A.   Power Checkout  With DC power applied to the PWR IN connector, the power LED should illuminate and remain on.  Pin 6 of the DATA connector should measure +10.0 Vdc nominal which is the output from the voltage regulator (Note: Pin 5 is dc ground, signal ground and is also grounded to the chassis).   cDATAPWR INDIAGNOSTICS PWR DCD RXDRTS CTS TXD ANTENNA      Figure 2.1  LED Display   B.   2888 LED Checkout  Briefly observe the behavior of each of the 6 LED indicators with reference to the following table:   LED Description TXD (Transmit Data) Indicates the 2888 radio is receiving incoming data from the customer’s interconnected terminal to be transferred to the destination.    RXD (Receive Data) Indicates the 2888 radio is receiving data over the air from an associated radio or communications test set.  DCD (Data Carrier Detect) Indicates the 2888 radio is receiving a sufficient level of RF carrier signal to open the receiver’s squelch gate.  RTS (Request To Send) Indicates the customer’s interconnected terminal is requesting to send data.  CTS (Clear To Send) Indicates the 2888 radio is ready to receive data from the customer’s interconnected terminal.  PWR (Power) Lights up whenever the radio is powered up.  Off when radio is powered down.  Table 2.2 LED Description
 8 C.   Transmitter Test   CAUTION To avoid possible damage to your service monitor, be sure that the input port can handle at least 10 watt.   Key the Tx by pulling RTS pin 7 of the DB9 data interface port high.  This can be accomplished by shorting RTS pin 7 with DSR pin 6.  At this time, the RTS & CTS LEDs should light up.  As long as the keying signal is on, both LEDs will remain on until the time exceeds the time out timer value, which is factory set at 30 seconds or at a customer programmed timing interval.    Measure the RF power level as inputted to a calibrated communications test set or to a RF power level meter to measure the 2888 transmitter power output. Note: The output power should be about 5.0 watts (when +13.8 Vdc is the power supply voltage), which is the factory setting.  Note the transmitted frequency on a calibrated Communications Test set and compare this reading to the desired Transmitter frequency setting of the 2888 radio.  Note: The Transmitter time out operating parameter can be set for 0 to 255 seconds, with 0 meaning that the transmitter will not time out and will follow the keying signal no matter how long it lasts.  Use the Alligator Advanced Diagnostics Software to change the value of this parameter.  This can be found under the Change Operating Parameters option under the Remote sub-menu.    D.   Receiver Test  With the service monitor connected to the antenna port (Figure 3.1, ••, Page 3-2), turn on the service monitor’s RF signal generator.  Set the frequency of the service monitor’s RF signal generator to the programmed receive frequency of the 2888 radio.  The 2888’s DCD LED should turn on for an input level which is higher than the receiver squelch level.
 9 With the squelch level set at 0.7 ìV (-110 dBm), an RF signal level of 0.5 ìV or lower will turn squelch on (DCD LED off).  For an RF input of 10 ìV, 1.2 kHz modulation frequency, and +/- 3.0 kHz deviation from the service monitor, you should see the RXD LED light up.  The DCD LED should light up, and the RXD LED should light up for a square wave 20 volts peak-to-peak with frequency of approximately 1.2 kHz going through Pin 2 (RXD) of the DB-9 connector.  This output is RS-232 compatible.  The receiver squelch level is factory set at 0.7 ìV (-110 dBm).  The RSSI level can be measured at Pin 5 of the RJ-45 connector.  Approximately +1.2 Vdc = 1 ìV (-107 dBm) RF, +2.3 Vdc = 10 ìV (-87 dBm) RF, and +3.2 Vdc = 100 ìV (-67 dBm) RF.  The RSSI will become saturated at approximately +4 Vdc with a 1 mV (-47 dBm) or higher RF input.  E.   Deviation Test    Check the deviation level of the 2888 Radio by keying on the transmitter using RTS, and presenting an alternating square wave to the TXD input utilizing a test data frequency of 600 Hz to 3000 Hz.  The amplitude of this wave should be at least 10 volts peak-to-peak and the low level of the square wave must be less than 0.5 volts.   Since the IF bandwidth of a service monitor determines how much signal goes through, a narrow bandwidth will create overshoot in the square wave, resulting in a deviation reading which is higher than the actual deviation.  Choose the highest bandwidth setting possible for the service monitor.  Read the deviation of the Remote Radio from the service monitor.  If it reads around +/- 3.0 kHz (+/- 5.0 kHz for wide band), no further adjustment is necessary.  The RTS, CTS, and TXD LEDs should all light up.  If for any reason a lower deviation than that set by the factory is desired, refer to Section 2.2.7 for adjusting the deviation level.  CAUTION For a Remote Radio with a 1200 BPS data rate, any deviation exceeding +/- 3.0 kHz (+/- 5.0 kHz for wide band) will violate FCC Rules Part 90.  Never adjust the deviation for more than this value.
 10 2.2.5 SQUELCH ADJUSTMENT  By default, the factory sets the squelch level to 0.7 ìV  (-110 dBm).  If a different squelch level is required for the 2888 Radio, you can adjust the mechanical potentiometer located at R131 on the 2888 Radio P.C. Board (see Figure 2.3, „„).  The squelch level can be adjusted from 0 to 5 ìV .  A.   Determining the Squelch Level    To properly adjust the squelch level, the squelch level should be set according to the site where the Remote Radio is to be installed.  If the squelch level is set too low (less than 0.5 ìV or -113 dBm), it will be likely that environmental interference or other various noise to initiate the triggering of the squelch.  This may create invalid data from noise to be sent to the RTU and may result in invalid received data packets.   For any squelch level below 0.5 ìV (-113 dBm), note invalid data can be generated due to outside interference.  A low squelch level setting is not recommended for an RF link with a strong signal level (due to close proximity or a good antenna setup); a higher squelch level is recommended for these kinds of situations.  A good squelch level setting is always a compromise between interference from the environment, the receive RF level, background noise, and the fade margin.  In order to calculate the recommended squelch level, you must first calculate or measure the receive level.  For a fairly strong receive level (greater than 100 ìV or -67 dBm), subtract 20 to 30 dB away from the receive level (to account for the fade margin), then set the squelch level 3 to 4 dB below that point.  For example, a typical situation follows:   Receive level in RF path: -67 dBm (typically 10 miles separation)  Lowest possible receive level: -67 dBm - 20 dB (fade margin) = -87 dBm   Recommended squelch level: -87 dBm - 3 dB = -90 dBm    If the receiver level is under 5 ìV for a weak RF path under ideal environmental conditions, the squelch level should be set to 0.5 ìV (-113 dBm).
 11The level to turn squelch on and the level to turn squelch off is approximately 3dB difference.  For example, if the level to turn squelch off (Rx LED on) is 0.7 ìV, the level to turn squelch on (Rx LED off) has to be approximately 0.4 ìV.  The purpose of this is to prevent squelch noise when the receive level is at this threshold point.  This is the 3 dB hysteresis gap between squelching and unsquelching the receiver.   B.   Adjusting the squelch level  After determining the appropriate squelch level, set the RF signal generator to that level.  Connect the output port of the service monitor to the antenna port of the 2888 Radio  (Figure 3.1, ••, Page 3-2).  Turn the Squelch Adjustment Potentiometer located at R57 (Figure 2.3, „„) counterclockwise to the turn limit.  Then, rotate the potentiometer clockwise slowly until you see the Rx LED solidly on, then stop turning immediately.  To verify proper adjustment, reduce the RF input to the 2888 Radio by approximately 4 dB.  The Rx LED should turn off solidly.  If this is not the case, a minor counterclockwise adjustment may be required to insure squelch to be off at the required receive level, and turned on 4 dB below the required receive level.
 12 2.2.7   DEVIATION ADJUSTMENT  If the factory setting for the deviation is not what is desired, you can use the Alligator Advanced Diagnostics Software to set the digital potentiometer on the P.C. Board (if the deviation adjustment option is installed), or manually adjust the mechanical deviation potentiometer R104 (Figure 2.3,ˆˆ) after removing the top cover.  The factory presets both potentiometers for a deviation of +/- 2.2 kHz for 12.5 KHz channels  (+/- 3.5 kHz for 25 KHz channels; the digital deviation potentiometer is set at position 27), which is the maximum deviation allowed to avoid violating FCC emissions rules.   To properly receive the transmitted data at the destination, deviation settings of less than +/- 1.5 kHz are not recommended.   If for any reason a lower deviation than that set by the factory is desired, you may change the position of the digital potentiometer by accessing the FM Deviation Adjustment option under the Remote sub-menu.  Use the <+> and <-> keys to raise and lower the deviation, respectively.  Whenever the digital potentiometer position is changed, you must first unplug the DB-25 connector from the radio (when doing a local adjustment) and transmit a square wave 10 volts peak-to-peak, low level lower than +0.5 Vdc, between 600 Hz and 3000 Hz through the TXD line, with RTS high, to see the results of the deviation adjustment on the service monitor.    The deviation digital potentiometer is already at the maximum position of 31.  If the potentiometer position is at 31 and a higher deviation is required, you must first set the position to 27, and then adjust the mechanical deviation potentiometer R309 (Figure 2.3,••) while inputing the square wave as described above, until the desired level is achieved.  Turning the mechanical potentiometer counterclockwise will result in a lower deviation.  Repeat this process until the desired deviation is achieved.  CAUTION For a Remote Radio with a 4800 BPS data rate, any deviation exceeding +/- 2.2 kHz (+/- 3.5 kHz for wide band) will violate the FCC rules.  Never adjust the deviation for more than this value.  For a data rate lower than 4800 BPS, a higher deviation may be used, but +/- 2.2 kHz (+/- 3.5 kHz for wide band) deviation is still the recommended maximum value.
 132.2.10  FIELD SIMULATION TEST  When the 2888 Radio has passed the initial series of tests, it is now ready for field simulation testing.  NOTE:  A second 2888 Radio or a Model 1800A Master Station Radio configured to link with the 2888 Radio under test is required to perform this test.  (1) Connect a 50 Ù Dry load to the antenna port of the Model 2888 Radio.    (2) Connect a 50 Ù Dry load to the antenna port of the 2888 Radio or Model 1800A Master Station Radio that is configured to communicate with the 2888 Radio under test    (3) Place the 2888 Radio 5 to 20 feet away from the 1800A Master Radio.    (4) Be sure that the transmit frequency of the 2888 Radio under test matches the receive frequency of the opposite link end 2888 Radio or Model 1800A Master Station Radio being utilized for the test, and that the receive frequency of the 2888 Radio under test matches the transmit frequency of the opposite link end test radio.  Utilize the Alligator Advanced Diagnostics Software or a service monitor to verify the complementary frequency configuration information.    (5) Key the transmitter of the 2888 Radio under test by applying a high logic to the RTS input pin.  Observe that the SQUELCH LEDs on the Master Radio turn on and off solidly whenever the 2888 Radio under test is keyed off and on, respectively.    (6) Observe that the DCD LED on the Remote Radio is lit when it is not being keyed, whenever the TX ON AIR LED on the 1800A Master Station is lit.    (7) Repeat Steps 1 through 6, except connect the Remote and Master Radios together using an attenuator (80 to 100 dB gain).  If one is not available, you may connect the two radios together using a series of smaller gain attenuators to achieve 80 to 100 dB signal attenuation.  Ensure the attenuator(s) are rated 1.0 to 5.0 watts.
 14Model QS1 RadioRemote TerminalUnit 1800G Radio Host Computer5 to 20 Ft. Separation   Model QS1 RadioRemote TerminalUnit 1800G Radio Host Computer80 dB to 120 dBAttenuation
 15Figure 2.3 DB-9 DESCRIPTION AND PIN LOCATOR   Pin#1Pin#6Pin#9Pin#5  View of the DB-9 connector from outside of the radio enclosure.      Table 2.4   DB-9 PIN FUNCTIONS   Pin Function/Comment 1 DCD (Data Carrier Detect) from Radio to RTU 2 RXD (Receive Data Output) -Data from Radio Receiver to Field Device 3 TXD (Transmit Data Input)  - Data from Field Device to Radio Transmitter 4 Not Connected 5 Signal Ground 6 DSR (Data Set Ready) from Radio to RTU 7 RTS (Request to Send) from RTU to Radio 8  CTS (Clear to Send) from Radio to RTU 9 Not Connected  Table 2.3  Pin Assignments for DB-9 Data Interface Port   Figure 2.3 DB-9 connector; Model 2888
 16uProcessorRF ConnectorDB- 9DataPortDiagnosticJackDC InputTCXOR104R110R131Tx Modulation AdjustTCXO Coarse AdjustSquelch AdjustAlligator Communications2888  Radio Circuit Board      Figure 2.4, Model 2888 Internal Circuit Board
 17 Figure 2.6   RJ-45 Diagnostic Port  1 2 43 5 6 87    View of the RJ-45 diagnostic port connector from outside of the radio enclosure           Table 2.6   RJ-45 PORT PIN FUNCTIONS   Pin Function/Comment 1 10 VDC (High) 2 Signal and DC Ground 3 PTT/ (Keys Tx when Grounded) 4 DTMF Tones Out 5 DTMF Tones In 6 RSSI Ramp Voltage (0.2 to 4.0 VDC) 7 RXMute (Mutes RX during Diagnostics) 8  Alarm Logic Output Pin
 182.6   DIAGNOSTIC PC INTERFACE  A diagnostic computer running the Alligator Advanced Diagnostic Software can interface with a Model 2888 Radio in a number of ways.  The following sections diagram the most common system configurations.  2.6.1   Model 2888 Radio Local Diagnostic Connect  cDATAPWRINDIAGNOSTICSPWRDCDRXDRTSCTSTXDANTENNALaptop computer   Figure 2.5  - Remote Radio Local Link  In this configuration the sub-menus of the diagnostic software are fully functional.  To link the computer to the Model 2888 Remote Radio: first, connect the male DB-25 connector of the DTMF Converter Cable to the female DB-25 parallel port of the diagnostic computer.  Then connect the male RJ48 connector of the DTMF cable to the female RJ45 connector on the QS-1 Radio.    Required Hardware: 1ea   PC to DTMF converter (Part No. 4000-0002)
 192.6.2 Model 1800A Master Station Local Connect   PC to DTMF Converter CableALLIGATORcommunications, inc.Model 1800 Master StationABDiagnosticComputerModel 1800 RadioRemote RadioNetwork  Figure 2.6 - Model 1800A Master Station Local Link  In this configuration the Alligator diagnostics software is fully functional.  To link the computer to the Model 1800A Master Station: first, connect the male DB-25 connector of the DTMF converter cable to the female DB-25 parallel port of the diagnostic computer.  Then connect the male RJ48 connector of the DTMF cable to the female RJ48 port on the back of the master station (See Figure 2.6, above).  The RJ48 port on the master station is labeled PC (DTMF)(See Figure 2.7, below).  Required Hardware: 1 - PC to DTMF converter (Part No. 4000-0002)   TB1TB2114114PHONEPC(DTMF)MODEMRJ48 Port for PC to DTMF Converter, Local LinkRJ11 Port for Dial-up Auto-Answer 1    TX AUDIO +                             EXT BAT A + 2    TX AUDIO -                              EXT BAT A - 3    RX AUDIO +                             EXT BAT B + 4    RX AUDIO -                              EXT BAT B - 5    RX A RSSI                                BATTERY ENABLE 6    RX B RSSI                                GROUND 7    TX CHANGE ENABLE                8    VOX ENABLE 9    GND                                        NO10   13.8V / 100ma                        COMMON11   LOW KEYLINE                          NO12   GROUND                                 NO13   +12V KEYLINE                         COMMON14   +24/48V KEYLINE                    NOMODULEALARMACFAILURETB1TB2 Figure 2.7 - Model 1800A Master Station Rear Panel
 202.6.3 Model 1800A Master Station Phone Dial-up Connect  Dial-up Interface ModuleRemoteRadio NetworkALLIGATORcommunications, inc.Model 1800 Master StationABModel 1800 Master StationDTMF to PC Converter         CableDiagnosticComputer Figure 2.8 - Phone Dial-up Master Link   In this configuration, the Alligator diagnostics software is fully functional.  This configuration requires the Dial-up Auto-Answer option be installed on the connected Model 1800A. To link the computer to the Model 1800A via telephone: first, connect the male DB-25 connector of the DTMF Converter Cable to the female DB-25 parallel port on the back of the diagnostic computer.  Then, connect the male RJ48 connector of the DTMF cable to the female RJ45 connector on the Dial-up Interface Module.  Then use a standard RJ11 phone cord to connect the interface module to an operational phone jack.  At the master station location, connect the Model 1800A to an operational phone jack also using a standard RJ11 phone cord (See Figure 2.8, above).  The RJ11 phone port is located on the rear panel of the Model 1800A and is labeled PHONE (See Figure 2.7, previous page).  Required Hardware: 1  -- PC to DTMF converter (Part No. 4000-0002)  1  -- Dial-up Interface Module (Part No. 4000-0004)  1  -- Dial-up Auto-Answer option installed on Model 1800A
 21       3.1   MECHANICAL INSTALLATION  The Model 2888 radio is shipped with a universal mounting bracket which can be attached to the radio enclosure and allow mounting the radio on a wall or other flat surface (6-32 X 5/16" round head screws are provided to secure the bracket to the enclosure).  The bracket will accommodate four 1/4" fasteners.   CAUTION If substitute screws are necessary for the 6-32 X 5/16” round head screws, do not use screws which extend into the chassis more than 5/16”. Doing so might contact and damage the P.C. Board in the radio.   Note:  In the event of an uneven mounting plane, consider using two (diagonally opposite) or three fasteners rather than four, which might distort the bracket and radio enclosure, resulting in physical damage.   3.2   LOCATION  Monitoring the diagnostics and/or changing the parameters of the 2888 radio is possible by using a local computer connected to the RJ-45 connector of the 2888 radio.  If this is desired, attempt to locate the radio with convenient access to the 2888 connector.   Note:  Attempt to position the transceiver away from main power lines and hydraulic or pneumatic lines.  A catastrophic failure of any of these lines in close proximity to the radio transceiver could damage the radio and disrupt communications at a time when specific alarms are most needed.  Also, service technicians repairing these types of failures require space to work and might inadvertently damage the radio or cables.  3.0 Installation
 223.3 ELECTRICAL INTERCONNECTION  The Model 2888 radio has four external connectors.  These connectors provide access to the antenna, power supply, associated RTU and diagnostic computer    Figure 3.1 illustrates the connector locations and their usage.      cDATAPWR INDIAGNOSTICSPWR DCD RXDRTS CTS TXD ANTENNA         2   3   4      1   •• Antenna Feedline:  RF signals are transmitted and received via a coaxial cable (not supplied) connected to a type "N" connector. Note: Most feedlines are substantial in size and relative rigidity.  It is suggested that a flexible "coaxial pigtail" be used between the feedline and the radio to preclude the application of mechanical stress to the connector and/or radio. ‚‚ Power Cable:  Power is supplied to the radio transceiver via a two-conductor cable and a power connector (supplied).  Red wire to + 13.8 Vdc and black wire to Ground If a power supply voltage other than 13.8Vdc is required, an external DC-DC converter will result in the red wire reading the desired power supply voltage. ƒƒ Diagnotics Port: RJ45 connection for the DTMF diagnostic cable(P/N 4000-0002) „„ Interconnecting Cable: The RTU connects to the radio transceiver via a multiconductor cable (not supplied) and a DB-9 connector.  Section 2.4 includes a pin-by-pin commentary on the function of each pin in the DB-9 connector.  The connector should be tightened using two 4-40 X 1/4” long screws to avoid losing contact between the cable and connector before the radio is in service.  Figure 3.1 Model 2888 External Connectors
 23    4.1   GENERAL DISCUSSION  The 2888 radio is a half duplex transceiver intended for use as either a Master or a Remote Station Radio unit in a Wireless SCADA data transmission system.     4.2   MICROPROCESSOR OPERATION  The microprocessor, U-203 is the "brain" of the 2888 radio.  It enables a computer to communicate with the 2888 radio and enables the operator to "see" everything that the Remote "sees", such as diagnostics.  The microprocessor also allows the operator to observe the operating parameters, frequency, power output, reverse power, PLL voltages, the power output level and the frequency offset.  These and other operations may be performed locally or through the RF link.  4.3   FUNCTIONS OF THE 2888 RADIO  The Alligator Model 2888 offers diagnostic parameters which aid the user in troubleshooting potential problems in the SCADA network.  The Model 2888 also offers options which enable the radio to be a “smart” radio.  It may also be configured for use in a variety of different configurations.  The Alligator Advanced Diagnostics Software can read and/or modify all of the following parameters for each responding Model 2888 Radio.  4.3.1   Diagnostic Parameters    Parameter Description Alarm Status  Alerts the user that one or more of the diagnostic parameters are not within the safety limits.  Received Signal Strength Indicator (RSSI) An indicator of a Remote’s signal strength.   Forward Power The amount of power the carrier frequency is being transmitted.  Reverse Power An indicator of the quality of the Remote Radio’s antenna.  A reverse power reading greater than one-third of the forward power reading indicates that the antenna is degrading, or that cables and connectors are not properly connected to the radio.  4.0 Theory of Operation
 24 Parameter Description Supply Voltage The recommended power supply to the Remote Radio should be no less than 11 V and no more than 16V, with 13.8V the nominal voltage. A power supply capable of supplying at least 2 amps is required for proper operation of the radio.  PLL Voltages The voltage readings of the two Phase-Locked-Loops (PLL1 & PLL2).  For safe radio operation, this voltage should be between 0.1 to 4 Volts.  Internal Temperature Serves as a “thermometer” for the environment surrounding the radio. Also serves as a sign if something is wrong with the Remote Radio.  Table 4.2 Diagnostic Parameters Descriptions   4.3.2   Alarm Limits and Conditions  The Alligator Advanced Diagnostics Software provides the user with the capability to set the desired safety limits for each diagnostic parameter.  The user can set high and low limits for Supply Voltage, PLL1 Voltage, PLL2 Voltage, Internal Temperature, Forward Power, and event (squelch, PTT, Time-out) counters.  Should any of these parameters fall outside its safety limits, an alarm condition will be generated and displayed by the Remote Radio.  An alarm condition will also exist if the Reverse Power (reflected power) reading exceeds 30% of the Forward Power reading, or if the VSWR (Voltage Standing Wave Ratio) reaches an unsafe value.  4.3.3   Operating Parameters  The Alligator Advanced Diagnostics Software enables the user to configure each Remote Radio to operate in a certain configuration.  Each Remote Radio can be configured to operate under any of the following configurations:   Parameter Description PTT Dekey Time (0-255 msec) Whenever the 2888 Radio turns on its transmitter, the dekey time is the number of milliseconds the transmitter stays on after the radio is dekeyed. Some applications require squelch-tail elimination, and other applications may require that the master station is never squelched.  By keeping each of the Remote’s transmitters on for an extra few milliseconds, the Remotes will overlap each other during polling cycles, thus the master station’s receiver modules will always be receiving something. For applications where a dekey time is not required, this
 25 Parameter Description parameter should always be programmed to 0 milliseconds.  The factory automatically sets this value to 0 milliseconds unless the customer specifies otherwise.  Tx On Delay Time (0-255 msec) For some applications, especially when one or more repeater stations involved in a SCADA system, the 2888 Radio may need to delay turning on its transmitter whenever it is keyed.  Time-out Duration (0-255 sec) To prevent lockup of the transmitter, each 2888 Radio can be individually programmed to shut off its transmitter if it is keyed on for a certain number of seconds.   If this value is zero, the transmitter will never time out.  When setting this parameter, be sure that this duration is longer than the longest possible transmit time for each data transmission.  RTS/CTS Delay for Internal Modem (0-255 msec) Each Radio needs a certain amount of time to get ready for data to be transmitted over the air.  The RTS (Request To Send) signal is the command from the RTU to key on the 2888 Radio.  The CTS (Clear To Send) signal is the indicator from the Remote Radio to the RTU that it is ready to send the data supplied by the RTU.  This delay time is simply the minimum amount of time that the data must be delayed starting from the RTS signal.  The Alligator Model 2888 Radio can handle a delay of 1 millisecond, but the most effective value is anywhere from 10 to 20 milliseconds.  The factory default setting is 10 milliseconds.  PTT Limit (per 10-second interval) (0-255)  This parameter is used mainly to detect problems with external keying circuits. Each Remote Radio is capable of counting the number of external keys within every 10-second interval of operation.  If the number of external keys exceeds the PTT Limit, the PTT operating parameter will automatically become disabled.  Using the Alligator Advanced Diagnostics Software, the Remote Radio will alert the user that PTT had been disabled due to erratic keying.  Once the user investigates the problem and fixes it, the user can then enable PTT. The factory preset this value to 255.  A value of 255 means that there is no limit to the number of external keys that can occur within each 10-second time frame.  Table 4.3 Description of Operating Parameters
 26  4.3.4   Communication Parameters  The Alligator Advanced Diagnostics Software enables the user to configure each Remote Radio to operate in a certain configuration.  Each Remote can be configured to operate under any of the following configurations:   Parameter Description Transmitter Frequency  Each 2888 Radio’s transmitter can be individually programmed to frequencies in the FCC designated 895 - 960 MHz Band.  Radio Address  Each 2888 Radio’s identification address can be changed at any time. Each address consists of a unique 4-digit number.  Mechanical Frequency Potentiometer for Manual Frequency Adjustment  For users who do not like to deal with digital potentiometers or automatic frequency adjustment schemes, it is possible to disable the frequency digital potentiometer on the 2888 Radio and use the mechanical potentiometer R110 to tune the Remote Radio’s reference standard frequency at the site.  This mechanical potentiometer has 25 turns and has an adjustment range of approximately +/- 7 kHz, with an accuracy of 100 Hz.  This frequency adjustment scheme can only be enabled if the technician is at the Remote site, since changing from the digital potentiometer to the mechanical potentiometer can be dangerous if done over-the-air.   Digital Frequency Potentiometer for Manual Frequency Adjustment  By enabling this parameter, the user can manually adjust any 2888 Radio’s frequency, remotely or locally, using the Alligator Advanced Diagnostics Software.  The software allows the user to move the frequency digital potentiometer one step at a time.  Each step of the digital potentiometer will adjust the Remote Radio’s frequency by approximately 200 Hz each step. The adjustment range for this digital potentiometer is approximately +/- 3 kHz. Automatic Global Frequency Calibration (AGFC) (Optional Feature) (YES/NO) By enabling AGFC, each 2888 Radio will continuously and automatically adjust its own TCXO frequency to match that of its received carrier frequency whenever it has finished transmitting data, without using any special hardware circuits to constantly track the TCXO bias voltage.  All adjustments are done through the on-board microprocessor to insure that the Remote Radio does not lock onto an interfering signal or environmental noise.    A frequency digital potentiometer is used and controlled by the on-board microprocessor, so even if the 2888 Radio is powered down, the frequency of the Remote will remain unchanged after power up.  In other
 27 Parameter Description words, after the Remote Radio is correctly adjusted, its frequency will remain unchanged, even if the master station’s signal has disappeared (for Remote Radios operating under traditional AFC, the TCXO bias voltage becomes unstable if the master station’s signal disappears and requires some time to follow the Master Station’s signal after squelch is off).  This AGFC frequency adjustment scheme will enhance the reliability and stability of the Remote Radio’s frequency at all times, without the disadvantages of “traditional” AFC.  The accuracy of adjustment is 200 Hz.  This automatic frequency adjustment scheme cannot be enabled when either of the Tx and/or Rx AFC schemes are enabled.  Whenever AGFC is enabled, Tx and Rx AFC automatically become disabled.  It is always good practice to calibrate the master station’s RF signal before adjusting any of the 2888 Radio’s frequencies.  As a safety precaution, each frequency adjustment will be by no more than 200 Hz every time the Remote Radio has just finished transmitting data.    Tx AFC (YES/NO) Rx AFC (YES/NO)  By enabling Tx or Rx AFC, each 2888 Radio will automatically adjust its own Tx or Rx frequency to match that of its received carrier frequency whenever it is receiving an RF signal.  The adjustment accuracy is 400 Hz, and offers less immunity to interfering signals compared to AGFC.  AGFC is also smart enough to adjust only when the Remote Radio has just finished transmitting data, while Tx and Rx AFC are not.  Whenever Tx and/or Rx AFC are to be enabled, AGFC must be disabled first.  Adjustments are done based on the AGFC Counter Limit (see above).   Table 4.3 Communication Parameters Descriptions
 28     5.1   GENERAL DISCUSSION  While the 2888 is a reliable and relatively maintenance free radio, there are a few quick checks and adjustments that may be made to ensure continued worry-free operation.  These procedures should only be performed by qualified engineers or technicians.  Should any problems arise or there are any questions that would assist in maintaining the radio, we invite you to call Alligator Communications Customer Service Department at 1-408-327-0800, 8 A.M. to 6 P.M. Pacific Standard Time.   5.2   TEST EQUIPMENT REQUIRED  •• Communications Test Set/Service Monitor.  This instrument performs the combined functions of an RF and audio signal generator, a frequency counter, a modulation analyzer, and an RF wattmeter.  These units are usually equipped with an input-attenuated pad (or dummy load) that allows the full output of the radio to be transmitted directly into the instrument.  If this feature is not included, a separate dummy load must be used.  Suitable monitors are made by Hewlett-Packard, Motorola Inc., Marconi Instruments Ltd., and IFR Inc.    ‚‚ Multimeter.  A basic multimeter, such as a Simpson or a Fluke, will meet this requirement.    ƒƒ Oscilloscope.  If the service monitor does not include a low frequency oscilloscope, then a basic one is needed.  5.0 Maintenance
 29       6.1   GENERAL DESCRIPTION  Alligator Communication's Advanced Diagnostic Software (ALLI) reads and modifies all operating parameters on the Model 2888 radios.  With this software, a technician can quickly identify possible conditions that may eventually result in a non-responding remote radio.  The technician may then modify the current radio's parameters to correct the condition "over-the-air".  Virtually all radio maintenance no longer requires dispatching a technician to perform an on site repair, thus reducing undesirable downtime.  The software runs on a PC/AT compatible computer system (Desktop or Laptop).  When connected directly to a Model 2888 the software can read and/or modify each of the following remote parameters:  Diagnostic Parameters:    Alarm Status RSSI RF Power Output Mode PLL1 Voltage PLL2 Voltage Power Supply Voltage FM Deviation Frequency Offset Internal Temperature Forward Power Reverse Power    Alarm Limits and Conditions (Low/High):   Power Supply Voltage PLL1 Voltage PLL2 Voltage Forward Power Reverse Power Internal Temperature Squelch Counter PTT Counter Tx Timeout Counter  Operating Parameters:     PTT Dekey Time PTT Limit per 10 seconds Timeout Duration     RTS/CTS Delay Tx On Delay (repeater use)    Communication Parameters:     Transmitter Frequency Receiver Frequency Radio Address Tx/Rx Spacing Bandwidth    6.0 Alligator Diagnostic Software
 30  Frequency Adjustment Schemes:    Tx AFC Rx AFC Mechanical Frequency Pot Automatic Global Frequency Calibration (AGFC)  Digital Frequency Pot  Event Counters:    Squelch PTT Time-out  Sleep Mode Parameters:    Clock Time Sleep Enable/Disable Wake-Up Time Sleep Time Wake Duration Snooze Duration Maintenance Enable Start Time End Time   When connected to a Model 1800A master station, the Alligator Advanced Diagnostics Software (ALLI) can read and/or modify all of the previously listed parameters for each responding Model 2888 Radio.  It can also switch the master transmitter, and perform a master station battery test.  In addition, the software can read the following parameters from the Model 1800A:   Master Station Diagnostic Parameters (A and B)     RF Power Output Supply Current Power Supply Voltage Front Panel Status FM Deviation  Frequency Offset  Received Signal Strength and Offset (A and B):   RSSI (dBm) Frequency Offset    Alarm Conditions:   Module Unlock TxA Power too low TxB Power too low Primary TCXO failure Power Supply A off-line Power Supply B off-line  Communication Parameters:   TxA Frequency TxB Frequency  Radio Address RxA Frequency RxB Frequency Setup Configuration  Operating Parameters:       Repeater Operation Enable Hot-Warm-Standby Timeout Timer
 31  Automatic Tx A/B Cycling Parameters:    Time of Day Switchover Countdown Switchover Interval Tx A/B Cycling Enable Time to Switch    Dial-Up Auto Answer Parameter Settings:    Auto Answer Enable Number of Rings    Frequency and Deviation Adjustments (from any remote location)    Digital Frequency Pot Digital Deviation Pot    Transmitter Forward Power Reading Corrections    TxA Correction Factor TxB Correction Factor     For a complete description of the software installation and operation refer to the Alligator Advanced Diagnostics Software Manual.   6.2   Diagnostics Feature Theory of Operation  The ALLI software uses a multi-address polling communications scheme to communicate with the microprocessor of each remote radio responding to the connected master station.  Each time the software updates information to or from a remote or master, it must send a command string requesting the appropriate action from the specified radio.  The software then waits for a response.  If the remote or master does not exist or is not responding then the software will report a time-out error.  The software communicates with the radios using the DTMF protocol.  It is the same protocol researched and implemented by the U.S. telephone and emergency broadcast systems for more than two decades.  This protocol isolates the diagnostic capabilities of the radio system from the connected SCADA equipment.  In other words the radio system's diagnostic transmissions will not trip the connected SCADA equipment and the connected SCADA equipment's data transmissions will not trip the radios' diagnostics.  However, this protocol was not designed to quickly transmit large quantities of data.  Therefore, a few of the software commands that require large amounts of data will respond slowly.  This trade off of speed for data isolation has only a minimal effect on overall system performance.  The few extra seconds spent reliably performing over-the-air calibrations is much more desirable than the few extra hours spent visiting a remote site.  By default, Alligator programs the Model 2888 to prevent the ALLI software from interrupting any SCADA transmission.  Also by default, any SCADA transmission will interrupt the software's attempt to communicate with any remote.  However, upon a customer request, the factory can program the master to operate in the reverse.

Navigation menu