Larcan MX1000U 1000 Watt UHF Translator User Manual mx1ku
Larcan Inc 1000 Watt UHF Translator mx1ku
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Publication TSM 20-319 TECHNICAL MANUAL 1KW UHF INTERNALLY D IPLEXED TV TRANSMITTER MX1000U SERIES LARCAN INC. 228 AMBASSADOR DRIVE MISSISSAUGA, ONTARIO CANADA L5T 2J2 PHONE: FAX: (905) 564-9222 (905) 564-9244 Rev 1: March 2003 INTRODUCTION This manual describes the LARCAN model MX1000U, internally diplexed UHF television transmitter. LARCAN all-solid-state 1 kW UHF transmitters are designed to operate conservatively at 1 kW peak sync visual/vision RF power and 100W average aural/sound single carrier RF power, with superb performance, reliability and operating economy. The MX1000U transmitter accepts an on-channel internally diplexed (in a 10:1 ratio vis to aur/snd) composite driving signal of 10 mW peak visual RF, as input to its RF chain. The 1 kW transmitter is self-contained within a single 19" cabinet with an integral cooling fan and filtered rear door air intake. The simplicity of design, the employment of modular subassemblies, and the use of standard readily available components, also enhances serviceability. Important transmitter parameters are monitored, and can be displayed on the meters built into the transmitter control panel. Additionally, telemetry readings are made available as DC signals for monitoring by remote control systems. The MX1000U, like all other LARCAN transmitting equipment, is suitable for unattended remote-control operation. AMPLIFIER CHAIN (R EFER TO FIGURE 1) The Aural signal of the transmitter is diplexed (at IF) with the visual/vision signal within the exciter (hence the term "internally diplexed), and is amplified in common with the visual signal in the above amplifier chain (hence the term common amplification). The internally diplexed composite RF output of the exciter/translator is fed to a 4-way active splitter. The 4 outputs of the splitter are fed to conservatively designed broadband solid-state amplifiers. The outputs from the four PA modules are combined for the total transmitter output power. These amplifiers require no tuning or adjustment. Phasing for the four PA modules is done at the splitter level. Internal cable lengths and precise production tolerances allow for a very small adjustment range for phasing. Simplicity of operation, reduced maintenance costs and increased reliability are a few of the major benefits derived from this modular amplifier design. The modules are operated well below their maximum ratings. Each RF power amplifier (PA module) is fully modular within itself and each module has a gain equivalent to the entire gain of the transmitter (see Figure 2). Each PA module has it's own preamplifier, Intermediate PA, Driver and PA section. The front end preamplifier on the PA module monitors and provides soft startup, overdrive and VSWR protection for the module itself (independent of the transmitter protection). The output stage of the module consists of three amplifier "pallets" each consisting of two push-pull LDMOS FET amplifiers that operate in class AB, and are combined in quadrature. The outputs of these pallets are further combined in a 3way combiner. The amplifier module is rated for 350 watts, and in the present four PA module system is operated at a total transmitter power of 1 kW sync peak + 100 watts aural/sound. The module is provided with a test jack for monitoring. The amplifier output is fed to the bandpass filter and a directional coupler, which provides a small sample of forward and reflected output power for metering, AGC and VSWR supervisory functions. An additional sample is available for monitoring and transmitter setup. The transmitter output then passes to the antenna system. TRANSMITTER CONTROL The control circuitry in this solid state transmitter is straightforward and simple. The use of latching type relays ensures that the transmitter state (on/off, or trip status) is “remembered” under power failure conditions. Interlocking is provided for loss of airflow and for over temperature conditions. An additional interlock connection point is provided for interlocking the transmitter to an external patch panel. Facilities are provided on the control board for telemetry, status, and control connections to and from a remote control system. These are available on 25 pin D-sub connector. For remote control operation, simply press the REMOTE switch (LED illuminated). This places +12V on Remote Enable line and allows the transmitter to be turned on and off via remote control. In this mode the transmitter cannot be turned on locally but for safety purposes, the transmitter can always be turned off locally while in REMOTE. The Remote Enable +12V appears as an arming signal at J5-5. A momentary connection of this +12V to J5-13 turns the transmitter ON, and momentary connection of the +12V to J5-8; turns the transmitter OFF. Control circuit power for the transmitter is supplied by two redundant power supplies wired in parallel. The failure of either power supply will not affect the operation of the transmitter. The transmitter's power supply consists of two ferro-resonant transformers each with dual secondary windings. Each transformer secondary feeds a rectifier/filter and linear regulator combination. The regulator modules are located inside the rear door of the transmitter and can be removed for servicing by first disconnecting the two cables and then unplugging the module. This can be done without turning off the transmitter. A two pole fused disconnect or breaker is required for transmitter connection from line-to-line. The transmitter is wired per Figure 5. • Press the OFF button on the control panel. Pull out the regulators so they are no longer mating with their respective AC power connectors. Turn on the power supply breakers. Press the ON button. Looking into the back of the transmitter DS6 and DS7 on the AC distribution board should be illuminated (refer to figure 3). If the blower comes on and DS6 and DS7do not, then the AC Distribution board needs to be bench tested. • Press the OFF button again. Install the regulators but disconnect the cables that mate at the top of each regulator (connecting the regulators to the PAs). Turn on the transmitter. Measure the voltage on the output connectors of the regulators. The voltage should be 28V (±0.5V) for each regulator. Note: Since the regulators have no load, when the transmitter is subsequently turned off it will take a while for the voltage to decay down to zero. • Turn off the transmitter. Reconnect the cables to the regulators. Turn the RF drive level down as far as it will go at the appropriate OUTPUT LEVEL/RF OUTPUT adjustment on the exciter. Alternatively, disconnect the drive from the output of the exciter. Turn on the transmitter. Using a clamp-on current meter, measure the current going from the regulators to the PA's. Measure the current going through the +28V supply cables and not the return cables (some of the ground current may return through the transmitter chassis as opposed to the return wires, causing the current reading to be lower than it actually is). The 28V supply cables are the two lower wires in the cable assembly (Figure 4). These are accessible by pushing back the protective covering on the cable. The front panel current meter (the digital LCD meter) can now be calibrated for each PA module. (Remember that the modules are numbered 1-4 from left to right across the front of the transmitter. This will be reversed when looking into the rear of the cabinet.) The corresponding adjustment pot on the control panel (PC board 20C2065G1) is listed below. PA1 Pot R221 PA2 Pot R225 PA3 Pot R229 PA4 Pot R223 These adjustments can be accessed by opening the hinged control panel on the front of the transmitter. • Disable the AGC using the front panel AGC Enable switch. Note: the AGC is disabled when the LED on the enable switch is off. Increase the output power from the exciter until 100% • • • • • • • • • operating power in achieved. Use a thru-line type Wattmeter to measure the transmitter power. Select FWD on the analog meter select switch and adjust R164 on the control board until the forward power meter (analog meter) reads 100%. To calibrate the aural power, refer to the RF detector board description and setup procedure. Calibration of the reflected power metering and the VSWR cutback and trip is detailed next. Note, this setup was done at the factory initially, and should not be adjusted unless absolutely necessary. Conditions that would warrant this adjustment include the replacement of the RF detector assembly or the control PC board. Turn R130 fully CW and R138, and R128 fully CCW The Reflected power meter reading corresponds to 10X the actual power reflected. That is, when the reflected power meter reads 100%, this means 10% of the output power is being reflected (ie: there is a VSWR of 1.9:1 at the transmitter output). (10dB match). To calibrate the meter for this level, the forward sample port that feeds the RF detector circuitry for metering is fed through a 10dB attenuator back to the reflected power input on the RF detector board. To do this, disconnect the cable at the forward port of the output directional couple and connect Reflected power sample cable through a 10dB pad to the forward power port. This simulates having a 10dB mismatch on the output of the transmitter. Note: AGC must be disabled during this procedure. Adjust R117 until a 100% reading is achieved on the RFL power setting of the analog meter. Change the attenuation from 10dB to 16db of the forward power into the reflected port on the metering board. Adjust R138 so that the power just starts to cutback slightly Adjust R130 so that the VSWR CUTBACK LED just turns on. Change the attenuation to 13dB. The cutback circuit should cut the power way back. Adjust R128 so that the transmitter trips and locks out with VSWR. Now change the attenuation to 14 dB of forward power into the reflected port on the metering board. Adjust R128 so that the transmitter does not trip and lockout with VSWR. You may have to press reset, adjust the pot, press reset, adjust the pot, etc. Then repeat the previous step to verify that the transmitter still trips with 13 dB of reflected power. Reconnect the forward and reflected sample cables to the directional coupler as they were before. Verify that the AGC buttons can raise and lower the power levels. TABLE OF CONTENTS 1. 2. INTRODUCTION .........................................................................................................................1 CIRCUIT DESCRIPTION..............................................................................................................2 Visual Forward And Combined Reflected Circuit Description ..............................................................2 Aural Forward Metering....................................................................................................................3 3. TEST AND CALIBRATION ...........................................................................................................3 Test Equipment For Board Tests On The Bench: ...............................................................................3 Test Procedure................................................................................................................................4 4. PARTS LIST................................................................................... Error! Bookmark not defined. LIST OF FIGURES Fig Title RF Detector Board (Photo) Test Equipment Setup for Bench Test Assembly Drawing 41D1607 Schematic Diagram 41D1607S 1. INTRODUCTION RF Power levels throughout the transmitter are sampled in directional couplers, and the resulting RF samples are detected and appropriately processed to provide DC outputs corresponding to the amplitude of the desired parameter of the input signal. These DC outputs contribute to the AGC/VSWR supervision of the transmitter as well as the front panel metering. The 41D1607G1 and 41D1607G3 dual RF detectors are designed for measuring forward visual/vision signal, forward aural/sound signal and reflected combined visual and aural signal. Group 1 is for NTSC and group 3 is for PAL. The circuitry provides DC outputs corresponding to the instantaneous visual/vision forward and reflected RF levels at the back porch (blanking level) of the modulated signal, so that the DC output remains proportionally constant regardless of the video signals to the transmitter. Two virtually identical detector circuits reside on a single board for visual forward and reflected metering. Detection sensitivity of the circuitry for reflected visual/vision power is approximately 10 dB greater than for the visual/vision forward RF detector circuit. Group 1, (for NTSC) and group 3, (for PAL) differ only in their colour subcarrier frequency, consequently in a few component values. The aural/sound metering circuit takes a sample of detected video signal from forward port and provides DC level proportional to the amplitude of the aural carrier. The sample of this DC level is used to compensate visual forward reading affected by presence of the aural carrier at the forward port. The reflected port does not have this compensation circuit so in reality reflected reading is combined visual and aural power. The 41D1607G2 and 41D1607G4 dual RF detectors are similar, but have identical detection sensitivities for each circuit. Th ey are designed for use in parallel amplifier systems. Group 2 is for NTSC and group 4 is for PAL; again, these differ only in colour subcarrier frequencies. The two ports J2 and J3 are not identical. J2 has aural metering circuit and compensation circuit for the presence of aural carrier at J2 port. J3 will measure combined visual and aural power unless special trap is used to reject aural carrier Figure 1: RF Detector Board 2. CIRCUIT DESCRIPTION Drawing references: 41D1607 sheet 1 (Figure 3), and 41D1607S sheet 1 (Figure 4). The visual/aural RF Detector board is fitted with two RF detectors, which respond to RF samples fed from RF directional couplers mounted on transmission lines in the amplifier cabinets and/or on external probe sections. The modulation envelope blanking level is measured because it remains constant, regardless of the picture content of the transmission. Measurement sampling occurs during the back porch. Both sections of the board are almost identically configured, except for the component numbering, system gains and the function names given in schematic Figure 2. Because the same discussion applies to both circuits, we will describe the first one only, but refer to the second one during the description by enclosing the relevant component numbers in parentheses ( ). VISUAL FORWARD A ND COMBINED R EFLECTED CIRCUIT D ESCRIPTION (REFER TO 41D1607S SHEET 1) The RF sample is applied to input J2 (J3) and is terminated by R2 (R34). CR1 (CR3) and Q1 (Q6) form an envelope detector. CR1 (CR3) is forward biased slightly by R1 (R33) and R3 (R35) to overcome CR1 (CR3) conduction threshold voltage, thereby improving detection linearity. Q1 (Q6) is forward biased by R3 (R35) as well, and when RF is applied, Q1(Q6) is driven in the direction of turn off during each positive -going half cycle, thus causing its emitter voltage to become more positive, and in effect forming a linear envelope detector. C50 (C51) utilizes the lead inductances of CR1 (CR3) and Q1(Q6) to form a Tee network, which provides a matching section that improves the UHF signal transfer between the devices. Q1(Q6) and CR1 (CR3) have similar temperature coefficients, and the opposing connection of the two in this back-to-back configuration, provides temperature compensation. Finally, Q1(Q6) serves as a low impedance video source to drive the colour traps FL2, FL4 and aural traps FL1, FL3 which remove the colour subcarrier burst and aural carrier from the back porch. Subsequent downstream sampling circuits monitor the blanking level, therefore require a clean back porch. The detected video signal is phase split by Q2 (Q7) to produce two 180° out of phase signals. The inverted video signal, after being buffered by Q11(Q13), is fed to input pin 11 of sync separator Ul (U8). Ul (U8), pin 7 is an open collector "mute" output, which switches off when adequate horizontal sync pulses matching the setting of R28 (R57) are present, lighting CR2 (CR4) the "sync ok" LED. If a TV sync signal is not detected, pin 7 collector goes low, and CR2 (CR4) is turned off. When sync is detected, the sync output at pin 9 delivers a positive -going composite sync pulse, which turns on Q5 (Q10) whose collector then goes low. If no sync is detected by Ul (U8), its pin 9 remains LOW, and Q5 (Q10) remains off. After the pin 9 pulse has finished, Q5 (Q10) turns off and its collector output goes high. This low-to-high transition activates blanking multivibrator U2 (U7), and an active low pulse is fed to Q3 (Q8), turning it on. Q4, C5, and U4A (Q9, C22, and U6B) form a sample-and-hold circuit that samples the signal originating from the emitter of Q2 (Q7) and which is buffered by Q12 (Q14). Sampling occurs during the back porch, and holds during the subsequent horizontal line. This DC sample is amplified in U4A (U6B). Because a "single supply" op-amp is used at U4 (U6), the output seen on TP9 (TP10) will contain a small DC offset which must be minimized because low level signals are near ground/earth potential. With no RF input, this offset voltage is adjusted by potentiometer R10 (R42) as near as possible to zero. A residual voltage offset of 10 to 20 millivolts can be expected. Outputs from unity gain op-amps U4A, U4B(U5A, U5B) drive the forward (reflected) power metering circuits, and provide telemetry and AGC (VSWR) signals. Bench test calibration consists of adjusting the level to U4A (U5A) on R13 (R43) with calibrated, properly modulated input: The forward input at J2 should be 200 mW in 50Ω, (J3 Reflected input 20 mW for both the 41Dl607G1 ,3 boards, or for 41D1607G2,4 boards the J3 Combined input 200 mW), and the voltage observed at TP1 (TP2) should read 4.0 volts DC for full scale calibration. AURAL FORWARD M ETERING A sample of the signal detected by CR1 from J2 is buffered by Ql and high-pass filtered by R90, C55 and the input impedance of Q15. R92 and R91 set the base bias for Q15 while R93 and R94 set the gain of the stage to approximately 4.7 for the 4.5 MHz (5.5 MHz) aural intercarrier signal. The wideband visual/aural signal drives FL1, an aural bandpass filter. This filter is chosen to match the broadcast standard used. C59 couples the filtered aural signal to common emitter amplifier Q17 which is direct coupled to common base amplifier Q16. The bias for these stages is set by resistors R95, R96, R97. C57 and C58 provide bypassing. Q16 is a current amplifier with L7 as the collector load and C60 provides frequency compensation. The aural signal is then fed to a peak voltage detector consisting of CR6, C63 and R102. U9A provides DC amplification of the detected signal. Amplifier gain is set by potentiometer R104 such that the DC level at TP8 is in the range of 7VDC. This provides enough "safety" range for the signal not to saturate yet enough level to reliably give a 4VDC calibration at TP3. 3. TEST AND CALIBRATION TEST EQUIPMENT FOR BOARD T ESTS ON T HE B ENCH: RF Detector test fixture, comprising a 12 volt DC power supply, suitable connectors for the board to be tested, a signal generator, a modulator, and an amplifier good for 200 milliwatts output. An exciter will suffice for the generator and modulator, but its output is good for a maximum +10 dBm (10 mW) therefore requires an external amplifier, and the exciter aural output may be used as an unmodulated source if required (A LARCAN exciter visual/vision section can not deliver unmodulated RF). TEST PROCEDURE • • For test setup, see Figure 2. 1. 2. 3. 4. 5. 6. 7. 8. TEST EQUIPMENT REQUIRED 12 V power supply UHF preamplifier (approx 200mWo/p). Video Generator. Modulator. UHFUpconverter. Oscilloscope. Spectrum Analyzer. VHF / UHF Two Way Splitter. Connect board under test to power supply. Apply • ground on pin 7 & 8 of J2 and apply +12v (± 0.2 V) to • pins 3 & 4. Do not apply RF to J2 and J3 yet. • Adjust R111 max CW. • Adjust R10 to get a min voltage at Ul0-1 (TP9). Check the voltage between U10-2 and U10-3. It • should be no more than 10 mV. • Adjust R42 to get a minimum voltage at U6-7 (TP10). Check the voltage between U6-6 and U6-5. It should be no more than 10 mV. Set R104 in mid position. Apply staircase modulated RF signal from UHF upconverter to J2 and J3 through splitter according to Table 1. The signal should include aural carrier 10 dB lower than visual sync peak. Check this level on the spectrum analyzer. Note: Make sure to set spectrum analyzer resolution RBW to 300 kHz to see sync peak level. Assembly Group G1/G3 Connector Visual Peak Signal [dBm] J2 23 G2/G4 J3 13 J2 20 J3 20 TABLE 1. 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Adjust R104 for 7.5 ± 0.5 V at TP8. Adjust R107 for 4V at TP3. Adjust R28 so that CR2 lights up. Adjust R57 so that CR4 lights up. Using the oscilloscope, check that there are positive 12V pulses at TP4 and TP5. Check DC voltage at TP9. VTP9 should be within 4.5V to 9.5V. Check DC voltage at TP10. VTP1O should be within 4.5V to 9.5V. Turn off the aural carrier. Adjust R13for4VatTP1. Turn on the aural carrier. Adjust R111 for4V at TPl. Repeat steps 12 and 13 until voltage at TP1 stays the same with and without aural carrier. Adjust R43 for 4 V at TP2 with aural carrier on. Figure 2. Test Setup For Visual + Aural RF Detector Assembly. TABLE OF CONTENTS 1. 2. INTRODUCTION .........................................................................................................................1 CIRCUIT DESCRIPTION..............................................................................................................1 Front End Preamp. ........................................................................................................................1 IPA Module ....................................................................................................................................2 Pallet ..............................................................................................................................................3 Module Interface Board. ...................................................................................................................4 3-Way Splitter .................................................................................................................................4 3-Way Combiner .............................................................................................................................4 3. TESTING AND TROUBLESHOOTING..........................................................................................4 Front -End Preamp...........................................................................................................................5 Intermediate Amplifier (IPA) ............................................................................................................5 4. PARTS LIST................................................................................... Error! Bookmark not defined. 1. INTRODUCTION The PA module for the MX1000 is a high gain linear amplifier. Each PA module includes its own preamplifier, intermediate amplifier, driver amplifier and power amplifiers. The gain of the module is equal to the gain of the entire transmitter. Every PA module has its own on-board protection against overdrive, excessive VSWR and over temperature. A single LED on the front panel indicates the status of the module. Any fault will cause this LED to turn off. Figure 1: PA Module, MX1000 2. CIRCUIT DESCRIPTION FRONT END PREAMP. The RF input to the module is via J1. U1 provides the amplification of the signal for this stage. This IC is an 18dB gain broadband hybrid amplifier. The output of this stage to the following amplifier (IPA) stage is through J2. A directional coupler HY1 provides a sample of the input power for a detector CR1, C2 through C4 and buffer amplifier U6B and associated components. A PIN attenuator circuit consisting of CR2, CR3, R8 through R13 and C5 and C6 provides the means for controlling the signal gain through the front-end stage. A higher voltage applied to this attenuator through L1 results in less attenuation through the PIN attenuator and hence, more gain through the preamp unit. A further coupler HY2 provides an output sample to a detector and buffer circuit (CR4 and U6C). The maximum gain of the front-end preamplifier is approximately 8dB, however, in practice, the gain is adjusted to compensate for gain differences in other stages such that the gain of each PA module is the same. The three-way combiner circuit for the PA module incorporates a bi-directional coupler with detectors for forward and reflected power on the module. These detected voltage samples for forward and reflected power are fed into the front-end preamp through J4-7 and 14. Comparator circuitry is used to detect either overdrive conditions or VSWR conditions. Since the circuitry is identical for both forward and reflected, a circuit description will be given for the forward power circuit only. U3D is configured as a comparator with the reference voltage being provided by the voltage divider consisting of R44, 45, 46. Note: this level is preset. Values for this voltage divider should not be modified. Doing so without prior authorization from factory service personnel will void any warranty. When the detected voltage rises above the preset level, the output of the comparator U3D goes high, and forces transistor Q1 to the "on" state through diode CR7. Other inputs to Q1 include the reflected (VSWR) signal, an external mute signal and a power-up delay circuit consisting of U5D configured as a comparator along with R47 through R50 and C20. The action of turning on Q1 causes the voltage on the PIN attenuator, preset by R25, to be shunted through the transistor, thus increasing the attenuation of the PIN attenuator. Additional circuitry on the front-end preamplifier also drives the logic for the Green LED on the front panel of the PA module. Output samples from each of the power amplifier pallets are monitored and compared with preset voltages through comparators U2C, U2D and U3C. A failure of the output of any one of these pallets will cause the output of U5A to drop and the LED (connected to J6) to be extinguished. Note: this applies if the input RF signal is removed and thus results in no output from the module (as well as in the case of an overdrive situation or VSWR cutback situation). There are buffered signals for the various stages on the PA module that are brought to the front -end preamp and routed through to the interface board on the rear of the PA module. These signals are present on the 25 pin connector (intended as an on-site troubleshooting port). In the MX 1000 application, these signals are present but most are not monitored by the transmitter's control circuitry. IPA MODULE The intermediate amplifier consists of two FET amplifiers, type MRF181 paralleled in RF phase quadrature, and operated in class A. Amplifier static bias control and over-current protection is provided by an industry-standard type µA723 regulator IC, U1. The overall gain of the Intermediate Amplifier is a nominal 15 dB over the band. Figure 2: IPA Module The input signal is split evenly by quadrature hybrid splitter HY1. Each FET gate is matched with the equivalent of an L network followed by a π network. Capacitors C100 and C110 provide DC blocking of the gate voltage. A couple of low impedance microstripline sections along with adjustable capacitor (C101 or C111) to ground and the gate capacitance of the FET form the L-C-L-C matching network for the input circuit. This matching arrangement is good for operation from 470 through 860 MHz, adjustable capacitors C101 and/or C111 provides for a flat frequency response over the range. The output circuit is similar except it uses narrower (higher impedance) microstriplines because the drain impedance of the FET is higher. The output matching network is adjustable with variable capacitor C103 or C113. Again, this capacitor is adjusted only to provide flat response over the 470 to 860 MHz range. An output coupling capacitor C104 or C114 completes the match to 50 ohms; two amplifier outputs are combined in a quadrature hybrid HY2. Bias to the gates of the FETs passes through R100 or R110 from balance controls RV100 or RV110. The bias regulator Ul uses an µA723 (MC1723CD) to provide approximately 6½ volts to the gate bias controls RV100 & RV110. Voltage divider R5, R6 provides the inverting input of the regulator error amplifier with a sample of the output voltage, and the wiper of RV3 provides the non inverting input with its reference signal which is an adjustable fraction of the 7.15 V built-in reference of the µA723. The adjustment of RV3 therefore should be able to give an output within the range from zero to approximately 9 volts. R4, C2, C1, R3, and C4 provide frequency-compensation and maintain regulator stability. Drain current of the two FETs is sampled by the voltage drop across R7. When this voltage exceeds approximately 0.5V at normal operating temperature (about 1.5 amps total FET current), Q3 begins conduction and feeds voltage to pin 2 of the regulator to start its current foldback/limiter circuit. The regulator reduces its output voltage, which in turn reduces the bias on the FETs, they decrease their drain currents, reducing the voltage drop across R7 and over-current protection is achieved. CR1 protects Q3 emitter-base junction from current inrush to C3 and C107 charging during start-up. PALLET The following description applies to the driver amplifier as well as the circuitry used in each of the three sub-modules comprising the final PA stage of the PA module. The difference being that the driver consists of a single device amplifier (called a “half-pallet”) while the final stage are based on dual FET amplifiers with an integral 3dB hybrid combiner. Referring to the schematic diagrams (figures 14 and 16) one will notice that even the component numbering is similar. The following description is for the dual FET version of the amplifier (refer to fig 16). Figure 4: Driver The stripline balun developed at LARCAN is a practical implementation of the coaxial cable based solution on a broadside-coupled horizontal stripline structure. It is made up of three printed circuit boards of high dielectric material bolted together. Using this structure, very tight coupling can be achieved, thus emulating the properties of a coaxial transmission line balun. With this arrangement, the characteristic impedance and degree of coupling can be controlled through geometric dimensions. This circuit is the subject of a patent application. The amplifier pallet (full-pallet) couplers also include hybrid 3dB couplers as part of the multi-layer stripline circuit. The resultant output of the coupler assembly is two pairs of equal and opposite phase signals 90 degrees out of phase (that is, a set of signals at 0° and 180°, and a set of signals at 90° and 270°). Transistors Q1 and Q2 are Lateral N-Channel Broadband Push-Pull Power MOSFETs. One side of the amplifier is described. Components C6 through C11 and C52 along with the associated printed circuit traces form the matching network to the gate of the push pull transistor Q1. L2 and R2 along with L3 and R3 are low frequency parasitic arrestors. Similarly, C14 through C15 and C53 along with associated stripline traces provide output matching on the drain of the device. C6, C8, C16 and C18 also provide DC blocking of the supply and bias voltage. C7 is factory adjusted for a flat frequency response from 470 to 860 MHz. DC power enters the module through a screw terminal connection and is fed to the main circuit board through a series of jumpers. 28V is fed to the drains of the FETs via L5 and L6 with bypass capacitors C13, C25, C20, C22 and C28. Bias for the devices is via L1/L4 with bypass capacitors C1, C2, C5 and C12. The bias voltage is adjusted via R12 and R11, from a regulated source provided by Ul. R12 sets the overall bias and R11 provides adjustment for balance between Q1 and Q2. Thermistors R21 and R22 provide thermal stability for the bias. MODULE I NTERFACE BOARD. This PC board is located on the rear of each PA module. The RF input and DC input to the module enters via this interface board. Four fuses are located on this board. Three fuses are in line with the 3 output PA pallets and one with the front end, IPA and driver modules. These fuses serve to protect the circuitry from damage in the event of a device failing in the short circuit condition. This is part of the “soft failure" mechanism of the PA modules. Because the normal failure mode of a transistor is a short circuit, and we desire to keep the rest of the PA module functioning in the event of a failure, the fuse effectively disconnects the failed circuit from the regulator, allowing it to supply the rest of the module. The interface board performs a number of other signal routing functions. Various signals from the different stages of the module are routed through this board to connectors. In the case of the MX1000, many of these signals are not routed any further, but are present on the connector (J3). 3-W AY SPLITTER The three-way splitter is a stripline implementations of a 1.76dB hybrid/3 dB hybrid combination. It is a mechanical structure consisting of 3 PC boards sandwiched together to form the stripline structure. The middle layer board thickness along with the trace locations determine to the largest extent the coupling. J4 feeds a 1.76dB splitter. The input power to this splitter is divided 1/3 – 2/3 between the two outputs. The 1/3 output is fed to J3 and the 2/3 output is fed to a further 3dB hybrid coupler. The two outputs of this coupler are fed to J1 and J2. The termination load for the reject port of the 1.76dB splitter is at the far end of the board from J4 and the termination load for the 3dB coupler is located at the edge of the board between J2 and J3. J5 is connected to a directional coupler on the input to the splitter and is not used in this configuration. 3-W AY COMBINER The three-way combiner is essentially the mirror of the 3-way splitter. J1 and J2 are coupled to the inputs of a 3 dB hybrid coupler. The output of this combiner is fed to the input of a 4.77dB hybrid coupler along with the input from J3. The output of this coupler appears at J4. R6 serves as the balance load for the 3dB coupler while R7 serves as the balance load for the 4.77 dB coupler. Each of the inputs to this combiner have a directional coupler and detector circuit that feeds a DC sample of the output of each pallet to the sensing circuitry on the front-end module. As well, a directional coupler on the output of the combiner has detectors for both the forward and reflected power samples of the output. All the information fed back to the front-end appears at J11. Additionally, a second directional coupler provides an RF sample that is fed to a front panel test point via J5. 3. TESTING AND TROUBLESHOOTING Basic troubleshooting of a PA module is as follows. The front panel LED is extinguished if one or more output amplifier pallet levels are lower than nominal preset level. As mentioned earlier, if the drive is removed from the module(s), the output of the amplifiers also satisfy this condition and thus the LED will be off. In this case, there is nothing wrong with the amplifier. Therefore, if all the LEDs are off, the first place to look is at the output of the exciter. If a fault condition exists (LED off) on a single module, the first place to check is the PA module interconnect board where all the fuses are installed. A blown fuse will most often indicate a defective amplifier pallet. Most times, this will be the problem and replacing the defective amplifier and fuse will rectify the problem. If, however, there are no blown fuses, there are other areas to check. Figure 6: Fuses The front panel current meter will give an indication of the current drawn by the modules in comparison to one another both under drive conditions and under static bias conditions. Check the current under drive conditions for overdrive situations and under static bias conditions (no drive) for amplifier stage failure. Check for potential connector problems causing either no drive to a module (input connector) or VSWR (output connector) problems. Also, if you suspect an over temperature condition, be extremely careful when pulling out a module as the heatsink may be too hot to hold onto comfortably. The following procedures are essentially the same procedures used during factory testing. Basically, if there is no suspected problem with a particular stage, we would recommend not performing these procedures. • • • • • • • • • • • • • • FRONT -END P REAMP Short Pin J4-10 to ground (this can be accomplished by placing a small jumper across J4-10 and J48). This simulates a good thermal switch. Connect a +28V power supply to E1 and ground. Apply a 0dBm (1mW) RF input to the amplifier. Turn R25 fully clockwise. The preamp should have minimum gain (approx. 7dB). Adjusting R25 from one extreme to the other should vary the gain 4dB. Check RF output telemetry. There should be 1.5V ±0.5V at J3-12. Check the RF input telemetry. There should be 1.0 ±0.2 V at J3-13. Check the RF attenuator voltage telemetry. There should be 5.4V ±0.2V at J3-1 Check Thermal switch status indication. J3-4 should be 0V. Remove the jumper from J4-10 to J4-8. (This simulates the thermal switch opening). The voltage at J3-4 should be high (4 Volts ±0.5V) and J3-1 should be 0V. Replace the jumper across J4-10 and J4-8. RF Mute check: Connect a variable supply, to J3-2. Gradually increase the voltage until the gain drops by 30dB or more. The applied voltage should be approximately 2.5 volts. Reflected Power Cutback check: Connect the variable supply to J4-9. Increase the voltage gradually until the gain drops by 30dB or more. The voltage should be approximately 4.0Volts ±0.2V. This same voltage should also be present at J3-14. J3-6 should be 4.0 volts. Overdrive Cutback check: Connect the variable supply to J3-7. Increase the voltage until the gain drops by 30dB or more. The voltage should be 7 volts ±0.5V. The voltage at J3-11 should be the same and the voltage at J3-7 should be 4.0 volts. Set the adjustable supply to 2 volts. Connect this voltage to J4-1, J4-3 and J4-5 simultaneously. J26 and J3-5 should be high. Disconnecting any one or more of J4-1,3 or 5 should cause both J2-6 and J3-5 to go low (0V). INTERMEDIATE AMPLIFIER (IPA) B ENCH T EST PROCEDURE: This amplifier must be mounted on a properly sized heatsink for testing. • Connect a suitable load to the output of the IPA. • On the IPA under test, set RV200 fully clockwise and set RV110 fully counter-clockwise. • Set variable power supply to 28.0 volts and set its current limit to 1 ampere. • Apply the +28V to the feedthrough capacitor of the IPA shield box. • Adjust RV3 to achieve 6.5 ±0.2 volts at the junction of R5 and RV100. • Adjust RV200 to achieve total current draw of 500 ±20 mA. • Check that the junction of R100 and CR100 measures between 3.5 and 5.5 volts. • Adjust RV110 to raise total current draw to 1000 ±50 mA. • Check that the junction of R110 and CR110 measures between 3.5 and 5.5 volts. • Increase the power supply current limiting to 2.2 Amps. • • • • • Increase RV3 clockwise slowly and check that the maximum current limits itself at 1.6 ±0.1 Amp but do not allow current to go above 2 amps while performing this test. Reset RV3 to achieve 6.5 ±0.2 volts measured at the junction of R5 and RV100. Check balance of the two transistors with a voltmeter connected between the hot sides of C105 and C115; difference voltage should be less than 3 mV. Apply RF drive (max. +18dBm to IPA) and adjust C101, C103, C111, and C113 for minimum frequency response ripple and flat response. Gain should be a minimum of 15 dB with maximum variation less than 0.5 dB over the frequency range 470 MHz through 860 MHz (Note: IPA output will then be about +33dBm or 2 Watts, so make sure you properly protect your test equipment). If roll off at the higher frequencies prevents meeting this gain-bandwidth specification, it may be necessary to replace either C103 or C113 or both with a higher value; use variable capacitor made by Johanson, part # 16E2320-2, which is 2.5 to 10pF. TABLE OF CONTENTS 1. 2. 3. 4. INTRODUCTION .............................................................................................................1 BLOWER REPLACEMENT ..............................................................................................1 COMBINER AND REJECT LOAD .....................................................................................1 THERMAL SWITCH AND AIR SWITCH ............................................................................2 Thermal Switch ...................................................................................................................2 Air Switch............................................................................................................................2 5. PARTS LIST....................................................................... Error! Bookmark not defined. LIST OF FIGURES Fig. Description 1. Roof of Transmitter 2. Access to Blower 3. Thermal Switch/Air Switch Location 1. INTRODUCTION The following description, while described as the module housing for the transmitter, in essence, comprises the additional assemblies and circuits that are not included in the other assemblies described in this manual. They include such assemblies as the Blower, the 4-way combiner and reject load assemblies for the overall output, the various interface circuitry and the protection circuitry. The “housing” is basically the assembly that brings all these items together. 2. BLOWER REPLACEMENT The Blower is located on the top of the module housing. It is accessible through the top of the transmitter. The blower is a backward curved motorized impeller. The motors have no adjustments and need no maintenance. The blower motor bearing life should be on the order of 100,000 hours. Should the blower fail for any reason, the replacement is relatively simple. The entire blower and motor assembly can be removed through the top of the cabinet. Figure 1: Roof of Transmitter 3. Figure 2: Access to Blower COMBINER AND REJECT LOAD The 4-way combiner used in the transmitter is basically a combination of three 3dB hybrid couplers. Two couplers form the first level of combining and a third combines the outputs of the first two for the final output. These combiners require balancing loads, or reject loads. The loads are located in the module housing on an assembly similar to the module assembly. The Reject load assembly is within the cooling air plenum and comprises all three reject loads for the combiners. This reject load assembly is not removable when the transmitter is under power and as such incorporates SMA connectors and is held in place additionally by screws through the rear of the module housing. A sample of the input to each of the loads is provided on the front panel of the reject load assembly. These samples can be used for setting up of the 4-way splitter. Phase and gain of each power amplifier signal path can be adjusted to minimize the power in these reject loads. 4. THERMAL SWITCH AND AIR SWITCH THERMAL SWITCH The thermal switch is located on the air duct between the module housing and the blower. It can be accessed by opening up the control panel. The thermal switch, through its mounting on the air duct essentially monitors the outgoing air temperature of the module housing. The metal in the duct itself serves to ‘average’ the temperature in the duct. It is connected to the TEMP interlock circuitry in the control electronics. Figure 3: Thermal Switch/Air Switch Location AIR SWITCH The Airflow switch consists of a power resistor mounted back to back with a thermal switch. The air that flows through the transmitter flows across this assembly, cooling the resistor. If the airflow is compromised, the resistor is not cooled properly and thus heats up. At a certain temperature, the thermal switch will open, shutting off the power supplies and thus protecting them from damage. The thermal switch mounted on the resistor should not be confused with the transmitter thermal protection. The air switch is designed to detect the presence of air flow throughout the normal operating temperature range of the transmitter and in fact operates, under normal conditions at a much higher temperature than the maximum operating temperature of the transmitter itself. The sole purpose is to detect the presence of air flow, and in the case of reduced, or no air flow, the resistor/thermal switch combination overheats and shuts off the supplies. WARNING: AC VOLTAGE IS PRESENT ON THE AIR SWITCH RESISTOR. DO NOT REMOVE THIS ASSEMBLY WITHOUT FIRST DISCONNECTING AC FROM THE TRANSMITTER. TABLE OF CONTENTS 1. 2. INTRODUCTION .............................................................................................................................1 CIRCUIT DESCRIPTION..................................................................................................................1 TEST AND TROUBLESHOOTING....................................................................................................1 General...............................................................................................................................................1 Troubleshooting ..................................................................................................................................2 Splitter Setup ......................................................................................................................................2 4. PARTS LIST....................................................................................... Error! Bookmark not defined. 1. INTRODUCTION The 4-way splitter provides four evenly balanced, equal amplitude, properly phased signals to each of the PA modules in the transmitter. The intention is to provide the ability to fine match the phasing and gain of the amplifiers such that they combine with the minimum of reject power. It has been found that normal production tolerances do not cause wide variations in phasing between amplifiers and thus the control over the output phase is limited to a relatively narrow range. At different channels, some touch-up of phasing might be desireable in order to finely balance the PAs, although, it is not absolutely necessary. 2. CIRCUIT DESCRIPTION The RF enters this splitter via J5 and is applied to a PIN attenuator circuit comprised of CR1 and CR2 and associated circuitry. The attenuator voltage to this circuit is applied through L1 via buffer amplifier/ inverter Q1. A higher voltage at E2 results in more attenuation through the PIN attenuator. E2 is fed from the transmitters AGC/VSWR circuitry. The signal at the output of the PIN attenuator is fed to a hybrid 3dB coupler HY1. The two outputs from HY1 are fed to two more hybrids HY2 and HY3. The result is four outputs, equal in amplitude but differing in phase. Each of the four signals is then passed through a phasing network and a further PIN attenuator for the purpose of balancing the transmitter phase and gain overall. All four balancing circuits are identical therefore only the circuit that supplies PA1 will be described. The phasing adjustment is accomplished by using two varactor diodes CR100 and CR101, connected to the output ports of a 3dB hybrid coupler HY4. If the impedance of these pure reactances is kept equal, the signal is reflected back through to the isolation port of the hybrid with a change in phase and minimal loss. The reverse bias on the varactor diodes is controlled through R101 and R102/R103. Attenuation adjustment is controlled by varying the bias across CR102 via R108 through R111. This has the effect of shunting some signal to ground. R110 controls the coarse level adjustment and R109 controls the fine adjustment. U1 is a signal buffer amplifier. The signal is then passed through a final coupler which provides a sample to a detector circuit and to the output connector J1. TEST AND TROUBLESHOOTING GENERAL Because the splitter, in its normal operation provides the phasing and balance for the modules in the transmitter, often times, if the balance between modules is incorrect, the splitter is the first suspected problem area. One must be very careful troubleshooting under these conditions. What may be suspected as a gain or phase imbalance can simply be a problem with a PA module. In addition, in the field it may be difficult to quantify phase relationships between signals without a network analyzer. As mentioned elsewhere in this manual, the transmitter has been delivered to site in a fully functioning condition. As designed, the phasing controls in the splitter circuitry will allow up to approximately 30 degrees of phase shift. The bulk of the phase relationship between the signal is developed within the hybrid splitters themselves. Additionally, the gain controls on the splitter is only for fine matching of the module outputs. TROUBLESHOOTING If trouble is suspected with the splitter unit itself, the following checks may be done to pinpoint the cause of failure. • • • • • Turn off the transmitter With +12V connected to E1, verify that there is +8V (±0.1V) at pin 3 of VR1. Disconnect the AGC signal to E2. With signal applied at the input use a spectrum analyzer, to verify that there is signal at each of the four output ports. Note; if one of the output ports is significantly lower (10dB) than the rest, this may indicate a problem in that particular circuitry. With a variable supply connected to E2, verify that the output levels of each port drop at least 30dB with a voltage of 3.0 Volts. SPLITTER SETUP Fine balancing of the splitter outputs is accomplished with the transmitter operating at full power. Refer to Figure 1 below. Firstly, the phasing and gain balance must be done between the inner level of combining, that is between PA1 and PA2 and between PA3 and PA4. Then, carefully, the phasing must be done between the PA1/PA2 combination and the PA3/PA4 combination. The simplest way to balance the phase and gains is to monitor the reject load power. On the front of the reject load assembly, there are various sample ports for such purpose. The relative phasing and gain is adjusted to minimize the signal level at these ports. • • • • • • • • Balance all four PA output levels. This is best done with a spectrum analyzer connected to each sample port in turn and adjusting R110, R210, R310 and R410 to adjust the level of its respective PA module output. With the transmitter operating at full power, connect a spectrum analyzer to reject load sample port for PA1/PA2. See figure 3. Adjust either R101 or R201 (one or the other, not both) to minimize the measured signal at this sample port. Connect the spectrum analyzer to reject load sample port for PA3/PA4. Adjust either R301 or R401 (one or the other, not both) to minimize the measured signal at this sample port. Connect the spectrum analyzer to the transmitter overall reject load sample port. Carefully adjust phase adjustment pots R101 AND R201 together to minimize the measured signal at this sample port (alternately R301/R401 pair can be adjusted instead). Repeat the above steps to further reduce reject levels. Note: do not use the gain adjustments to attempt to minimize reject load power. * R97 R98 C37 R95 R96 C36 R93 R94 C35 R91 R92 C34 R89 R90 C33 R87 R88 C32 R85 R86 C31 R83 R84 C30 R81 R82 C29 R79 R80 C28 R77 R78 C27 R75 R76 C26 R73 R74 C25 Rx Ry Cx FIGURE 1 PWR U2 - U6 11 TABLE OF CONTENTS 1. INTRODUCTION .............................................................................................................1 MX1000 Power supply. ........................................................................................................1 Linear Regulator..................................................................................................................1 2. CIRCUIT DESCRIPTION..................................................................................................2 Rectification ........................................................................................................................2 Regulation Circuitry .............................................................................................................2 Control Circuitry ..................................................................................................................2 3. TESTING AND TROUBLESHOOTING..............................................................................5 4. PARTS LISTS ..................................................................... Error! Bookmark not defined. 1. INTRODUCTION MX1000 POWER SUPPLY The MX1000 power supply consists of two transformers, each with dual (isolated) secondary windings. Each power amplifier module is fed from a 60A linear voltage regulator. The output voltage of each regulator is 28 Vdc. The input of the regulator assembly fed from the secondary of the ferro-resonant transformer secondary winding is 35 Vac. The AC power to the transformers is supplied via a contactor on the AC distribution board. This contactor is controlled through the transmitter’s control board, ensuring that all interlock and overload conditions are observed. LINEAR R EGULATOR The 60A linear voltage regulator is a ‘generic’ term for the entire plug-in assembly that performs more than simply a regulation function. In essence, the Linear regulator assembly is an independent power supply (less the transformer), performing rectification, regulation and self protection. Assembly is accessible through the rear of the transmitter and can be removed from service without turning off the transmitter. (For the purposes of description in this text, the ‘front’ of the linear regulator will be designated as the end with the handle, which is in actuality, located at the rear of the transmitter). Obviously, removing a regulator will disable the associated power amplifier and result in a lower output power. The AC input to the regulator is fed through the rear of the regulator and the control, status and telemetry connections as well as the DC output fed to the PA is located at the front of the module. Figure 1: Linear Regulator Assy. 2. CIRCUIT DESCRIPTION The linear regulator assembly incorporates the following circuitry: • A semiconductor-controlled rectifier bridge, the input filter capacitor and power resistors (Q1, C1 and R63, R64 respectively). This circuitry is shown in block A on the schematic diagram. • The Voltage Regulator itself (block B). • The control circuitry (block C,D,E,F,G )which provides a few different functions including over-current protection, over-voltage protection and power-on and reset functions. R ECTIFICATION Refer to block ‘A’ on the schematic diagram 40D1680S. Rectification of the AC from the transformer secondary winding is performed by a semiconductorcontrolled bridge (SCR) rectifier, Q1. Capacitor C1 performs the filtering function. The advantage of using a semi-controlled rectifier bridge instead of a conventional rectifier bridge is significant. In normal operating conditions the bridge is constantly on because the opto-coupled triacs, U33 and U34 are active. Thus Q1 behaves as a conventional rectifier bridge. In the case of serious damage to the regulator unit the control can isolate the transformer secondary from the rest of the transmitter by turning off the bridge (turning on U32). The power resistors R63, R64 are bleeder resistors, to safely discharge filter capacitor C1, when the unit is pulled out of the transmitter. R EGULATION CIRCUITRY Refer to block ‘B’ on Schematic Diagram 40D1680S. The voltage regulator circuitry consists of a low current linear voltage regulator, U1 utilizing an external high power pass transistor, giving the regulator the required current capability for this application. The combination of pnp transistor Q3 and npn power transistor Q2, creates the equivalent of a high power npn pass transistor. OR gate U25d activates, as required by the various overload commands from the control circuitry, The output of this gate is applied to the internal shut down circuitry of U1-2. The command for over-voltage shutdown is applied through U25d-12 and the command for over-current is applied through U25d-13. The output voltage setting for this regulator is provided by R18, R19 and R20. Additional regulator output filtering is provided by C8 through C12 CONTROL CIRCUITRY Control Circuit Operation a. Over-current. Whenever an over-current or short-circuit condition occurs the control circuit will shut down the output of the regulator, wait for 3 seconds and try to restart. A fault is indicated by two LEDs lighting up, a red LED (previous trip) which latches on showing that a trip has been recorded and counted and a yellow LED (over-current) which is on for the 3 second shutdown duration only. After three trips a red LED (lockout) will come on until a reset command is received, resetting all counters and restarting the cycle. b. Over-voltage The operation of the overvoltage protection circuitry is much the same Figure 2: Front Panel Indicators as that of the overcurrent circuitry with a couple of exceptions. One of the common causes of failure in a series linear regulator is the short circuit of the series pass transistor. Once the pass transistor has shorted, there is no way to shut down the regulator output (to prevent over-voltage damage to the power amplifiers), hence the SCR bridge that effectively disconnects the entire regulator from the transformer secondary. When the over-voltage protection circuitry detects an over-voltage condition the circuit shuts down the output of the regulator for 3 seconds and then tries to restart the regulator. The fault is shown by two LEDs lighting up, the red LED (previous trip) which latches on showing that a trip has been recorded and counted and a yellow LED (over-voltage) which is on for the 3 second shutdown duration only. After three trips a red LED (lockout) will come on until a reset command is received, resetting all counters and restarting the cycle. In the event that the series pass transistor short circuits, turning off the regulator IC will have no effect. In this case, additional control circuitry will shut down the rectifier bridge isolating the regulator. A red LED (Q2 short-circuit) comes on. A local reset switch for this circuitry is available for restarting the regulator (if the pass transistor is indeed short circuited the circuitry will again shut down the regulator showing the same fault condition). In this case the regulator must be serviced and Q2 replaced. Until the necessary steps are taken to do this, the damaged regulator is safely isolated from the rest of the transmitter. c. Power ON Reset and Master Reset The regulator assembly utilizes control voltages supplied by the transmitter control power supplies. These are supplied via a connector on the front of the regulator module. In the event that these ‘auxiliary’ voltages are removed from the circuit the regulator control circuit shuts down the rectifier bridge, isolating the regulator. This situation could occur if either the auxiliary power supply fails or if the 15 pin control connector is disconnected leaving the unit without the auxiliary voltages. When the voltages are reapplied, the circuitry sends a power-on reset pulse, setting all counters and protection circuits back to original conditions. The same effect occurs when the master reset switch is pressed and released. Over-current protection (refer to block C on schematic diagram 41D1680S) Along with current transducer S1, block C on the schematic contains the over-current protection. The current information from S1 is amplified and compared to a threshold determined by the setting of R51. When the current information reaches the threshold level, the output of comparator U6 goes high (0 to 10V). U3 is a buffer amplifier that is used to distribute Pin (U3) Output function the over-current status to various other pin 10 front panel status LED (overcircuits within the regulator (see table) current ) and via inverter U20d to over-current event counter U14a. Whenever an over-current event happens, pin 2 activates the OR gate U25d the comparator output toggles (U6-6) and shuting down the regulator. the positive level through U3 (pin 6) is pin 4 starts the timing circuitry (see transferred through the closed contacts of block E ). K1 to the gate of Q7. Q7 turns on and R35, pin 6 activates the locking circuitry. R41 and R43 form a voltage divider latching U6 into the ‘tripped’ state. When a reset command is issued relay K1 is activated, the gate of Q7 discharged and the circuit comes back to its original state. Over-Voltage Protection (refer to Block D on Schematic diagram 41D1680S) Over-voltage condition is sensed by U4. This is a programmable voltage sensor. The threshold over-voltage reference is set by the voltage divider consisting of R5, R21 and R22 (the threshold is set by the following formula: V= 2.6 [1+ (R5+R21)/ R22] ). An over-voltage condition causes the output of U8 (pin8) to go high. This triggers flip-flop U10a. Once set, the flip-flop output (pin 6) stays high until a reset pulse clears the flip-flop. The output of the flip-flop activates a yellow LED (over-voltage indicator CR5), the over-voltage counter, U14b, the ‘trip recorded’ circuit of U29b and the regulator shutdown circuitry of U25d. The over-voltage circuitry is reset by U12 as follows: Once the over-voltage disappears, the output of U4 returns to zero, pin 5 of AND gate U2b becomes logic 1. The signal at pin 4 of this gate is connected to the output of U10a (already set to logic 1). After a delay determined by the timing circuitry (see block E ), pin 3 of U2b goes high triggering U12 and resetting U10a. The regulator will restart. If the fault is still present the over-voltage trip will re-occur and event counters will allow three overloads before the lock out circuitry shuts the regulator down. In the event that the regulator is unable to shut down the output due to pass transistor short circuit, the over-voltage shutdown circuitry will shut down the regulator but it will have no effect on the output voltage. The output of U4 cannot return to zero in this case and pin 13 of U2a is high (via inverter U20e) instead of pin 5 of U2b. After the timing circuitry delay, pin 1 of AND gate U2a is set high, thus causing its output to go high. The output of flip-flop U10b is set and stays high until reset via S2 ( Q2 FAIL RESET ). The output of U10b (pin 10) activates solid state relay U32 . This removes drive from U33 and U34, turning OFF the bridge. The regulator circuitry is now fully isolated from the secondary of the transformer and the rest of the transmitter. Timing and Counting Circuitry (refer to Block E on Schematic diagram 41D1680S) When overloads occur OR gate U25C triggers timer IC U26. This OR gate is triggered on pin 10 in the case of over-voltage trips and on pin 9 in the case of over-current trips. Once triggered the timer releases a train of pulses to counter U28b. AND gates U30a, U30b and U31a monitor the outputs of the counter and when all outputs are high U31a triggers the internal reset circuitry to restart the regulator. If the overload event was an over-current, U31d enables timer IC U16 (see block G). This IC issues a pulse activating Q4, opto-coupler U15 and relay K1. The relay discharges the gate of MOSFET Q7, releasing the over-current protection. Since relays are inherently slow devices, opto-coupler U15 holds the shutdown pin of the regulator U1 high during the reset period. This prevents serious over-current conditions on the output of the regulator from causing damage during this transition period when the over-current protection circuit is resetting. If the overload event was an over-voltage the output of U31a removes the shutdown condition from AND gates U2a/U2b allowing the regulator to return to operation. Each of the inputs to U25c are driven by an AND gate (U30d and U30c). These gates form part of the three-shot lock-out circuitry. Binary counter U14a counts three over-current events and U14b counts three over-voltage events. As long as the number of trips is less than three the outputs of U31c and U31b are logic 0, the outputs of inverters U27e and U27d are logic 1 and over-current or over-voltage trips are transmitted through the AND gates U30d/U30c. Once either of the event counters reaches a count of three, the output of AND gate U31c or U31b goes high and the internal reset circuitry is disabled . When the overload count reaches three LED CR8 (lockout ) turns on. A master reset is required to restart the regulator circuitry in this case. Power-On and Master Reset Circuit (refer to Block F on Schematic diagram 41D1680S) Whenever the control power supply from the transmitter (+ 12v) is disconnected and reconnected to the circuitry, a power-up master reset is initiated. Q5 is activated after a delay given by capacitors C36-C39 and divider R78, R74. K2 triggers the timer U18 which issues a mater reset pulse. K2 can also be activated directly by pressing and releasing the master reset switch SW1 on the regulator. Additionally, the main control board of transmitter can issues a reset command on pin 1 of connector J1 (operator pressing tx front panel reset button). This external reset command will only have an effect only if an overload trip has been recorded and is disregarded otherwise. In this case U19 activates relay K2. 3. TESTING AND TROUBLESHOOTING With the exception of replacing the pass transistor in this circuit, repair of the circuitry on these units in the field is not recommended. Any adjustments provided on the module are for factory settings only. Modification of these settings should not be attempted in the field as damage to other sections of the transmitter may occur. To remove a regulator module, first unplug the control cable (ribbon cable). This shuts off the regulator. Then unplug the DC cable that feeds the PA module and pull the module out of the housing. Support the bottom of the regulator as the slide mechanism is shorter than the regulator itself and the regulator may drop suddenly, potentially damaging the AC input connector. TABLE OF CONTENTS 1. 2. 3. 4. 1. INTRODUCTION .........................................................................................................................1 CIRCUIT DESCRIPTION..............................................................................................................1 TESTING AND TROUBLESHOOTING..........................................................................................2 PARTS LIST................................................................................... Error! Bookmark not defined. INTRODUCTION In order to minimize the amount of wiring in the transmitter, a single circuit board was used to distribute the AC power and various DC control voltages throughout the transmitter. The circuit board is mounted on the AC circuit breakers behind the circuit breaker panel. On later models of the MX1000, the control power supplies are also mounted on this panel. 2. CIRCUIT DESCRIPTION The AC from the mains terminal block is distributed to the various power supplies and the blower via this board and the breakers. The control power supplies receive their AC power via fuses Fl through F4 on J8 and J9. The three control voltages from these supplies come into the board on J8 and J9 as well. Each of the voltages is monitored by voltage monitor ICs U3, U4, and U5. If one of the voltages fail, the PS1 FAIL or PS2 FAIL LED will illuminate. In addition, these control supply failure signals are routed to the transmitter control board. Each of the control voltages from the control power supplies is diode-ORed. Note that a single control power supply can power the transmitter on it's own. Dual supplies are provided only for redundancy. The AC to the transmitter blower and to the two power supplies is routed through circuit breakers CB1 through CB3. The BLOWER ON command is applied to this board on J8-39 from the tx control board. An emergency interlock is provided for interlocking the transmitter to a building fire alarm system. This interlock disables the transmitter blower as well as the power supplies (not the control power supplies). The connections to this interlock are on J7. The interlock can be bypassed via JP1. K6 controls the AC to the contactor relay K3 which provides AC to the blower at J2-2 and J2-3. The AC that supplies the blower, also supplies power to the airflow switch. The voltage applied to the blower also arms the power supply contactors K1 and K2. The TX-ON command is applied through J8-37 from the transmitter control board. This signal energizes K4 and voltage is applied to the power supply contactor coils of K1 and K2 via the step start thermal interlock circuits and the breaker auxiliary contacts. The AC to the power supplies is applied through a step-start circuit to minimize the inrush currents associated with the ferroresonant power supplies. This step start circuitry consists of a resistor in series with the transformer that is shorted out after a predetermined delay period. A solid state relay is used to short the resistors allowing full supply voltage to be applied to the power supplies. In the event of a failure in this timing circuit there is a thermal cutout switch mounted on the step start resistors. These thermals will remove the power to the power supply contactor coils, thus removing power from the supply. The step start timing circuit for one power supply will be described, the second circuit is identical. When AC is applied to the surge The step start timing circuit for one power supplyresistors, AC is applied to opto isolator U2-3 (U2-4). This opto-isolator applies voltage to the timing circuit consisting of R5 and C5 (R16/C11). When the voltage across the capacitor reaches a predetermined level as set by the voltage divider R10/R11 (R13/R14), the output of comparator UlA (UlB) goes high causing the solid state relay K7 (K5) to turn on, shorting out the surge limiting resistors. 3. TESTING AND TROUBLESHOOTING This board is essentially an interconnect circuit for the transmitter and, as such there are not many circuits on the board to require service. Much of the troubleshooting that can be done with this circuit is detailed in the installation section of this manual. The troubleshooting can be done by simply observing which LEDs are illuminated and determining where the problem lies. Refer to figure for the location of the LEDs and to the schematic diagram (figure ) for their function. DS 11 and DS12 indicate the presence of AC on the inputs to the circuit breakers CB1 through CB3. DS5 indicates the presence of a blower command. DS8 indicates that the blower contactor K3 is closed. DS6 and DS7 indicate that power supply contactors (K1 and K2 respectively) are closed. DS9 and DS10 are illuminated during the startup inrush limiting period, indicating essentially that the inrush resistors are in circuit. Note that these resistors are provided to limit the inrush caused by the magnetizing current of the ferroresonant transformers and protect the contactors from damage due to these high currents as well as prevent inadvertent breaker trips. Should the inrush circuitry fail to function properly, leaving these resistors in circuit and dissipating power, the thermal cutouts mounted on the surface of the resistors will open, causing the contactors to open. DS1 and DS2 indicate this thermal cutout condition should it occur. DS11 R46 J8-37 R45 TX ON CMD L1 +12V L1 L1 1uH DS12 L2 11 L2 THERMAL 1 FAIL J13 R1 NC NC J15 220uF NC CR9 16 JP1 J8-39 BLOWER ON CMD 11 K3 K2 K1 J7 1N4001 K6 DS2E-S-DC12V CR8 +12V R41 16 E1 K5 DS2E-S-DC12V R36 E8 51K E2 11 TO RESISTOR 1 E7 EMERGENCY INTERLOCK +12V 13 DS5 ON CMD TO BLOWER 20K DS9 13 T92S11A12-240 T92S11A12-240 1N4001 51K THERMAL 2 FAIL T92S11A12-240 R2 +12V DS2 SCR 1 OPEN K4 DS2E-S-DC12V RES 2 THERMAL J14 CR7 1N4001 51K DS1 RES 1 THERMAL J16 C12 AM2-A9A8AW CB3 NO 13 AM2-A9A8AW CB1 NO 16 AM2-A9A8AW CB2 NO 51K 51K R33 1K DS8 TO RESISTOR 2 K5-11 J8-40 R42 DS7 DS6 K8 R35 51K 22uF +12V C15 22uF LM324 Q1 2N2222 4K7 1K R57 43K 13 10 1K C11 .1uF +12V +12V R40 L2 10K U6-2 ILQ1 12 R56 C16 22uF 13 1K R58 43K R15 1K U1B LM324 R13 1K R14 1K R52 1K 10K R53 22uF +12V R38 11 10K R55 16 L2 R39 10 43K 10M +12V L1 15 U6-1 ILQ1 C13 R50 1K R11 1K U1C R47 14 +12V R51 1K 10K LM324 13 +12V L1 R10 1K R49 1K R37 R12 R16 U1D 14 LM324 R54 Q2 2N2222 4K7 43K 1K 11 C14 10M C5 .1uF +12V 1N4001 CR11 U2-4 ILQ1 R3 1K U1A R4 12 R48 12K 11 11 1N4001 CR10 R5 +12V R21 11 +12V U2-3 ILQ1 +12V +12V 20K 470R U2-2 ILQ1 16 U2-1 ILQ1 J2 R20 R18 470R R19 1K CSD2425 CSD2425 J1 R17 1K R6 14 R34 51K 15 K7 DS10 SCR 2 OPEN 20K LARCAN M8 -12V M6 M3 +12V +5V M9 +12V R7 L3 L4 L5 M7 M5 M4 M1 +5V C7 2K7 DS3 J3 .1uF U3 R22 7K5 PS1 FAIL R29 F2 J1-1 L1 J8 L2 J1-2 2K -12V J8-31 PS1 STATUS F1 CR3 80SQ040 +12V R23 MC34161 1K CR2 10 11 12 13 14 15 L2 -12V 8K2 L7 CR1 80SQ040 +12V R24 +5V C8 2K7 DS4 F4 PS2 FAIL .1uF L1 U4 -12V J9 L2 R31 2K J8-32 PS2 STATUS +12V C2 10uF 80SQ040 CR5 R30 MC34161 1K C3 80SQ040 10uF +5V R25 CR4 8K2 R27 R9 9K1 9K1 C1 10uF 80SQ040 C9 R26 1K 1K .1uF U5 MC34161 10 11 12 13 14 15 +12V -12V J10 J11 J12 L11 C10 C6 C4 330pF 330pF 330pF +12V +5V L12 L13 J5 10 11 12 13 14 15 10 11 12 13 14 15 -12V L9 L6 L10 PS1 STATUS PS2 STATUS -12V L15 J6 +5V +5V R32 F3 CR6 R8 L8 J4 +5V 7K5 +12V +5V 80SQ040 R28 TX ON CMD +12V +5V L16 BLOWER ON CMD K5-11 L17 L14 LARCAN 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 TABLE OF CONTENTS 1. 2. INTRODUCTION .............................................................................................................1 CIRCUIT DESCRIPTION..................................................................................................1 General...............................................................................................................................1 On/Off Control And Interlock Functions . ...............................................................................2 Metering Display Circuitry ...................................................................................................2 AGC And VSWR Protection .................................................................................................3 Interconnection With The Transmitter ...................................................................................4 Remote Control ..................................................................................................................4 3. TESTING AND TROUBLESHOOTING..............................................................................5 Metering switches ................................................................................................................5 Interlocks ............................................................................................................................6 Control................................................................................................................................6 Remote Status and Telemetry interface ................................................................................7 AGC Circuitry ......................................................................................................................7 4. PARTS LIST....................................................................... Error! Bookmark not defined. 1. INTRODUCTION The MX1000 control system is completely self contained on a hinged panel at the front of the transmitter. From this panel, the user can turn the transmitter on and off, raise and lower the output power, and monitor all critical parameters and status. The interface for remote control of the transmitter is also provided from this panel. The control system handles all the interlocking control, protects the transmitter against excessive VSWR and displays power supply status. Meters are provided for monitoring output power, reflected power, P/S currents and AGC voltage. Figure 1 Front Panel 2. CIRCUIT DESCRIPTION GENERAL The circuitry is generally divided into various functional sections. Each section performs different functions and is typically shown on a separate sheet of the schematic. The circuit board used in the MX1000 was designed for dual uses. On the MX1000, this board is configured to control a single transmitter. In another configuration (internally referred to as Group-2), this board controls dual PA/Power supply cabinets. ON/O FF CONTROL A ND INTERLOCK F UNCTIONS (P AGE 1 OF T HE SCHEMATIC ). The ON/OFF state of the transmitter is determined by the state of the latching relay K6. Note that OFF switch S11 is connected such that it is always enabled (this is a built in safety feature of the transmitter: pressing S11 at any time, even if the transmitter is in remote mode will latch K6 into the OFF state). The ON switch S12 is only enabled when the LOCAL/REMOTE switch Sl0 (shown in LOCAL mode) is placed in the LOCAL position. If S10 is in REMOTE mode, the remote inputs are enabled and can turn on and off the transmitter. Interlock connections to the control board are on J2. The signals from the interlock circuitry in the transmitter are opto-isolated (U21, U22 and U24A) for circuit protection. Interlocks include the airflow in the cabinet and the air temperature in the exhaust duct as well as another 'External' interlock that can be connected to patch panel or coax switch interlocking circuits. The outputs of the opto-isolators are fed to AND gates U19B and U19C. If an interlock opens or fails in any way, these gates will remove the drive from the base of transistors Ul 7A and B. These transistors buffer the ON command from K6 to turn on the power supplies. Interlock failure also latches the associated latching relay (K3, K4, K7, K8, or K9). These relays remain latched until a reset command is issued. If an interlock is opened and then restored, the latching relay remains latched. This ensures that a "history" or record of the interlock failure is retained. On early versions of the transmitter, this would cause the interlock LED to remain off until the reset was given. Later versions of the control circuit included a circuit that would cause the LEDs to blink on and off after the interlock was restored but before the reset was pressed. A blinking LED indicates that the interlock was opened but subsequently restored. Note that the command to turn on the blower is sent directly from relay K6 and is not included in the interlock circuitry. METERING DISPLAY CIRCUITRY (P AGE 2 A ND 3 O F T HE SCHEMATIC) The circuitry shown on pages 2 and 3 of the schematic is identical in function. The two sets of circuitry simply drive different meters. The metering circuit on the control board serves to route the selected signal (coming from various points within the transmitter) to the front panel display meter. As both metering circuits are the same, only the circuitry on page 2 of the schematic will be described. A debounce IC is used as a latching circuit for the meter selection switches. The debounce ICs U6 and U7 (MC14490) use an oscillator to debounce the switch inputs. Capacitor C31 is connected between to pins 7 and 9 of U7 and determines the frequency of oscillation. Buffer inverter U42A is used to connect the oscillator output of U7 to pin 7 of U6. When a switch is pressed, R33 is temporarily removed from the circuit allowing the oscillator to oscillate and the debounce IC debounces the switch inputs. When the switch is released, R33 is grounded, causing the oscillations to stop. At the point the oscillation is stopped, the output of the debounce IC latches. The outputs remain latched in the last known state until the debounce oscillator is functioning (user presses a selector switch). The outputs of U6 and U7 drive the selector inputs of CMOS analog switch ICs U3 and U4. The output of these analog switches drive the digital panel meter via buffer amplifier U9C and calibration pot R217. The schematic shown on page 3 is identical in design to that of page 2, except for the obvious component designation changes and that the buffer amplifier output drives the analog power meter. This meter is current driven, so the adjustment pot R219 adjusts the current being fed through the meter, as opposed to the voltage being fed to the meter. AGC A ND VSWR PROTECTION (P AGE 4 OF T HE SCHEMATIC). The AGC circuitry is designed to maintain the power of the transmitter at a particular power level, however the AGC circuit is also used to generate cutback protection in the event of excessive output VSWR. Output power is sampled and detected by the RF detector board and fed to the AGC circuitry J8. U35A buffers the voltage and feeds the metering display circuitry through calibration pot R164. U35B is configured as a comparator, using the voltage from NOVPOT U43 as a reference voltage against the sampled output voltage. The output of U35B feeds the AGC output via buffer amplifier U35C. AGC enable switch S23 is shown in the "disable" position. In this position, the AGC voltage is grounded through forward biased transistor U33D, thus disabling the ACG part of the circuit. U43 is a solid state Non Volatile Digital Potentiometer. The IC has an internal pulse counter and internal switching logic and the solid state equivalent of a stepping motor to connect the taps in an internal string of resistors, one at a time to its "wiper" terminal. Programmable non-volatile memory is provided within the device to maintain its last setting and restore that setting during power-up. U41 is configured as a clock pulse generator providing the required clock signal to U43. VR1 is a safety device that disables the raise/lower circuitry from operation during power fail or power-up conditions. This prevents inadvertent transmitter power changes. The output of VR1 feeds AND gate U38A. Pressing the RAISE (S20) or LOWER (S17) switch causes the other input to U38A to go high. This has the effect of starting the clock generator, U41, and placing a low on pin 7 of U43. If the RAISE switch was pressed, pin 2 of U43 is low as well, causing the "wiper" pin (pin5) of U43 to rise in voltage. If the LOWER switch was pressed, pin2 of U43 stays low, causing pin 5 of U43 to lower in voltage. AGC SYSTEM OPERATION The function of the Automatic Gain Control system is to keep the transmitter operating at 100% over varying environmental conditions. The intent of this system is not to compensate for device failures, or excessive loss in output systems due to mismatch or poor tuning. Power FETs have some inherent change in gain over operating temperature and this is the reason for the AGC system. Generally, the AGC is set up with 10 - 15% headroom. Typically, this is done by disabling AGC, setting the exciter for a tx output power of 115%, then, with the AGC enabled, lowering (or raising) the power for a nominal 100% output. Of course, this can only be done (properly) with a healthy transmitter, at normal operating temperature. The AGC control sends a voltage to a variable attenuator located in the 4-way splitter module. This voltage is varied, depending on the gain of the PA modules, to keep the transmitter output constant. The detected sample of the reflected power is fed to comparator U29B. This signal is compared to a factory set threshold level determined by resistor combination R142, R146,R138 and R125. As the reflected power increases to this preset level, the output voltage from U29B will increase. The output of U29B feeds buffer amplifier U35C and thus overrides the AGC voltage, causing the transmitter power to drop. In addition, op-amp U29C compares the output voltage from U29B to a factory preset level as determined by R137/R13O. As the output of U29B increases due to VSWR, U29C will turn on the CUTBACK LED D56 on the front panel display. The forward power telemetry is also sent to op-amp U28B where it is amplified by a factor of two and then passed through a pot. The output from the pot is then sent to op-amp U28C. However, if the output of the pot is too low, diode CR28 will pass a voltage of approximately 2.7V to the input of the diode. The other input of op-amp U28C receives the reflected power telemetry. Now, when pot R128 is set properly, if the reflected power telemetry reaches the same voltage as the forward telemetry from pot R128, then you have high VSWR and the transmitter should be shut off. The transmitter will be shut off because the output of op-amp U28C will cause relay K11 to trip. When K11 trips, it sends a "VSWR OUT TRIP" indication to and gate U19A which causes the transmitter to turn off. It will also cause K10 to trip, and stay tripped until a reset command is issued, causing the VSWR trip led to record the VSWR trip. Now, once K11 trips, the input capacitor to U31 A will start to charge. When it passes +5V, relay K11 will be set back to it's original state and the transmitter will turn on again. In this way, a momentary VSWR will cause the transmitter to trip off and then restart. However, each time relay K11 trips, the monostable IC U30B sends a pulse to slightly charge capacitor C92. If the transmitter trips 3 times in succession, capacitor C92 will have charged past the voltage present on the negative input of U31B, which is provided by the voltage divider of R150 and R154. Should this happen, op-amp U31B will cause relay K5 to trip. This will turn off the transmitter until a reset command is issued. INTERCONNECTION W ITH T HE T RANSMITTER (P AGE 5 O F T HE SCHEMATIC) Information from the various modules within the transmitter are fed to the control board via J3. Table 1 details the signals and pins. 11 12 13 16 18 19 20 23 25 26 27 Table 1 Reset Command Over Current Status Current Telemetry Over Voltage Status Lockout Status Over Current Status Current Telemetry Over Voltage Status Lockout Status Over Current Status Current Telemetry Over Voltage Status Lockout Status Over Current Status Current Telemetry Over Voltage Status Lockout Status All Regulators Regulator 1 Regulator 1 Regulator 1 Regulator 1 Regulator 2 Regulator 2 Regulator 2 Regulator 2 Regulator 3 Regulator 3 Regulator 3 Regulator 3 Regulator 4 Regulator 4 Regulator 4 Regulator 4 The lockout information from the regulators is an open collector signal, these signals are bused together to a “collective” lockout indication. The trip information is connected together in a similar manner. Diode CR32 connects the trip and the lockout lines so that either a trip or a lockout of the regulators will cause opto U31A to turn on U16B, causing the REGULATORS OK LED to turn off. In addition, relay K1 will latch, causing the REGULATOR TRIP LED to turn on. K1 is also connected to remote interface J5 which will indicate that a regulator tripped. If a regulator trips, and then locks out, the REGULATORS OK LED will be off. However the REGULATOR TRIP LED will blink, indicating the lockout. U8 is configured as an oscillator that controls the ‘blinking’ of the LEDs The clock signal from U8-3 passes through U5A only if a regulator has locked out. This signal then alternately turns U16A on and off. The current telemetry signals from the regulators are used for front panel metering and also telemetry. These voltages pass through calibration pots R221, R225, R229 and R233. From here they are buffered by op amp U2 and sent to both the remote control interface and to the analog switches that send the signals to the meters. Note: In the case of parallel 1kW cabinets, the information from the second amplifier cabinet is returned to the control board via J4.Pl R EMOTE CONTROL (P AGE 6 OF THE SCHEMATIC) This page illustrates the routing of the remote control interface. Connector J11 is a 25 pin D-shell connector that comprises the majority of the remote control interface connection. Remote control connections are detailed in Table 2. When the front panel REMOTE switch is pressed, a remote arming voltage is present and the grounding of a remote control input will result in that command being issued. A remote reset command on J11-5 will cause the opto U24 to send a reset command. This reset is split into an active low and an active high reset by transistors U20 B and D. Connectors J12, J13, J14, and J15 bring information from the PA's to the remote interface. On those connectors pin 3 brings the cutback voltage, and pin 5 brings a RF OK indication. The cutback voltage is buffered by op amps U10A, B ,C,D while the RF OK indication is isolated by opto isolators U11A, U11B, U12A, U12B. Table 2 Pin 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 3. Signal PA 1 Current PA 2 Current PA 3 Current PA 4 Current Reset ON OFF AGC Raise PA 1 Cutback PA 2 Cutback PA 3 Cutback PA 4 Cutback Reflected Power Vis. Fwd. Power Aur. Fwd. Power AGC Lower PA 1 RF OK PA 2 RF OK PA 3 RF OK PA 4 RF OK Ext Interlock Temperature Interlock Air Flow Interlock Cab. 2 Temp. Interlock** Cab. 2 Air Flow Interlock** Function Telemetry Telemetry Telemetry Telemetry Command Command Command Command Telemetry Telemetry Telemetry Telemetry Telemetry Telemetry Telemetry Command Status Status Status Status Status Status Status Status Status TESTING AND TROUBLESHOOTING For the most part, there is very little servicing that can be done to this circuit in the field. The circuitry uses surface mount technology (SMT) and can be very difficult to service with conventional tools. There are adjustments that are preset at the factory and do not require readjustment under normal circumstances in the field. The following tests are in essence, functional tests that can be performed to determine it the circuitry is indeed working properly. In the event that the circuitry is not functioning the way it should, it is suggested that firstly, a visual inspection be done for obvious problems, secondly, that wiring into and from the circuit board be inspected and finally, that the circuit board be removed and replaced. For these tests, if the board functionality is tested in the transmitter, it is recommended that the breakers for the blower, and power supplies be left off. • METERING SWITCHES Ensure that JP1 and JP2 are installed. Note: on the MX1000 version of this board, some switches are not installed. These are for the dual cabinet version of the controller. • • • • • • • • • • • On power-up the LEDs on the VIS switch for POWER METERING should be lit as should the LED on the PA1 switch for METERING. When a switch button is pressed the corresponding LED should illuminate. Select the VIS metering function on the POWER METERING section. Connect a variable power supply set to 4 volts to J8-9. Adjust R164 for a reading of 100% on the power meter. R219 may need adjustment in order to get the correct deflection on the meter. Select the RFL metering function. Using the variable supply, apply 4 volts to J8-6. Adjust R117 for a reading of 100% on the meter. Select the AUR metering function. Connect the variable supply to J8-11. Note that the board has no adjustment for the meter deflection in this function. In the transmitter calibration of this function is done on the RF detector board. There should be meter to deflection for 4 volts input. Select the AGC metering function. Press the OFF switch. Measure the voltage on the BNC connector J16. Adjust R217 so that the voltage measured at the BNC connector appears on the LCD display (±0.1 volts). Select the PA1 metering function. Apply a voltage between 1 and 2 volts to J3-4 and verify that there is a meter reading. Note: a voltage higher than 2 volts will cause a reading of “1” on the screen indicating an over-range condition. Select the PA2 metering function. Apply a voltage between 1 and 2 volts to J3-4 and verify that there is a meter reading. Select the PA3 metering function. Apply a voltage between 1 and 2 volts to J3-4 and verify that there is a meter reading. Select the PA4 metering function. Apply a voltage between 1 and 2 volts to J3-4 and verify that there is a meter reading. INTERLOCKS Install jumpers across: J2-1 and J2-2 J2-3 and J2-4 J2-5 and J2-6 • • • • • Press the reset button. The EXTERNAL, TEMP, and AIR LEDs should all be illuminated. Remove the jumper across J2-1/J2-2. The EXTERNAL LED should extinguish. Re-install the jumper. The LED should stay off until RESET is pressed. While the Led is on you should see ground on J11-21, while the led is off, J11-21 will be floating. Remove the jumper across J2-3 and J2-4. The TEMP led should turn off. Re-install that jumper. The Led should stay off until you press reset. While the Led is on you should see ground on J11-22, while the led is off, J11-22 will be floating. Remove the jumper across J2-5 and J2-6. The AIR led should turn off. Re-install that jumper. The Led should stay off until you press reset. While the Led is on you should see ground on J11-23, while the led is off, J11-23 will be floating. Again remove the jumper across J2-5 and J2-6. The AIR led should turn off. Re-install the jumper. Put the board in remote (push in the remote button so the led on the switch is turned on) and by grounding J11-5 you should be able to turn on the LED again. CONTROL In Remote mode, the local ON button (on the tx front panel) will not work. The OFF button will still work. This is a built-in safety feature of the transmitter. • • Verify that the REMOTE switch is in the Local, or ‘out’ position. The corresponding LED should be off. The transmitter controller is in ‘Local’ control mode. Press the ON switch and verify that its corresponding LED is illuminated. Press the OFF switch and verify that its LED is illuminated and the ON LED is extinguished. • • • • • • • • Press the REMOTE switch to set the control into ‘Remote’ mode. The LED on the REMOTE switch should be illuminated. Press the OFF switch. The OFF LED will illuminate. Verify that when the ON switch is pressed, there is no change in state. Set the control back to ‘remote’ mode. Ground J11-7, and verify that the OFF LED turns on. Ground J11-6 and verify that the ON LED turns on and the OFF LED is extinguished. Verify that with the control in ‘local’ mode that the above two steps have no effect on the transmitter on/off state. Press RESET. Verify that the REG OK LED is illuminated and the REG TRIP LED is extinguished. Verify that by grounding J3-2 (or any one of J3 pins 2,5,9,12,16,19,23,26), the REG TRIP LED illuminates and REG OK LED turns off. The REG TRIP LED will only turn off when RESET is pressed and there is no ground on J3-2 any of the other pins noted above. Ground J3-6 (lockout). The REG TRIP LED should now blink. The LED will blink as long as J3-6 is grounded (Any one of J3 pins 6, 13, 20, 27). R EMOTE STATUS AND T ELEMETRY INTERFACE • Using a variable power supply set at approximately 4 volts, the voltage applied at pins listed in the first column will be buffered and appear at the pin on the second column. J12-2 J11-9 J13-2 J11-10 J14-2 J11-11 J15-2 J11-12 • Grounding the pin listed in the first column, will result in a grounded pin in the second column J12-5 J11-17 J13-5 J11-18 J14-5 J11-19 J15-5 J11-20 Apply a voltage (~4 volts) to J8-11. The same voltage should appear at J11-15. Apply a voltage to J8-9. Adjust R164 for the same reading at J11-14. Apply a voltage to J8-6. Adjust R117 so for the same reading at J11-13. • • • • • • • • • • • • • • • AGC CIRCUITRY Install jumpers across J2-7,8 and across J2-9,10. Press the ON switch. Apply +5V to J8-9. Do not apply any voltage to any other pins on that connector. Push the ACG ENABLE switch. The LED on the switch should illuminate indicating AGC control is enabled. Measure the voltage on the AGC connector J16. With the transmitter in local control mode, alternately pressing the AGC RAISE and LOWER buttons you should be able to lower and raise the voltage on J16 (note: RAISE will actually decrease the voltage and vice versa). Set the control to remote mode. The AGC RAISE and LOWER switches will no longer vary the voltage on J16. By alternately grounding pins J11-8 and J11-16 you should be able to lower and raise the voltage on connector J16 (remotely). Press the OFF switch. The voltage on J16 should be substantially higher (approximately 8 volts or higher). Press the ON switch. Remove the voltage on J8-9. Apply +5V to J8-6. Monitor the voltage at J16. Adjust R138 for approximately 1 volt at J16. • • • • • Adjust R137 and verify that DS6 can be turned on and off by this adjustment. Apply +4V to J8-9. Adjust R128 for 4.0 Volts at U28-9. Apply +4V to J8-6. The VSWR TRIP LED should illuminate and the VSWR L/O LED will illuminate after a few seconds. Remove the voltage from J8-6. Press RESET to clear the VSWR TRIP and VSWR L/O LEDs. Briefly touching +4V to J8-6 and removing it 3 times within a few seconds will cause theVSWR L/O LED to come on and stay on until RESET is pressed. VSWR OUT TRIP (SH.4) LOCAL/REMOTE 6 S10 R62 1K MMPQ2222A TQ2SA-L2-12V U17D HSMS-2800 CR22 HSMS-2800 16 14 R107 330pF C84 1K U26A MOCD207 R105 1K5 DS9 U15B MOCD207 +12V J11-23 Cab 1 Air Ok (SH.6) CR20 HSMS-2800 J11-24 Cab 2 Temp Ok (SH.6) U26B MOCD207 R101 1K5 R104 330pF C82 1K 1K5 R103 CAB 2 TEMP REMOTE ON CMD J11-6 (SH.6) CR19 HSMS-2800 DS8 R56 C53 R102 330pF +12V TQ2SA-L2-12V K7 10 +12V REMOTE OFF CMD J11-7 (SH.6) DS2 R71 1K 1K5 CAB 1 AIR TQ2SA-L2-12V K8 +12V 10 1K U15A MOCD207 +12V CR10 R106 +12V 16 DS1 11 DS10 J11-22 Cab 1 Temp Ok (SH.6) CR21 HSMS-2800 R65 1K C63 330pF TRIP BLINKER S11 U16-7 SH.5 1K5 R100 1K5 CR17 HSMS-2800 +12V CAB 2 AIR CR18 HSMS-2800 DS7 R99 U17C 10 6 CR9 HSMS-2800 +12V R120 330pF C90 1K +12V OFF J4-37 CAB B ON CMD (SH.5) J11-21 Ext Ok (SH.6) 330pF U27B MOCD207 R108 1K5 2K K6 +12V 10 CAB 1 TEMP R79 DS11 C85 CR12 HSMS-2800 TQ2SA-L2-12V K9 +12V 10 U17B C76 .01uF S12 MMPQ2222A 12 R110 1K5 1K U27A MOCD207 100 +12V 100 R95 11 13 REMOTE ARM (SH.4) +12V +12V +5V 10 BLOWER ON CMD J3-39 (SH.5) J4-39 2K R113 DA DB O1 O2 O3 O4 O5 O6 15 +12V I1 I2 I3 I4 I5 I6 GND 10 12 14 R91 R76 +12V +12V R96 10K ON LOCAL ARM (SH.4) EXT 16 13 10K U23 10 2K 1K5 1K5 10 14073 REMOTE ARM (SH.4) R109 CR11 HSMS-2800 R114 MMPQ2222A R77 U20A MMPQ2222A U17A U19C 15 15 10K 14503 10 R88 +12V 330pF R87 1uF CR16 HSMS-2800 4K7 MMPQ2222A 11 12 13 U24A MOCD207 1K5 + C71 C73 .01uF +12V C81 +12V +12V TQ2SA-L2-12V K3 +12V 10 100 14073 R92 10K R98 CR15 HSMS-2800 DS12 VSWR LOCKOUT CR14 HSMS-2800 J3-37 CAB A ON CMD (SH.5) 330pF +12V V LOCK (SH.4) 100 R84 1K5 100 R82 11 13 O1 O2 O3 O4 O5 O6 C80 R111 1K5 +12V R83 U19B U22B MOCD207 R97 330pF Active High Reset (SH.4) RESET SW J3-1 J4-1 (SH.5) TQ2SA-L2-12V K5 10 330pF +12V C83 CR13 HSMS-2800 DA DB R90 10K +12V L1 TQ2SA-L2-12V K4 10 +12V 15 1K5 1uF GND I1 I2 I3 I4 I5 I6 +12V 10 12 14 U22A MOCD207 R93 C79 RESET +12V C68 1uF R81 14503 10 16 +12V EXT CAB 1 TEMP CAB 1 AIR CAB 2 TEMP CAB 2 AIR U18 R89 10K +12V +12V +12V 330pF J2 14073 R36 4K7 U21B MOCD207 1K5 C86 +12V R94 C77 14 R85 10K +12V U19A 1K5 330pF +5V C74 .01uF U21A MOCD207 R86 C75 R259 10K Active Low Reset SH.4 & 5 ) 10 1K +12V +12V +12V R213 S13 330pF C78 1K U25A MOCD207 J11-25 Cab 2 Air Ok (SH.6) +12V +12V +12V TQ2SA-L2-12V +12V R39 R244 4K7 1K Q5 MSD601 R34 R245 4K7 1K Q6 MSD601 +5V Ain Bin Cin Din Ein S4 10 S2 PA4 10 S9 AGC V 10 S7 PA5 10 S5 PA6 10 10 R33 C31 1K 1000pF 1K Q8 MSD601 R19 R246 4K7 1K Q7 MSD601 R11 R248 4K7 1K Q9 MSD601 JP1 14 +5V 10 R29 1K R27 1K R23 10 + 9 - LM324 U9C C93 1K .1uF R217 1K +12V +12V Ain Bin Cin Din Ein Aout Bout Cout Dout Eout 15 13 11 OsciIn OscOut +5V U42A 74HC04AD +5V S3 PA7 +12V S1 PA8 1Y 1Z 2Y 2Z 3Y 3Z 4Y 4Z 1E 2E HC4066 3E 4E 10 R24 1K R28 1K R32 1K R31 1K MC14490 11 13 12 .01uF U4 14 (SH.5) +5V C29 .01uF 14 12 330pF C96 +5V U6 +5V 1K R22 C26 4K7 1Y 1Z 2Y 2Z 3Y 3Z 4Y 4Z 1E 2E 3E HC4066 4E J9 14 R247 GND OsciIn OscOut +5V R25 11 13 12 +12V Select 1 (SH.3) MC14490 PA3 +12V Aout Bout Cout Dout Eout 15 13 11 .01uF U3 11 14 12 PA1 I U7 PA3 I PA2 PA2 I S6 (SH.5) PA4 I 11 11 +5V +5V 4K7 1K Q4 MSD601 C30 .01uF C20 GND R12 R243 22uF +5V C34 +5V PA1 10 10 +5V 2K PA5 I 4K7 470 Q3 MSD601 PA6 I PA7 I R242 CR5 HSMS-2800 S8 R37 100K R38 PA8 I R20 LM324 U9A 16 4K7 470 Q2 MSD601 +5V +12V +12V 16 R241 22uF +5V R26 + C33 HSMS-2800 1K Q1 MSD601 2K +5V GND 4K7 R240 10 CR6 GND R35 10 R42 K2 R43 51K U9B LM324 Select Out (SH.3) +12V +12V R156 51K R151 1K Q14 MSD601 R192 R254 4K7 1K Q15 MSD601 S18 OVERALL AURAL 10 S25 CAB 1 VIS 10 S22 CAB 1 REFL 10 14 12 Ain Bin Cin Din Ein OsciIn OscOut 10 R149 1K Q16 10 10 MSD601 R255 4K7 R158 1K Q18 MSD601 R257 4K7 14 12 S24 CAB 1 AUR R199 U36 9 - U32C LM324 +12V 1K R195 C105 11 13 12 Ain Bin Cin Din Ein Aout Bout Cout Dout Eout 15 13 11 .01uF U44 1Y 1Z 2Y 2Z 3Y 3Z 4Y 4Z 1E 2E HC4066 3E 4E OsciIn OscOut C103 1000pF U42B AGC V (SH.4) 74HC04AD 10 R206 1K R207 1K R211 1K R204 1K C97 +5V S15 CAB 2 AUR 1K R196 10 + 1K MC14490 S14 CAB 2 REFL 14 GND +5V (SH.4) VIS FWD (SH.4) VIS RFL J8-11 CMB AUR (SH.4) +5V C99 .01uF S19 CAB 2 VIS 1K R194 10 11 J7 10 11 10 11 10 11 +12V 4K7 1K Q17 MSD601 R189 +5V 14 R171 15 13 11 MC14490 1K R256 16 Aout Bout Cout Dout Eout 10 11 1Y 1Z 2Y 2Z 3Y 3Z 4Y 4Z 1E 2E 3E HC4066 4E R219 50K 14 11 13 12 +12V TXA VIS 10 U39 .01uF U37 +5V 4K7 S16 OVERALL RFL +5V 330pF C101 Select 1 (SH.2) 11 13 12 .01uF U34 +5V 14 R253 +5V C102 .01uF C35 R218 50K +5V R181 OVERALL VISUAL J10 C98 22uF 4K7 Q13 MSD601 GND 2K +5V R252 GND R198 1K TXA AUR JP2 HSMS-2800 TXA RFL 4K7 1K Q12 MSD601 10 S21 TXB AUR CR30 TXB RFL R177 R251 R159 +5V 4K7 1K Q11 MSD601 LM324 U32B 16 R161 100K +12V TQ2SA-L2-12V +5V R250 +12V GND R167 C94 GND 1K Q10 MSD601 10 HSMS-2800 4K7 22uF R249 10 2K +5V TXB FWD R185 11 K12 +5V 11 +12V CR31 U32A LM324 1Y 1Z 2Y 2Z 3Y 3Z 4Y 4Z 1E 2E HC4066 3E 4E 10 R172 1K R173 1K Select Out (SH.2) J6 +12V TQ2SA-L2-12V K10 10 VSWR TRIP +12V DS13 R112 2K 100K 5K U29B R139 10K LM324 R132 R145 470K U29D 12 R144 3K6 10K U28B LM324 CR28 HSMS-2800 10K 16 CR26 HSMS-2800 U30A R152 4K7 13 U33B MMPQ2222A CX RX/CX 14528 C89 +12V 12 11 10K R178 U33D R190 2K R187 2K U43 X9C103P +12V 6 - U31B LM324 R150 3K 11 10K U33C R154 1K 12 Active High Reset (SH.1) CV THR U41 555 LOCAL ARM (SH.1) R179 10K 6 R183 1K 8 +5V R208 AGC LOWER 2 R166 1K 6 MOCD207 U45B DS14 R170 1K R165 100K 10 REMOTE ARM (SH.1) R210 1K R209 470 U46A R193 4K7 L4 470 U45A AGC RAISE L2 S17 C109 .01uF GND GND 10K S20 R176 1K 10 C107 330pF REM AGC RAISE J11-8 (SH. 6) R201 10K R175 6K8 R203 330 R184 VR2 6K8 MC34064 2 IN OUT 2K R191 DIS 2K R197 100K TR 10uF OUT 14 +5V GND R186 74HC08 IN +5V +5V U38A 14 +5V J16 +12V VR1 MC34064 U40A 74HC04AD +5V GND R155 1K R162 +5V 74HC04AD 22M 5 + AGC +5V .01uF R188 U40B 1K +12V 10 MMPQ2222A C114 C92 10uF S23 C100 .22uF 510 510 C104 330pF LM324 11 R148 1K R182 LM324 470K R205 10K HSMS-2800 AGC OUT R180 9 - 11 100K +5V CX RX/CX R153 R141 14528 U35C 10 + U35B 6 - C110 R134 MMPQ2222A 10uF CR27 10 MMPQ2222A R157 C95 330pF +12V R239 50K +12V 5 + 470 1K C115 VIS FWD (SH.3) R164 10K R160 FWD HSMS-2800 4K7 +12V U20C 13 15 14 CR34 HSMS-2800 R237 11 10 10K CR33 R238 R168 10K U35A LM324 CAB A ON CMD J3-37 12 11 R169 U30B +12V 11 +12V R236 1K R202 2K .1uF CMB AUR (SH.3 & 6) R200 27K R126 R122 100K AGC V (SH.3) 10K (SH.1) VSWR OUT TRIP 4 C87 .01uF R128 10K +12V U33A +12V CR25 TQ2SA-L2-12V K11 10 HSMS-2800 +12V R143 1K LM324 +12V R136 1K5 +12V R174 14 13 LM324 18K R147 2K R146 510 9 - R129 15 4K7 R124 10K C116 330pF 9 LM324 1K R140 LM324 U28C 10 + CR24 HSMS-2800 14 R116 100K R138 330pF 6 - +12V +5V Active Low Reset (SH.1) MMPQ2222A U31A R125 11 C88 1K5 11 5 + 470 R258 100K R115 RFL +12V 2 - C91 10uF R127 5K1 +12V R78 U29C 10 R131 VIS RFL (SH.3) R142 5K1 LM324 10 11 1K R123 10K 11 R117 10K +12V J8 10 11 R130 2K U29A LM324 R118 2 - R121 10K +12V 3 + DS6 CUT BACK 3 + 1K CR29 HSMS-2800 16 R137 3K6 100K U28A 11 R119 10K R133 11 +12V +12V R135 +12V +12V CR23 HSMS-2800 MOCD207 DS15 R212 1K REM AGC LOWER C111 330pF J11-16 (SH. 6) V LOCK (SH.1) +12V PA1 I SH.2 R15 1K R221 1K 3 + 2 U2A C19 330pF R14 1K 1K C51 PA2 I SH.2 330pF R18 CR32 HSMS-2800 J3 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 HSMS-2800 CR4 1K 330pF 5 + 6 -U2B LM324 C24 330pF R16 C18 R229 1K 1K 330pF C21 330pF R230 10 + U2C 9 LM324 R231 C12 R233 1K 1K 330pF C15 330pF 12 + 14 13 -U2D LM324 HSMS-2800 PA5 I SH.2 CR3 CR1 HSMS-2800 C6 R4 1K 330pF PA6 I SH.2 R8 1K PA7 I SH.2 C10 1K 330pF R6 1K 330pF BLOWER ON CMD (SH.1) LM324 R232 1K R2 1K 330pF 6 - LM324 I-PA4 C11 330pF J11-4 (SH.6) R3 430 C2 330pF R7 430 C13 330pF U1C 10 + 9 - 330pF C5 C1 R9 430 U1B 5 + 330pF PA8 I SH.2 CAB A ON CMD (SH.1) 330pF 2 - 330pF DS3 U1A 3 + C4 CONTROL R80 1K J11-3 (SH.6) 1K +12V 1K 330pF C8 C27 I-PA3 C23 330pF R235 R234 C54 330pF PS OK R17 430 PA4 I SH.2 R10 C14 C28 R30 R228 1K 1K 1K R13 1K J11-2 (SH.6) PA3 I SH.2 (SH.1) +12V U5A MOCD207 C25 330pF 1K 1K CAB B ON CMD J3 & J4 LOCKOUT I-PA2 430 R227 R226 C9 +12V R21 HSMS-2800 CR2 C22 R225 1K R224 1K 11 J4 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 J11-1 (SH.6) R223 R222 RESET SW (SH.1) I-PA1 C16 330pF 430 LM324 11 C17 330pF R220 1K LM324 R5 430 C7 330pF U1D 12 + 14 13 - LM324 J5 R1 430 330pF 330pF C3 R63 15 U16A 16 4K7 +12V MMPQ2222A R59 R75 1K C36 10uF DS4 REG OK REG TRIP 13 R68 R72 4K7 4K7 11 +12V CR8 U13B MOCD207 DS5 REG TRIP 555 MMPQ2222A U16C U8 U16B MMPQ2222A THR TQ2SA-L2-12V K1 CR7 10 HSMS-2800 +12V C58 12 CV R41 100K U13A MOCD207 330pF HSMS-2800 L6 (SH.1) Active Low Reset +12V R69 1K L5 DIS R40 1K 1K BLOWER ON CMD (SH.1) 14 GND TR C32 .01uF +5V +5V L3 +12V 10 1K U16D MMPQ2222A +12V R67 TRIP BLINKER R49 1K5 L7 C112 K3,K4,K7,K8,K9-4 SH.1 +5V -12V 220uF R48 1K5 C108 C106 220uF 22OuF J1 C41 1K 330pF 13 - LM324 430 C46 U12A MOCD207 LM324 330pF 1K 11 C59 330pF R45 430 C38 330pF 1K5 C64 330pF C60 330pF 5 + 6 - LM324 74HC08 10 + 9 - 1K5 C70 330pF LM324 430 C67 330pF 1K5 C37 330pF gnd M7 gnd 14 14 7 gnd M4 gnd M1 M9 gnd gnd M6 M10 J15 U25B MOCD207 M8 M5 gnd 10 11 12 13 14 15 13 74HC08 U5B MOCD207 gnd R47 330pF R70 12 U46B MOCD207 M2 U11A MOCD207 C43 U14C 14 LM324 14 14 C48 330pF +12V 74HC08 R74 430 U31D 14 U38D R53 C44 U14B LM324 13 - 7U38C C72 330pF 330pF U9D 13 - 10 U11B MOCD207 R61 430 12 + LM324 12 + LM324 2 - U14A LM324 +12V 3 + R66 C69 CMB AUR J8-11 (SH.4) R60 C61 330pF 330pF 330pF U10D 14 9 - +12V 330pF 1K 14 13 - U38B 14 R52 C66 1K VIS FWD (SH.4) R73 C65 U14D +12V VIS RFL (SH.4) R64 C62 12 + 12 + 14 13 - U10C 11 J14 C52 330pF 330pF 330pF 10 11 12 13 14 15 330pF C57 330pF LM324 U32D R50 C40 1K5 LM324 U31C 10 + 430 LM324 C50 R54 12 + R58 U28D 14 13 - LM324 74HC04AD gnd M3 gnd 330pF 9 - 330pF 10 + U12B MOCD207 U10B 12 + 14 12 74HC04AD C49 1K 6 - C39 330pF 430 U35D U42F 13 330pF 5 + 74HC04AD 11 C47 1K 330pF C56 J13 LM324 +12V R55 C55 R57 10 11 12 13 14 15 2 - 13 - 330pF R46 330pF C45 1K 12 + U10A C42 3 + R51 11 J12 10 11 12 13 14 15 10 11 REM AGC RAISE U42E 11 MMPQ2222A 74HC04AD SH.4 REM AGC LOWER +12V U42D 11 Ext Ok SH.1 REMOTE OFF CMD SH.4 U42C Cab 1 Temp Ok U40F 11 SH.1 REMOTE ON CMD 4K7 SH.1 Cab 1 Air Ok U40E Cab 2 Temp Ok U40D 74HC04AD 12 11 J11-4 74HC04AD 10 13 14 7 U40C Cab 2 Air Ok J11-5 R216 74HC04AD 11 14 7 J11-3 74HC04AD SH.5 I-PA3 SH.5 I-PA4 J11-2 11 C113 J11-1 SH.5 I-PA2 R215 1K 330pF 13 U20B 14 Active Low Reset SH.1 10 4K7 Active High Reset DS16 R214 U20D SH.5 I-PA1 14 7 U24B MOCD207 MMPQ2222A 14 14 +5V REMOTE ARM SH.1 +5V 14 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 J11 11 TABLE OF CONTENTS 1. 2. INTRODUCTION .............................................................................................................1 OUTPUT ALIGNMENT.....................................................................................................1 Required Equipment: ...........................................................................................................1 Procedure...........................................................................................................................1 3. OUTPUT CHANNELING INFORMATION ..........................................................................4 1. INTRODUCTION The bandpass filter is a three-pole filter, the center frequency of each pole being determined by an adjustable line capable of being screwed into or out of the cavity. Two lines are available: • • 470-600 MHz range; and 600-800 MHz range. The input and output coupling are controlled by the area of variable loops in the cavities. As these are pushed further into the cavity, the effective area increases, resulting in more magnetic lines within the cavity being intercepted and thereby tighter coupling. The intercavity coupling is controlled by the depth of the capacitive probes within each cavity The use of both capacitive and magnetic coupling results in a bandpass that is symmetrical in off-channel rejection. The bandpass filter is normally aligned to be slightly overcoupled. This results in a suppression of the out-of-band ±4.5 MHz products of approximately 14 dB. The overall insertion loss of this section is approximat ely 0.5 dB. 2. OUTPUT ALIGNMENT R EQUIRED EQUIPMENT : The following test equipment is required to align the output of the XLS1000 transmitter: • 0-1,000 MHz Sweep Generator (Wavetek 1080 or equivalent); • X-Y Oscilloscope (Hitachi V-212 or equivalent); • 50 Ω detector (TTC 8520-301 or equivalent); • Wiltron return loss bridge 62NF50; • 7/8"-N adaptor (Andrew 2260B or equivalent); • HN female-t o-N female adaptor; • 50 Ω load (Microlab TA6MN or equivalent); • 50 Ω coaxial cables for connections. Note that the first four Items can be replaced by an appropriate network analyzer and its associated accessories. PROCEDURE Set the sweep generator to the channel of operation. Sweep width should be adjusted to 2 MHz/division. A reference-setting sweep should be sent directly into the detector set for seven divisions of deflection on the scope. 4. Connect the equipment as shown in Figure 1. 5. Set L102, L104 and L106 for an approximate on-channel bandpass. Note: During each of the following steps, fine tune these adjustments to maintain the best possible bandpass. 1. 2. 3. 6. Set L103 and L105 for minimum insertion loss. 7. Flatten the response using L101 and L107. 8. Set L201 and L202 for the out-of-band ± difference beats. Note: Notch filters L201 and/or L202 may or may not be present. If both filters are present, try each notch on both sides as one combination may have less adverse effects on the bandpass than the other. Figure 1. Sweep Alignment Test Set-up 9. 10. Re-flatten the response using L101 and L102. Set width of filter using L103 and L105. The width should be equal to the aural-to-visual difference of +0.5 MHz (total of 5 MHz for NTSC in North America). Ideally, waveshape should appear as shown in Figure 2. Figure 2. Ideal NTSC Response 11. 12. Adjusting L105 and L107 interactively with each other, tune for proper bandwidth and best out-of-band rejection. Adjusting L103 and L101 interactively with each other, tune for proper bandwidth and best out-of-band rejection. Figure 3. Return Loss Set-up 13. 14. Configure the equipment for return loss measurements, as shown in Figure 3. Return loss should be 30 dB at carriers (Reference Figure 4). Figure 4. Ideal Return Loss 15. Readjust the filter slightly as needed to obtain proper response. Note: During this test, the Wavetek 1080 should be set to maximum output. 16. Reconnect the equipment as in Figure 1 and repeat the sweep setup to compare response to the NTSC ideal in Figure 2. 17. If the response is acceptable (less than 0.8 dB loss), return to the return loss setup and lock down all adjustments on the bandpass filter. 18. Notches should be locked down after performing the final fine adjustment with a television signal. 3. OUTPUT CHANNELING INFORMATION BPF Lines 3 ea. • 470-600 MHz Part Number 6920-6008 • 600-806 MHz Part Number 6920-6009 Notch Filter Line Discs 2 ea. • 470-506 MHz Part Number 1314-2016-4 • 506-570 MHz Part Number 1314-2016-3 • 570-690 MHz Part Number 1314-2016-2 • 690-806 MHz No disks used
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