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LM1872

LM1872

  • 厂商:

    NSC

  • 封装:

  • 描述:

    LM1872 - Radio Control Receiver/Decoder - National Semiconductor

  • 数据手册
  • 价格&库存
LM1872 数据手册
LM1872 Radio Control Receiver Decoder February 1989 LM1872 Radio Control Receiver Decoder General Description The LM1872 is a complete RF receiver decoder for radio control applications The device is well suited for use at either 27 MHz 49 MHz or 72 MHz in controlling various toys or hobby craft such as cars boats tanks trucks robots planes and trains The crystal controlled superhet design offers both good sensitivity and selectivity When operated in conjunction with the companion transmitter LM1871 it provides four independent information channels Two of these channels are analog pulse width modulated (PWM) types while the other two are simple ON OFF digital channels with 100 mA drive capability Either channel type can be converted to the other form through simple external circuitry such that up to 4 analog or up to 4 digital channels could be created Few external parts are required to complement the self-contained device which includes local oscillator mixer IF detector AGC sync output drivers and all decoder logic on-chip Features Y Y Y Y Y Y Y Y Y Y Four independent information channels two analog and two digital Completely self-contained Minimum of external parts Operation from 50 kHz to 72 MHz Highly selective and sensitive superhet design Operates from four 1 5V cells Excellent supply noise rejection 100 mA digital output drivers Crystal controlled Interfaces directly with standard hobby servos Applications Y Y Y Y Y Y Toys and hobby craft Energy saving remotely switched lighting systems Burgler alarms Industrial and consumer remote data links IR data links Remote slide projector control Circuit Block and Connection Diagram Dual-In-Line Package TL H 7912 – 1 Bottom View Order Number LM1872N See NS Package Number N18A C1995 National Semiconductor Corporation TL H 7912 RRD-B30M115 Printed in U S A Absolute Maximum Ratings If Military Aerospace specified devices are required please contact the National Semiconductor Sales Office Distributors for availability and specifications Supply Voltage Package Dissipation (Note 2) Voltage Pin 7 8 9 10 11 or 12 7V 1600 mW Va Operating Temperature Range Storage Temperature Range Lead Temperature (Soldering 10 sec ) b 25 C to a 85 C b 65 C to a 150 C 260 C DC Electrical Characteristics V a e 6V TA e 25 C Test Circuit of Figure 1 fL0 e 49 890 MHz fIF e 455 kHz unless otherwise specified Parameter Supply Voltage Supply Current Conditions Functional for VIN e 100 mV CH A CH A Pin 4 Pin 13 Going from Low to High Voltage B Off B On Min 25 9 Typ 6 13 27 1 85 Va 2 b 0 4 21 Va 2 2 35 Va 2 a 0 3 Max 7 18 Units V mA mA V V VBIAS Sync Timer Threshold DIGITAL CHANNELS A AND B Saturation Voltage Saturation Resistance Source Current Collector Pull-Up Resistance Emitter Pull-Down Resistance ANALOG CHANNELS 1 AND 2 Saturation Voltage Saturation Resistance Collector Pull-Up Resistance Pins 11 Pins 11 Pin 11 12 RL e 2 kX 12 5 0 45 160 10 20 07 V X kX Pins 7 Pins 7 9 RL e 100X 9 100 5 5 10 10 20 20 04 7 07 V X mA kX kX Pins 8 10 VPin 8 Pin 10 s 1V Pin 7 Pin 8 Pin 9 to V a Pin 10 to GND Pin 12 to V a AC Electrical Characteristics Parameter RF Sensitivity RF Sensitivity Conditions For ‘‘Solid’’ Decoded Outputs (Note 1) Circuit of Figure 5 49 MHz with Antenna Simulation Network of Figure 6 Pin 5 to Pin 15 3V s V a s 6V 3 dB Down Pin 15 Min Typ 22 Max 39 Units mV 12 58 b1 mV dB %D V kHz mVrms mVrms mV Va a 0 13 V mmhos mmhos mmhos Voltage Gain PSRR of RF Sensitivity BW Noise 32 0 35 0 28 88 Va a 0 07 Va a 0 100 Referred to Input Pin 5 VIN e 0 Referred to IF Pin 15 VIN e 0 Onset of AGC Relative to RF Input VIN Pin 5 Relative to IF Output Pin 15 1 MHz 27 MHz 49 MHz 2 From Pin 5 to Pin 18 29 AGC Threshold Mixer Conversion Transconductance 40 37 35 69 AC Electrical Characteristics (Continued) Parameter Mixer Input Impedance Mixer Output Impedance IF Transconductance IF Input Impedance IF Output Impedance Conditions Pin 5 to Pin 4 (See Curves) Pin 18 to GND Pin 17 to Pin 15 (AGC Off) Pin 17 to GND Pin 15 to GND (AGC Off) (AGC On) IF Carrier Level Detector Threshold Pin 15 VIN e 100 mV (AGC On) Relative to RF Input VIN Pin 5 Relative to IF Output Analog Pulse Width Accuracy Pin 15 V a a 0 015 455 kHz 26 49 MHz Min Typ 20 kX a 5 pF 250 41 5500 800 2 70 20 V a a 0 025 V a a 0 040 56 kX mmhos X kX MX mVrms mV V Max Units Ratio of Received Pulse Width Pins 11 12 to Transmitted Pulse Width Pin 5 for VIN e 100 mV 0 95 10 1 05 ms ms Note 1 The criteria for the outputs to be considered ‘‘solid’’ are as follows DIGITAL In order to check the decoding section four RF frames are inputted in sequence with the proper codes to exercise all four possible logical output combinations at pins 7 and 9 For each frame the proper output logic state must exist ANALOG Each analog pulse width (measured at pins 11 widths obtained for VIN e 100 mV 12) in any of the above four successive frames must not vary more than g 5% from the pulse Note 2 For operation in ambient temperatures above 25 C the device must be derated based on a 150 C maximum junction temperature and a package thermal resistance of 75 C W junction to ambient Typical Performance Characteristics Supply Current vs Supply Voltage Analog Channel Output Voltage vs Load Current Digital Channel Collector Output Voltage vs Load Current Sensitivity vs Supply Voltage Mixer Transconductance (gm) vs Input Frequency IF Output Signal Level vs RF Input Signal Level TL H 7912 – 2 3 Typical Performance Characteristics (Continued) Equivalent Mixer Input Shunt Resistance and Capacitance vs Frequency Receiver AM Rejection vs RF Input Level IF Bandpass Response TL H 7912 – 3 Test Circuit TL H 7912 – 4 Bottom View L1 e Toko 10k type (KEN-4028 DZ) 6T T1 e Toko 10 EZC type (RMC 202313 NO) Qu e 110 Pin 1–2 131T pin 2–3 33T Pin 1–3 164T pin 4–6 5T T2 e Toko 10 EZC type (RMC 402503 NO) Qu e 110 Pin 1–2 98T pin 2–3 66T Pin 1–3 164T pin 4–6 8T Toko America 1250 Feehanville Drive Mount Prospect IL 60056 (312) 297-0070 FIGURE 1 Test Circuit 4 Circuit Description The following discussion is best understood by referring to Figures 2 3 4 and 5 SYSTEM ENCODING AND DECODING SCHEME For the transfer of analog information the LM1871 LM1872 system uses conventional pulse width modulation (PWM) In applying this technique the RF carrier is interrupted for short fixed intervals (tM in Figure 2 ) with each interval followed by variable width pulses (tCH) so as to define multiple variable time spans (tM a tCH) occurring in serial fashion Synchronization is accomplished by allowing one of the transmitted variable pulse widths (tSYNC) to exceed the duration (t’SYNC) of a receiver-based timer thus allowing the receiver to recognize this pulse for synchronization purposes Taken in sequence this collection of pulses constitutes a single frame period (tF) The LM1871 transmitter is equipped to transmit up to six channels which the companion LM1872 receiver uses to derive 2 analog and 2 digital channels The receiver decodes the demodulated RF waveform from the transmitter by negative edge triggering a cascade of three binary dividers called the A B and C toggle flip-flops (Figure 4 ) By ‘‘examining’’ all three flip-flop outputs simultaneously up to 6 unique channel time intervals could be identified and recovered Only the first two channels are actually decoded however and outputted by the receiver the rest being used for identification of two digital (ON OFF) channels In passing digital information a pulse count modulation scheme is used whereby different quantities of channel pulses are transmitted by varying the number of fixed width channels following the two variable width analog channels 1 and 2 (see Figure 3 ) TL H 7912 – 5 FIGURE 2 RX Timing Waveforms LM1871 Pin Conditions Pin 5 (CH A) Pin 6 (CH B) TX Transmitted Waveform LM1872 Binary Pulse Count RX Digital Outputs CH A CH B OPEN OPEN TL H 7912 – 6 100 OFF OFF GND OPEN TL H 7912 – 7 101 ON OFF OPEN GND TL H 7912 – 8 110 OFF ON GND GND TL H 7912 – 9 111 ON ON FIGURE 3 Digital Channel Encoding and Decoding via Pulse Count Modulation 5 Circuit Description (Continued) External parts TL H 7912 – 10 Depending on layout a small capacitance (10–47 pF) may be required across pins 2 and 3 to ensure oscillator start up FIGURE 4 Simplified Schematic Diagram 6 Circuit Description (Continued) Thus either 3 4 5 or 6 channels are transmitted to represent the four possible codes that two digital channels represent The receiver intrinsically counts channels with its decoder flip-flops by responding to the negative edges of the demodulated RF waveform of which there is always one more than the number of channels The two LSBs of the binary count are read latched and fed to the output drivers which comprise digital channels A and B RECEIVER SECTION The receiver circuit is a simple single conversion design with AGC which mixes down to 455 kHz and provides 58 dB of gain using the suggested transformers in Figure 5 The active digital detector provides an additional 30 dB gain over a silicon diode resulting in an overall system gain of 88 dB More or less gain can be obtained by using different transformers The frequency range of operation extends from 50 kHz to 72 MHz encompassing a wide range of allocated frequency bands The short (1 to 2 ) vertical whip antenna that is typically used has a very low radiation resistance (0 5X to 4X) and approximately 3 pF to 5 pF of capacitance This antenna is coupled to the mixer through a high Q tank consisting of C3 TL H 7912 – 11 R1 R2 R3 C1 C2 C3 C4 C5 C6 C7 C8 C9 C10 Motor decoupling t’SYNC Sync timer R2 e R2 s 470k 0 7 C6 Mixer decoupling LO bypass optional LO tank C2 e 43 pF e 24 pF 27 MHz 49 MHz 27 MHz 49 MHz C11 L1 LO bypass LO coil Toko 10k type (KXNA-4434 DZ) 9T 0 8 mH 27 MHz Toko 10k type (KEN-4028 DZ) 6T 0 4 mH 49 MHz L1 could be made a fixed coil if desired 455 kHz mixer transformer Toko 10 EZC type (RMC-202313 NO) Qu e 110 Pin 1–2 131T pin 2–3 33T Pin 1–3 164T pin 4–6 5T 455 kHz IF transformer Toko 10 EZC type (RMC-402503 NO) Qu e 110 Pin 1–2 98T pin 2–3 66T Pin 1–3 164T pin 4–6 8T Ant input transformer Toko 10k type (KXNA-4434 DZ) 3T sec Toko 10k type (KEN-4028 DZ) 1 T sec 3rd overtone parallel-mode crystal Electrostatic discharge (ESD) protection Toko America 1250 Feehanville Drive Mount Prospect IL 60056 (312) 297-0070 9T pri of 0 8 mH 6T pri of 0 4 mH 27 MHz 49 MHz T1 Ant input tank C3 e 39 pF e 24 pF VBIAS bypass Motor decoupling T2 t’SYNC Sync timer C6 e C6 s 0 5 mF 0 7 R2 Mixer decouple 0 01 mF s C7 s 0 1 mF AGC IF bypass optional Va bypass 0 01 mF s C10 s 0 1 mF T3 X1 D1 FIGURE 5 Typical Application Circuit for 27 MHz or 49 MHz 7 Circuit Description (Continued) and T3 This tank effectively keeps strong out-of-band signals such as FM and TV broadcast from cross-modulating with the desired signal When operating at 49 MHz or 72 MHz CB interference is also effectively minimized Image rejection is relatively low however being only 7 dB 49 MHz but this does not present a problem due to the usual absence of strong interfering signals 910 kHz below the desired signal The antenna signal is stepped down and DC coupled to the mixer which consists of the emitter-coupled pair Q1 and Q2 Emitter-follower Q1 feeds the common-base device Q2 while effectively buffering the antenna from the LO energy delivered by Q4 Mixer transconductance is 4 mmhos at low frequency (1 MHz) falling to 3 3 mmhos at the upper end (72 MHz) The local oscillator utilizes an emitter coupled pair Q3 and Q4 for accurate control of mixer drive I1 Quiescently Q3 and Q4 share I1 set by 0 69V R5 but healthy voltage swings at pin 2 due to oscillation of Q3 implement thorough switching of the differential pair As a result the full 1 8 mA of drive ‘‘tailgates’’ (switches) the mixer emitter coupled pair Q1 and Q2 This current is well regulated from supply voltage changes by the VBIAS circuitry The TC of VBIAS is positive by design in order to impress a positive TC on I1 so as to compensate for the temperature dependence of bipolar transconductance in the mixer Inasmuch as Q4 operates as an emitter-gated common-base-connected device excellent isolation between local oscillator and mixer is obtained As long as pin 4 is properly bypassed Q5 presents a low impedance to the base of Q4 resulting in low oscillator noise The oscillator easily operates up to 72 MHz with overtone crystals operating parallel mode The mixer signal is stepped down from the high Q mixer tank T1 and DC coupled to the IF via a secondary winding The IF stage consists of Q7 Q8 and Q10 and delivers a transconductance of 4 mmhos 455 kHz The quiescent current I2 is set at 120 mA by VBIAS and a 6 2k resistor Again the positive TC of VBIAS is used to compensate for the temperature dependence of transconductance The impedance at the IF output pin 15 is very high (t800k) permitting the IF transformer T2 to operate at near unloaded Q (110) The overall 3 dB bandwidth of the receiver section is 3 2 kHz (see characteristic curves) this is narrow enough to permit adjacent channel operation without interference yet wide enough to pass the 500 ms modulation pulses (tM in Figure 2 ) The IF signal is DC coupled to the digital detector which consists of a high gain precision comparator a 30 ms integrator and a supply-referred 25 mV voltage reference Whenever the peak IF signal exceeds 25 mV the comparator drives Q11 to reset the digital envelope detector capacitor C12 Since it takes 30 ms for the 1 mA current source to ramp C12 to the 3V (V a 2) necessary to fire the Schmitt trigger the presence of 455 kHz carrier (period e 2 2 ms) greater than 25 mVp will prevent C12 from ever reaching this threshold When the carrier drops out the Schmitt trigger will respond 30 ms later This delay (like that associated with the burst response of the 455 kHz IF tanks) is constant over the time interval of interest Thus it is of no consequence to timing accuracy because the LM1872 responds only to negative edges in the decoder AGC is provided only to the IF the mixer having sufficient overload recovery for the magnitude of signals available from a properly operating (i e good carrier ON OFF ratio) 10 000 mV m transmitter The AGC differential amplifier regulates the peak carrier level to 100 mV by comparing it to an internal 100 mV supply-referred voltage reference The resultant error signal is amplified and drives Q9 via rectifier diode D1 to shunt current away from Q10 C8 provides compensation for the AGC loop which spans a 70 dB range The 100 mV AGC reference is accurately ratioed to the 25 mV detector reference to permit a controlled amount of brief carrier loss before dropping below detector threshold Once into AGC typically 60% amplitude modulation of the PWM carrier is possible before the detector will recognize the interference (see characteristic curves) This kind of noise immunity is invaluable when the troublesome effects of other physically close toys or walkie-talkies on the same or adjacent frequencies are encountered DECODER SECTION The purpose of the decoder is to extract the time information from the carrier for the analog channels and the pulse count information for the digital channels The core of the decoder is a three-stage binary counter chain comprising flip-flops A B and C The demodulated output from the detector Schmitt-trigger drives both the counter chain and the sync timer (Q12 R2 C6 and another Schmitt trigger) When the RF carrier drops out for the first modulation pulse tM the falling edge advances the counter (see Figure 2 ) During the tM interval the sync timer capacitor is held low by Q12 When the carrier comes up again for the variable channel interval tCH C6 begins to ramp towards threshold (V a 2) but is unable to reach it in the short time that is available At the end of the tCH period the carrier drops out again the counter advances one more and the sequence is repeated for the second analog channel To decode the two analog channels 3-input NAND gates G1 and G2 examine the counter chain binary output so as to identify the time slots that represent those channels Decoded in this manner the output pulse width equals the sum of tM a fixed pulse and tCH a variable width pulse A Darlington output driver interfaces this repetitive pulse to standard hobby servos Following the transmission of the second analog channel a variable quantity from one to four of fixed width pulses (500 ms) are transmitted that contain the digital channel information Up until the end of the pulse group frame period tF the decoder responds as if these fixed pulses were analog channels but delivers no outputs At the conclusion of the frame the sync pulse tSYNC is sent Since tSYNC is always made longer than the sync timer period (t’SYNC e 3 5 ms) the sync timer will output a sync signal to the first of two cascaded 10 ms one-shots The first one-shot enables AND gates G3 x G6 to read the A and B flip-flops of the counter into a pair of RS latches The state of flip-flop A for example is then stored and buffered to drive 100 mA sink or source at the channel A digital output An identical parallel path allows the state of flip-flop B to appear at the channel B power output Upon conclusion of the 10 ms read pulse another 10 ms one-shot is triggered that resets the counter to be ready for the next frame 8 Application Hints A typical application circuit for either 27 MHz or 49 MHz is shown in Figure 5 Using the recommended antenna input networks and driving the circuit through the antenna simulation network of Figure 6 a solid decoded output occurs for 10 mV and 12 mV input signals at 27 MHz and 49 MHz respectively The primary tap on the IF transformer T2 can also be adjusted (further from the supply side) for higher gain but it is possible to cause the AGC loop to oscillate with this method Narrow overall bandwidth is important for good receiver operation The 3 2 kHz 3 dB bandwidth of the circuit in Figure 5 is just wide enough to pass 500 ms carrier dropout pulses tM yet narrow enough to hold down electrical noise and reject potentially interfering adjacent channels In the 49 MHz band the five frequencies available are only 15 kHz apart Should only two frequencies be used simultaneously these channels could be chosen 60 kHz apart Should three frequencies be used the spacing could be no more than 30 kHz At four or five frequencies 15 kHz spacings must be dealt with making narrow bandwidth highly desirable Even at 27 MHz where allocated frequencies are 50 kHz apart the proliferation of CB stations only 10 kHz away represents a formidable source of interference The response of the circuit of Figure 5 is 34 dB and 56 dB down at 15 kHz and 50 kHz away respectively (see characteristic curves) The sync timer should have a timeout t’SYNC set longer than the longest channel pulse transmitted but shorter than the shortest sync pulse tSYNC transmitted Using the component values in Figure 5 t’SYNC e 3 5 ms which works well with a transmitted sync pulse tSYNC t 5 ms Numerous bypass capacitors appear in the circuit of Figure 5 not all of which may be necessary for good stability and performance A low cost approach may eliminate one or more of the capacitors C1 C9 C10 and C11 The cleaner and tighter the PCB layout used the more likely is the case that bypass capacitors can be eliminated In the case of marginal board stability increasing the size of capacitors C7 C9 and C10 to 0 1 mF may prove helpful If the PCB layout and parts loading diagram shown in Figure 7 is used the circuit will be quite stable up to 72 MHz TL H 7912 – 12 FIGURE 6 Antenna Simulation Network This sensitivity has been determined empirically to be optimum for toy vehicle applications Less gain will reduce range unacceptably and more gain will increase susceptibility to noise However should the application require greater range (l50m for a land vehicle for example) either the antenna could be lengthened beyond 2 and or receiver sensitivity could be improved There are a number of ways to alter the sensitivity of the receiver Decreasing the turns ratio of input transformer T3 for example will couple more signal into the mixer at the expense of lower tank Q due to mixer loading Moving the primary tap on mixer transformer T1 further from the supply side and or decreasing the primary to secondary turns ratio will also increase gain For example just changing T1 from a 32 1 primary to secondary ratio to a 5 1 turns ratio (Toko RMC202202) will double 49 MHz sensitivity (6 mV vs 12 mV) Mixer tank Q will be affected but overall 3 dB BW will remain largely unchanged TL H 7912 – 13 FIGURE 7 PCB Layout Stuffing Diagram and Complete RX Module for Typical Application Circuit of Figure 5 9 TL H 7912 – 14 Application Hints (Continued) The digital channel output devices have significant drive capability they can typically sink 100 mA and possess a 7X saturation resistance Through their emitters they can source 100 mA up to 1V above ground for driving grounded NPNs and SCRs Unfortunately this kind of drive capability can cause thermally induced chip destruction unless total power dissipation is limited to less than 1000 mW It is good practice and highly recommended to allow the digital output devices to fully saturate at all times (sinking or sourcing) and to limit the current at saturation to no more than 100 mA For extra drive the two digital outputs can always be summed by connecting pin 7 to pin 9 The IF frequency is not constrained to be 455 kHz Operation is limited on the high end to about 1 MHz due to the frequency response limitations of the active detector The low end is limited to about 50 kHz due to the envelope detector integration time (Figure 4) RECEIVER ALIGNMENT The receiver alignment procedure is relatively straightforward because of an absence of interaction between the adjustments First the oscillator is tuned by adjusting L1 while monitoring the LO signal at pin 2 with a low capacity ( j 10 pF) probe During tuning the amplitude will rise peak and then abruptly quit Adjust the coil away from the quitting point and just below the amplitude peak In order to properly tune T1 T2 and T3 the RF signal must be provided through the receiver antenna by the specific transmitter which is to be used with that specific receiver This is because the crystals which are commonly used with these systems may have tolerances as loose as g 0 01% At 49 MHz the resultant g 5 kHz deviation could easily put the incoming signal out of the 3 2 kHz receiver IF bandpass The signal should be coupled through the receiving antenna to ensure proper loading of the T3 input tank Alignment is easier with a defeated AGC which is accomplished by merely grounding pin 16 The amplitude of the 455 kHz signal at pin 15 is used to guide alignment Care should be exercised that the signal swing not exceed roughly 400 mVp or diode D2 in Figure 4 will threshold and clamp the waveform Also note that a standard 10 pF probe at pin 15 will shift the IF tank frequency an undesirable 2 kHz Unless a lower capacity probe is available it is recommended that the signal be monitored at the unused secondary of T2 Although the signal amplitude would be down by a factor of 8 25 relative to pin 15 up to 50 pF probe capacitance could be tolerated with negligible frequency shift The incoming signal is obtained by removing the antenna from the transmitter and then locating the transmitter at a sufficient distance from the receiver to give a convenient signal level (s400 mVp) at pin 15 T3 T1 and T2 are then tuned for maximum signal Applications OPERATION AT 72 MHz The licensed 72 MHz band is popular among hobby enthusiasts for controlling aircraft The higher transmitted power levels that the FCC allows yield much greater operating range and the frequency band is uncluttered relative to 27 MHz Elevated frequencies such as 72 MHz are no problem with the LM1872 The part is stable and will provide good sensitivity and selectivity at that frequency The application circuit in Figure 8 will provide a set of solid decoded outputs for k2 mV of signal at the antenna input which is designed to match the 100X resistive impedance of the wavelength antenna IF bandwidth is a respectable 3 2 kHz For good immunity to overload from a very closely (antennas touching) operating high power transmitter the transmitter design should emphasize a high carrier ON OFF ratio Using the LM1871 as a low power exciter to drive one or more external class C power amplifier stages will result in a simple acceptable low cost transmitter at 72 MHz Inasmuch as many hobby applications require more analog channels than the LM1872 normally provides particular attention should be paid to Figures 10 and 12 which describe how to expand analog channel capacity up to 4 and 6 channels respectively OPERATION WITH AN IR CARRIER An infra-red (or visible) light data link is a useful alternative to its RF counterpart Should the application demand that the radiation not leave the room or that it be directional or not involve FCC certification then a light carrier should be given consideration The principal drawbacks to this approach include short range (s20 ft ) and high transmitter power consumption There is little that can be done to dramatically improve range but short burst-type operation of the transmitter will still permit battery operation The information link (Figure 9a) consists of a light carrier amplitude modulated by a 455 kHz subcarrier The subcarrier in turn is modulated by the normal Pulse Width Pulse Count Scheme produced by the LM1871 encoder A husky focused LED is used as the transmitter running Class A 100% modulated with an average current drain of 50 mA to 500 mA depending upon range requirements The detector consists of a large area silicon PN or PIN photodiode for good sensitivity The LM1872 will directly interface to such a diode and give very good performance Only a few nanoamps of photo current from D1 are required to threshold the detector Ambient light rejection is excellect due to the very narrow bandwidth ( j 3 kHz) that results from the use of three high Q 455 kHz transformers T1 T2 and T3 Note that the LO has been defeated and the mixer runs as a conventional 455 kHz amplifier Otherwise circuit operation is the same as if an RF carrier were being received 10 Applications (Continued) TL H 7912 – 15 R1 R2 R3 C1 C2 C3 C4 C5 C6 C7 C8 C9 C10 Motor decoupling t’SYNC Sync timer R2 e R2 s 470k 0 7 C6 Mixer decoupling LO bypass optional LO tank C2 e 22 pF VBIAS bypass Motor decoupling t’SYNC Sync timer C6 e C6 s 0 5 mF 0 7 R2 Mixer decouple 0 01 mF s C7 s 0 1 mF AGC IF bypass optional V a bypass 0 01 mF s C10 s 0 1 mF 72 MHz 72 MHz Ant input tank C3 e 24 pF C12 L1 Ant input tank C12 e 160 pF 72 MHz LO Coil Toko 10k type (KENC) 4T 0 2 mH 72 MHz L1 could be made a fixed coil if desired 455 kHz Toko 10 Pin 1–2 Pin 1–3 455 kHz Toko 10 Pin 1–2 Pin 1–3 mixer transformer EZC type (RMC-502182) Qu e 110 82T pin 2–3 82T 164T pin 4–6 30T IF transformer EZC type (RMC-502503) Qu e 110 82T pin 2–3 82T 164T pin 4–6 8T T1 T2 T3 Ant input transformer Toko 10k type (KENC) 4T sec 2T pri of 0 2 mH 72 MHz 5th overtone crystal parallel-mode 72 MHz Electrostatic discharge (ESD) protection X1 D1 FIGURE 8 72 MHz Receiver Circuit In a practical remote data link the transmitter could be battery operated and set up to transmit for brief intervals only in order to save power The brief transmission could be used to set or reset the digital output latches in the LM1872 and or command new motor positions via the analog channels After transmission the commands would be stored electrically in the case of the digital channels and mechanically in the case of the analog channels As a final note if the case of D1 is connected to the anode rather than the cathode the circuit of Figure 9b should be used at the input to maintain electromagnetic shielding 11 Applications (Continued) TL H 7912 – 16 Bottom View FIGURE 9a IR Type Data Link R1 R2 R3 R5 C1 C2 C3 C4 C5 C6 C7 C8 T1 Load decoupling Sync timer R2 e t R2 s 470k 0 7 C6 Photodiode D1 Vactec Vactec UDT UDT Siemens VTS 5088 VTS 6089 PIN 6D or 6 DP PIN 220 DP BPY 12 Active Area (cm2) 0 18 0 52 0 20 20 0 20 Preamp decoupling Photodiode decoupling Photodiode decoupling VBIAS bypass V a bypass Load decoupling IF bypass optional tSYNC Sync timer C6 e C6 s 0 5 mF 0 7 R2 Preamp decoupling AGC 455 kHz Toko 10 Pin 1–2 Pin 1–3 455 kHz Toko 10 Pin 1–2 Pin 1–3 455 kHz Toko 10 Pin 1–2 Pin 1–3 preamp transformer EZC type (RMC-502182) Qu e 110 82T pin 2–3 82T 164T pin 4-6 30T IF transformer EZC type (RMC-402503) Qu e 110 98T pin 2–3 66T 164T pin 4–6 8T input transformer EZC type (RMC-202313) Qu e 110 131T pin 2–3 33T 164T pin 4–6 5T T2 T3 TL H 7912 – 17 D1 PN or PIN Silicon Photodiode FIGURE 9b Input Stage Where the Case of D1 is Connected to the Anode 12 Applications (Continued) EXPANSION TO FOUR ANALOG CHANNELS For those applications that require more than the two analog channels that are normally provided the LM1872 can easily be expanded to 4 channels with appropriate external circuitry This is accomplished by creating a pseudo-sync pulse (tps) among a six channel transmitted frame from the LM1871 (Figure 10) The pseudo-sync pulse deceives the decoder in the LM1872 causing premature recognition of end-of-frame effectively splitting a single frame into two The idea is to transmit analog channels 1 and 2 in the first half of the normal frame period and analog channels 3 and 4 in the second half External logic will then steer the four channels from the LM1872’s only two analog output pins into four new analog outputs Steering is accomplished with the help of one of the digital channels Inasmuch as the digital channels respond only to the number of pulses received between any two sync (or pseudo-sync ) pulses the channels are capable of toggling in step with the alternating transmission of two and three channel pulse mini-groups occurring within each half frame Figure 10a reveals that both digital channels A and B are high during the dual pulse half frame and low during its triple pulse counterpart Figure 10b shows just how simple the external circuitry can be Digital channel B drives the channel select pin of a quad 2input MUX that routes the LM1872 channels 1 and 2 outputs to the four new outputs labeled analog 1 through 4 Although not the model of simplicity of Figure 10b Figure 10c is a lower cost alternative that works just as well The diodes with the asterisk prevent a ground step from occurring that could false trip an excessively edge sensitive servo and can be eliminated in many cases TL H 7912 – 18 a) Transmitter Receiver and Auxiliary Decoder Timing Diagram FIGURE 10 Deriving Four Analog Channels Through the Use of an Auxiliary Decoder 13 Applications (Continued) TL H 7912 – 19 b) Simple Decoding of Four Analog Channels with CMOS See Text c) Low-Cost Decoding of Four Analog Channels with DTL TL H 7912 – 20 FIGURE 10 Deriving Four Analog Channels Through the Use of an Auxiliary Decoder (Continued) FOUR SINGLE CHANNEL RECEIVERS DRIVEN FROM A SINGLE TRANSMITTER When it is desired to control more than two vehicles or remote stations with the analog information from a single transmitter the LM1872 can be put to the task By utilizing the frame splitting technique previously described in Figure 10 up to four independent single analog channel receivers can be made to operate from a single transmitter (Figure 11) Toggling digital channel A either directly or through an inversion is used to suppress a given receiver’s analog output when the undesired analog channels are transmitted In this manner only the desired analog channel is outputted at each receiver The amount of external circuitry required to do this is minimal two receivers require a single transistor apiece while the other two receivers need no extra parts at all 14 Applications (Continued) TL H 7912 – 21 a) Transmitter Receiver and Separated Channels Timing Diagram TL H 7912 – 22 b) Simple Channel Separation with Two External Transistors FIGURE 11 Obtaining Four Independent Single Analog Channel Receivers from a Single Common Transmitter 15 Applications (Continued) EXPANSION TO SIX ANALOG CHANNELS Still greater analog capacity can be obtained with an outboard auxiliary decoder The LM1872 a simple comparator and an 8-bit parallel-out serial shift register comprise a six analog channel receiver decoder (Figure 12) The one transistor comparator reconstructs the detector output of the LM1872 from the sync timer waveform and feeds it to the clock input of the shift register The channel 1 output then loads a ‘‘one’’ into the register and the clock shifts the ‘‘one’’ down the line of analog channel outputs in accordance with the time information from the detector output Note that the reconstructed detector waveform lags the channel 1 output very slightly ( j 10 ms) due to the finite slope of the sync capacitor discharge edge This delay is very important as it insures that channel 1 is high when the clock strikes initially (thus loading a ‘‘1’’) and low for each subsequent positive clock edge (thus preventing the loading of extraneous ‘‘1’s’’) CONVERTING AN ANALOG CHANNEL TO A DIGITAL CHANNEL Either analog channel can be converted to a digital channel with the aid of a low cost CMOS hex inverter (Figure 13) The internal 10k resistor and external capacitor C1 set a time constant (1 ms) that falls between a short (0 5 ms) and a long (2 ms) transmitted pulse option For pulses longer than 1 ms the first inverter will pull low momentarily once each frame Repetitive discharges of C2 prevent it from ever reaching threshold (V a 2) because the R1 C2 time constant is set longer (70 ms) than the frame period With the inverter input below threshold Q1 will energize the load For analog output pulses shorter than 1 ms the first inverter will back bias D1 allowing C2 to ramp past threshold and Q1 to go off For extra output drive the remaining inverters in the package can be paralleled to drive Q1 Alternatively for light loads Q1 can be eliminated altogether TL H 7912 – 23 a) Six Channel Timing Diagram TL H 7912 – 24 b) Six Channel Auxiliary Decoder FIGURE 12 Deriving Six Analog Channels 16 Applications (Continued) Where only one of the two available analog channels needs conversion to a digital format the LM555 approach offers simplicity combined with up to 150 mA of output drive (Figure 14) The trailing edge of CH 1’s output pulse is used to reset the timer in preparation for comparing CH 2’s pulse width to the time constant (1 1 ms) set by the internal 10k resistor and C1 For CH 2 pulse widths greater than 1 1 ms C1 ramps to threshold setting an internal latch in the LM555 and causing the load to be energized Due to the timing of the reset pulse however the LM555 output will go high again for 1 1 ms during the next pulse comparison cycle thus producing an ON state duty cycle of about 95% For most commonly encountered loads such as motors solenoids lamps and horns this is of little consequence The OFF state duty cycle is 100% TL H 7912 – 25 FIGURE 13 Conversion of an Analog Channel to a Digital (On Off) Channel TL H 7912 – 26 FIGURE 14 Simple Conversion of an Analog to a Digital Channel 17 Applications (Continued) BRIDGE DRIVING A MOTOR The two digital channels can be used to propel a car forward off and reverse without the need for a costly servo (Figure 16) The 100 mA digital output capability is used to drive a bridge of four transistors with Q5 added as a protection device Should an erroneous command to power both sides of the bridge occur (as may happen due to noise with the car out of range) the large motor drive transistors would fight one another resulting in the thermal destruction of one or more of those devices But Q5 will disable the left side of the bridge whenever the right side is powered preventing the problem from ever occurring The motor noise suppression network shown has proven to be especially effective in reducing electrical noise and is therefore highly recommended NOISE INTEGRATION OF A DIGITAL CHANNEL Commonly available inexpensive DC motors are a formidable source of electromagnetic interference Radiation can come from the power feed leads and or directly from the brushes Usually proper lead dress and board orientation coupled with a good filter network (see Figure 16 ) will eliminate any problems In particularly stubborn cases of motor interference the digital channels may experience more objectionable interference than the analog channels This is generally not because the digital channels are more susceptible but rather because the type of load they typically drive (i e a horn) will make more of a nuisance of itself than a typical analog load (i e a steering servo) when subjected to interference Straightforward time integration of the digital channel outputs works very well with any type or degree of motor interference The simple circuits of Figure 17 integrate over a period of about three frames (70 ms) and have approximately equal delay either going off or coming on TL H 7912 – 27 FIGURE 15 Interfacing Directly to Standard Hobby Servos 18 Applications (Continued) TL H 7912 – 28 FIGURE 16 Digital Bridge Motor Drive TL H 7912 – 29 a) Low Current Load b) High Current Load FIGURE 17 Integrating a Digital Channel Output to Achieve Noise Immunity 19 LM1872 Radio Control Receiver Decoder Physical Dimensions inches (millimeters) Molded Dual-In-Line Package (N) Order Number LM1872N NS Package Number N18A LIFE SUPPORT POLICY NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF NATIONAL SEMICONDUCTOR CORPORATION As used herein 1 Life support devices or systems are devices or systems which (a) are intended for surgical implant into the body or (b) support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in a significant injury to the user National Semiconductor Corporation 1111 West Bardin Road Arlington TX 76017 Tel 1(800) 272-9959 Fax 1(800) 737-7018 2 A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness National Semiconductor Europe Fax (a49) 0-180-530 85 86 Email cnjwge tevm2 nsc com Deutsch Tel (a49) 0-180-530 85 85 English Tel (a49) 0-180-532 78 32 Fran ais Tel (a49) 0-180-532 93 58 Italiano Tel (a49) 0-180-534 16 80 National Semiconductor Hong Kong Ltd 13th Floor Straight Block Ocean Centre 5 Canton Rd Tsimshatsui Kowloon Hong Kong Tel (852) 2737-1600 Fax (852) 2736-9960 National Semiconductor Japan Ltd Tel 81-043-299-2309 Fax 81-043-299-2408 National does not assume any responsibility for use of any circuitry described no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications
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