IRAUDAMP5

IRAUDAMP5 120W x 2 Channel Class D Audio Power Amplifier Using the IRS2092S and IRF6645 By Jun Honda, Manuel Rodríguez and Jorge Cerezo Fig 1 CAUTION: International Rectifier suggests the following guidelines for safe operation and handling of IRAUDAMP5 Demo Board; • Always wear safety glasses whenever operating Demo Board • Avoid personal contact with exposed metal surfaces when operating Demo Board • Turn off Demo Board when placing or removing measurement probes www.irf.com IRAUDAMP5 REV 3.0 Table of Contents Page Introduction………………………………………………………………….. Specifications………………………………………………………………… Connection Setup……………………………………………………….…… Test Procedure………………………………………………………………... Typical Performance…………………………………………………………. Theory of Operation…………………………………………………………. IRS2092S System Overview………………………………………………… Selectable Dead Time………………………………………………………… Protection Features…………………………………………………………… Efficiency…………………………………………………………………….. Thermal Considerations……………………………………………………… Click and Pop Noise Control…………………………………………………. Startup and Shutdown Sequencing…………………………………………… PSRR…………………………………………………………………………. Bus Pumping………………………………………………………………….. Input/Output Signal and Volume Control……………………………………. Self Oscillating PWM Modulator…………………………………………….. Switches and Indicators………………………………………………………. Frequency Lock, Synchronization Feature…………………………………… Schematics……………………………………………………………………. Bill of Materials……………………………………………………………… PCB specifications……………………………………………………………. Assembly Drawings…………………………………………………………... END…………………………………………………………………………... 2 3 4 5 5-9 9-10 10-11 11-12 12-17 17-18 18 18-19 19-21 21-22 22-23 23-26 27 28 29 32-36 37-40 42 43-49 49 Hardware……………………………………………………………………… 41 www.irf.com IRAUDAMP5 REV 3.0 Page 1 of 49 Introduction The IRAUDAMP5 reference design is a two-channel, 120W half-bridge Class D audio power amplifier. This reference design demonstrates how to use the IRS2092S Class D audio controller and gate driver IC, implement protection circuits, and design an optimum PCB layout using the IRF6645 DirectFET MOSFETs. The resulting design requires no heatsink for normal operation (one-eighth of continuous rated power). The reference design provides all the required housekeeping power supplies for ease of use. The two-channel design is scalable for power and the number of channels. Applications AV receivers Home theater systems Mini component stereos Powered speakers Sub-woofers Musical Instrument amplifiers Automotive after market amplifiers Features Output Power: Residual Noise: Distortion: Efficiency: Multiple Protection Features: 120W x 2 channels, Total Harmonic Distortion (THD+N) = 1%, 1 kHz 170µV, IHF-A weighted, AES-17 filter 0.005% THD+N @ 60W, 4Ω 96% @ 120W, 4Ω, single-channel driven, Class D stage Over-current protection (OCP), high side and low side Over-voltage protection (OVP), Under-voltage protection (UVP), high side and low side DC-protection (DCP), Over-temperature protection (OTP) Self-oscillating half-bridge topology with optional clock synchronization PWM Modulator: www.irf.com IRAUDAMP5 REV 3.0 Page 2 of 49 Specifications General Test Conditions (unless otherwise noted) Supply Voltage ±35V Load Impedance 8-4Ω Self-Oscillating Frequency 400kHz Gain Setting 26dB Electrical Data IR Devices Used Notes / Conditions No input signal, Adjustable 1Vrms input yields rated power Typical Notes / Conditions IRS2092S Audio Controller and Gate-Driver, IRF6645 DirectFET MOSFETs Modulator Self-oscillating, second order sigma-delta modulation, analog input Power Supply Range ± 25V to ±35V Bipolar power supply Output Power CH1-2: (1% THD+N) 120W 1kHz Output Power CH1-2: (10% THD+N) 170W 1kHz Rated Load Impedance 8-4Ω Resistive load Standby Supply Current ±100mA No input signal Total Idle Power Consumption 7W No input signal Channel Efficiency 96% Single-channel driven, 120W, Class D stage . Audio Performance THD+N, 1W THD+N, 10W THD+N, 60W THD+N, 100W Dynamic Range Residual Noise, 22Hz - 20kHzAES17 Damping Factor Channel Separation Frequency Response : 20Hz-20kHz : 20Hz-35kHz *Before Demodulator 0.009% 0.003% 0.003% 0.008% 101dB 170µV 2000 95dB 85dB 75dB N/A Class D Output 0.01% 0.004% 0.005% 0.010% 101dB 170µV 170 90dB 80dB 65dB ±1dB ±3dB Notes / Conditions 1kHz, Single-channel driven A-weighted, AES-17 filter, Single-channel operation Self-oscillating – 400kHz 1kHz, relative to 4Ω load 100Hz 1kHz 10kHz 1W, 4Ω - 8Ω Load Thermal Performance Idling 2ch x 15W (1/8 rated power) 2ch x 120W (Rated power) Physical Specifications Dimensions TC =30°C TPCB=37°C TC =54°C TPCB=67°C TC =80°C TPCB=106°C Typical No signal input, TA=25°C Continuous, TA=25°C Notes / Conditions At OTP shutdown @ 150 sec, TA=25°C 5.8”(L) x 5.2”(W) www.irf.com IRAUDAMP5 REV 3.0 Page 3 of 49 Note: Class D Specifications are typical *Before demodulator refers to audio performance measurements of the Class D output power stage only, with preamp and output filter bypassed this means performance measured before the low pass filter. Connection Setup 35V, 5A DC supply 35V, 5A DC supply 250W, Non-inductive Resistors 4 Ohm J3 G J7 TP1 TP2 4 Ohm J4 CH1 Output LED CH2 Output S1 J9 Protection J6 J5 J8 S3 Volume Normal CH1 Input CH2 Input S2 R113 Audio Signal Generator Typical Test Setup Fig 2 Connector Description CH1 IN CH2 IN POWER CH1 OUT CH2 OUT EXT CLK DCP OUT J6 J5 J7 J3 J4 J8 J9 Analog input for CH1 Analog input for CH2 Positive and negative supply (+B / -B) Output for CH1 Output for CH2 External clock sync DC protection relay output www.irf.com IRAUDAMP5 REV 3.0 Page 4 of 49 Test Procedures 1. Connect 4Ω, 250W load to both output connectors, J3 and J4 and Audio Precision analyzer (AP). 2. Connect Audio Signal Generator to J6 and J5 for CH1 and CH2 respectively (AP). 3. Connect a dual power supply to J7, pre-adjusted to ±35V, as shown in Figure 2 above. 4. Set switch S3 to middle position (self oscillating). 5. Set volume level knob R108 fully counter-clockwise (minimum volume). 6. Turn on the power supply. Note: always apply or remove the ±35V at the same time. 7. Orange LED (Protection) should turn on almost immediately and turn off after about 3s. 8. Green LED (Normal) then turns on after orange LED is extinguished and should stay on. 9. One second after the green LED turns on; the two blue LEDS on the Daughter Board should turn on and stay on for each channel, indicating that a PWM signal is present at LO 10. With an Oscilloscope, monitor switching waveform at test points TP1 and TP2 of CH1 and CH2 on Daughter Board. 11. If necessary, adjust the self-oscillating switching frequency of AUDAMP5 to 400KHz ±5kHz using potentiometer R29P. For IRAUDAMP5, the self-oscillating switching frequency is pre-calibrated to 400KHz. To modify the AUDAMP5 frequency, change the values of potentiometers R21 and R22 for CH1 and CH2 respectively. 12. Quiescent current for the positive supply should be 70mA ±10mA at +35V. 13. Quiescent current for the negative supply should be 100mA ±10mA at –35V. 14. Push S1 switch, (Trip and Reset push-button) to restart the sequence of LEDs indicators, which should be the same as noted above in steps 6-9. Audio Tests: 15. Apply 1 V RMS at 1KHz from the Audio Signal Generator 16. Turn control volume up (R108 clock-wise) to obtain an output reading of 100Watts for all subsequent tests as shown on the Audio Precision graphs below, where measurements are across J3 and J2 with an AES-17 Filter Typical Performance The tests below were performed under the following conditions: ±B supply = ±35V, load impedance = 4Ω resistive load, 1kHz audio signal, Self oscillator @ 400kHz and internal volume-control set to give required output with 1Vrms input signal, with AES-17 Filter, unless otherwise noted. www.irf.com IRAUDAMP5 REV 3.0 Page 5 of 49 THD versus Power: 10 5 2 1 0. 5 0. 2 % 0. 1 0. 05 0. 02 0. 01 0.005 0.002 0.001 100m 200m 500m 1 2 5 W 10 20 50 100 200 Blue, CH1 - 4 Ohm Red, CH2 - 4 Ohm Figure 18. Total Harmonics Distortion + Noise (THD+N) versus power output Fig 3 +4 +3 +2 +1 -0 -1 d B r A -2 -3 -4 -5 -6 -7 -8 -9 -10 20 50 100 200 500 1k 2k Hz 5k 10k 20k 50k 100k 200k Frequency Response: Red Blue CH1 - 4 Ohm, 2V Output CH1 - 8 Ohm, 2V Output Frequency Characteristics vs. Load Impedance Fig 4 www.irf.com IRAUDAMP5 REV 3.0 Page 6 of 49 . THD versus Frequency: 100 50 10 5 1 % 0.1 0.05 0.01 0.001 0.0005 0.0001 20 50 100 200 500 Hz 1k 2k 5k 10k 20k Pink Blue Cyan Green CH1, 1W Output CH1, 10W Output CH1, 50W Output CH1, 100W Output THD+N Ratio vs. Frequency Fig 5 . Frequency Spectrum : +0 -10 -20 -30 -40 d B V -50 -60 -70 -80 -90 -100 -110 10 20 50 100 200 500 Hz 1k 2k 5k 10k 20k Red Blue CH1, 1V, 1kHz, Self Oscillator @ 400kHz CH2, 1V, 1kHz, Self Oscillator @ 400kHz Fig 6 Frequency Spectrum www.irf.com IRAUDAMP5 REV 3.0 Page 7 of 49 . Floor Noise: +20 +0 -20 -40 d B V -60 -80 -100 -120 -140 10 20 50 100 200 500 Hz 1k 2k 5k 10k 20k Red Blue CH1 - ACD, No signal, Self Oscillator @ 400kHz CH2 - ACD, No signal, Self Oscillator @ 400kHz Fig 7 Residual Noise (ACD) . Channel Separation: +0 -10 -20 -30 -40 -50 d B -60 -70 -80 -90 -100 -110 -120 20 50 100 200 500 Hz 1k 2k 5k 10k 20k Red Blue CH1 – CH2, 60W CH2 – CH1, 60W Fig 8 Channel Separation vs. Frequency www.irf.com IRAUDAMP5 REV 3.0 Page 8 of 49 . Clipping Characteristics: Red Trace: Total Distortion + Noise Voltage Green Trace: Output Voltage 60W / 4Ω, 1kHz, THD+N=0.008% 174W / 4Ω, 1kHz, THD+N=10% Measured Output and Distortion Waveforms Fig 9 . IRAUDAMP5 Theory of Operation Referring to Fig 10 below, the input error amplifier of the IRS2092S forms a front-end secondorder integrator with C1, C21, C23 and R21. This integrator also receives a rectangular feedback waveform from R31, R33 and C17 into the summing node at IN- from the Class D power stage switching node (connection of DirectFET Q3 and DirectFET Q4). The quadratic oscillatory waveform of the switch node serves as a powered carrier signal from which the audio is recovered at the speaker load through a single-stage LC filter. The modulated signal is created by the fluctuations of the analog input signal at R13 that shifts the average value of this quadratic waveform through the gain relationship between R13 and R31 + R33 so that the duty cycle varies according to the instantaneous signal level of the analog input signal at R13. R33 and C17 act to immunize the rectangular waveform from possible narrow noise spikes that may be created by parasitic impedances on the power output stage. The IRS2092S input integrator then processes the signal from the summing node to create the required triangle wave amplitude at the COMP output. The triangle wave then is converted to Pulse Width Modulation, or PWM, signals that are internally level-shifted Down and Up to the negative and positive supply rails. The level shifted PWM signals are called LO for low output, and HO for high output, and have opposite polarity. A programmable amount of dead time is added between the gate signals to avoid cross conduction between the power MOSFETs. The IRS2092S drives two IRF6645 DirectFET MOSFETs in the power stage to provide the amplified PWM waveform. The amplified analog output is reconstructed by demodulating the powered PWM at the switch node, called VS. (Show as VS on the schematic)This is done by means of the LC low-pass filter (LPF) formed by L1 and C23A, which filters out the Class D switching carrier signal, leaving the audio powered output at the speaker load. A single stage output filter can be used with switching www.irf.com IRAUDAMP5 REV 3.0 Page 9 of 49 frequencies of 400 kHz and greater; lower switching frequencies may require additional filter components. +VCC is referenced to –B and provides the supply voltage to the LO gate driver. D6 and C5 form a bootstrap supply that provides a floating voltage to the HO gate driver. The VAA and VSS input supplies are derived from +B and -B via R52 and C18, and R50 and C12, respectively. Thus, a fully functional Class D PWM amplifier plus driver circuit is realized in an SO16 package with just a few small components. . R31 C17 R33 R52 C18 +B 0V C21 R21 C23 +VAA IRS2092S VB HO Modulator and Shift level Integrator C5 R32 DirectFet Q3 IRF6645 0V COMP C1 0V INPUT R13 INGND LP Filter D6 L1 Q4 IRF6645 C23A 0V + VS VCC LO . R30 . DirectFet C3 -VSS C12 R50 COM +VCC -B . Simplified Block Diagram of IRAUDAMP5 Class D Amplifier Fig 10 System overview IRS2092S Gate Driver IC The IRAUDAMP5 uses the IRS2092S, a high-voltage (up to 200V), high-speed power MOSFET PWM generator and gate driver with internal dead-time and protection functions specifically designed for Class D audio amplifier applications. These functions include OCP and UVP. Bidirectional current protection for both the high-side and low-side MOSFETs are internal to the IRS2092S, and the trip levels for both MOSFETs can be set independently. In this design, the dead time can be selected for optimized performance by minimizing dead time while preventing shoot-through. As a result, there is no gate-timing adjustment on the board. Selectable dead time through the DT pin voltage is an easy and reliable function which requires only two external resistors, R11 and R9 as shown on Fig11 below. www.irf.com IRAUDAMP5 REV 3.0 Page 10 of 49 . +B VAA GND IN- CSH VB HO VS VCC LO COM DT R13 R5 . AUDIO_INPUT COMP . Feedback CSD VSS R19 CH1 VREF CSLO +VCC -B R18 IRS2092S . System-level View of Class D Controller and Gate Driver IRS2092S Fig 11 Selectable Dead-Time The dead time of the IRS2092S is based on the voltage applied to the DT pin. (Fig 12) An internal comparator determines the programmed dead time by comparing the voltage at the DT pin with internal reference voltages. An internal resistive voltage divider based on different ratios of VCC negates the need for a precise reference voltage and sets threshold voltages for each of the four programmable settings. Shown in the table below are component values for programmable dead times between 15 and 45 ns. To avoid drift from the input bias current of the DT pin, a bias current of greater than 0.5mA is suggested for the external resistor divider circuit. Resistors with up to 5% tolerance can be used. Selectable Dead-Time Dead-time mode DT1 DT2 DT3 DT4 Dead time ~15ns ~25ns ~35ns ~45ns Operational Mode R5 3.3k 5.6k 8.2k open R13 8.2k 4.7k 3.3k 40V) or too low (11dB overdrive. +5V +5V C107 4.7uF, 16V R108 CT2265-ND 8 7 6 C108 10nF, 50V 5 VSS VR0 VR1 CLK U_2 VDD CS SDATA SIMUL 1 2 CS 3 SDATAI 4 +5V 10uF, 50V SCLK R10 R7 R8 47R CS 47R SDATAI AOUTL 10R C1 VD+ DGRD SCLK 47R MUTE R11 47R VAVA+ AOUTR -5V +5V Level OUT 2 R2 R4 100R 100K R9 AGNDL Level OUT 1 4.7uF, 16V U_1 ZCEN AINL R3 100R 100K R1 C109 Audio in J5 3310S06S Control Volume SDATAOAGNDR MUTE CS3310 AINR Audio in J6 Fig 26 Digital volume Control www.irf.com IRAUDAMP5 REV 3.0 Page 23 of 49 Bridged Output The IRAUDAMP5 is not intended for a bridge-tied-load, or BTL configuration. However, BTL operation can be achieved by feeding out-of-phase audio input signals to the two input channels as shown in the figure 27 below. In BTL operation, minimum load impedance is 8 Ohms and rated power is 240W non-clipping. The installed clamping diodes D5 – D8 are required for BTL operation, since reactive energy flowing from one output to the other during clipping can force the output voltage beyond the voltage supply rails if not clamped. . R31 C17 R33 +VAA +B C21 R21 C23 COMP C1 IRS2092S VB HO 0V Q3 IRF6645 . INPUT + VS L1 CH1 10k 1% GND VCC LO Integrator . R32 C18 R34 Q4 IRF6645 D7 D5 R13 IN- LP Filter Modulator and Shift level +B -B 10k 1% COM 1 -B . +VAA +B C22 C24 COMP C2 IRS2092S VB HO 0V Q6 IRF6645 . + VS L2 CH2 GND VCC LO Integrator Q5 IRF6645 D8 D6 R14 IN- LP Filter Modulator and Shift level +B -B COM -B Bridged configuration Fig 27 Output Filter Design, Preamplifier and Performance The audio performance of IRAUDAMP5 depends on a number of different factors. The section entitled, “Typical Performance” presents performance measurements based on the overall system, including the preamp and output filter. While the preamp and output filter are not part of the Class D power stage, they have a significant effect on the overall performance. Output filter Since the output filter is not included in the control loop of the IRAUDAMP5, the reference design cannot compensate for performance deterioration due to the output filter. Therefore, it is important to understand what characteristics are preferable when designing the output filter: www.irf.com IRAUDAMP5 REV 3.0 Page 24 of 49 1) The DC resistance of the inductor should be minimized to 20 mOhms or less. 2) The linearity of the output inductor and capacitor should be high with respect to load current and voltage. Preamplifier (Fig 28) The preamp allows partial gain of the input signal, and controls the volume in the IRAUDAMP5. The preamp itself will add distortion and noise to the input signal, resulting in a gain through the Class D output stage and appearing at the output. Even a few micro-volts of noise can add significantly to the output noise of the overall amplifier. R13 C5 10uF, 50V IN-1 Feedback R31 R33 1K C17 150pF, 500V OC -5V Audio in R1 J5 U_? 1 2 3 4 5 6 7 8 100K AINL AGNDL 16 15 14 13 12 11 10 9 R4 100R R72 OPEN R3 100R R71 OPEN 3.3K R55 0.0 CH1 IN 4 5 6 J1A 1 2 3 47k 1% ZCEN CS +5V SDATAI AOUTL VD+ DGRD SCLK VAVA+ AOUTR C2 10uF, 50V R5 4.7R 4.7R R6 C3 10uF, 50V C6 10uF, 50V -5V -5V +5V IRS2092S MODULE J1B 7 8 9 10 11 12 VCC SD SDATAOAGNDR MUTE CS3310 R2 100K J6 AINR R14 3.3K CH2 IN IN-2 R56 0.0 VCC Feedback R32 47k 1% R34 1K Audio in Preamplifier Fig28 It is possible to evaluate the performance without the preamp and volume control, by moving resistors R13 and R14 to R71 and R72, respectively. This effectively bypasses the preamp and connects the RCA inputs directly to the Class D power stage input. Improving the selection of preamp and/or output filter components will improve the overall system performance, approaching that of the stand-alone Class D power stage. In the “Typical Performance” section, only limited data for the stand-alone Class D power stage is given. For example, Fig 20 below shows the results for THD+N vs. Output Power are provided, utilizing a range of different inductors. By changing the inductor and repeating this test, a designer can quickly evaluate a particular inductor. www.irf.com IRAUDAMP5 REV 3.0 Page 25 of 49 I IRAUDAMP5 can be used as output inductors evaluation tool 100 TTTTTTT 10 1 % 0.1 0.01 0.001 0.0001 100m 200m 500m 1 2 5 W 10 20 50 100 200 Results of THD+N vs. Output Power with Different Output Inductors Fig 29 Self-Oscillating PWM Modulator The IRAUDAMP5 Class D audio power amplifier features a self-oscillating type PWM modulator for the lowest component count, highest performance and robust design. This topology represents an analog version of a second-order sigma-delta modulation having a Class D switching stage inside the loop. The benefit of the sigma-delta modulation, in comparison to the carrier-signal based modulation, is that all the error in the audible frequency range is shifted to the inaudible upper-frequency range by nature of its operation. Also, sigma-delta modulation allows a designer to apply a sufficient amount of correction. The self-oscillating frequency (Fig 30) is determined by the total delay time inside the control loop of the system. The delay of the logic circuits, the IRS2092S gate-driver propagation delay, the IRF6645 switching speed, the time-constant of front-end integrator (e.g.R13, R33, R31, R21, P1, C17, C21, C23 and C1 for CH1) and variations in the supply voltages are critical factors of the self-oscillating frequency. Under nominal conditions, the switching-frequency is around 400kHz with no audio input signal and a +/-35V supply. www.irf.com IRAUDAMP5 REV 3.0 Page 26 of 49 . R31 C17 P1 R33 C21 R21 C23 +B COMP C1 IRS2092S VB HO 0V Q3 IRF6645 . INPUT R13 INCH1 GND LP Filter + Modulator and Shift level Integrator VS VCC LO COM Q4 IRF6645 . -B Self Oscillating determined components Fig 30 Adjustments of Self-Oscillating Frequency The PWM switching frequency in this type of self-oscillating switching scheme greatly impacts the audio performance, both in absolute frequency and frequency relative to the other channels. In absolute terms, at higher frequencies distortion due to switching-time becomes significant, while at lower frequencies, the bandwidth of the amplifier suffers. In relative terms, interference between channels is most significant if the relative frequency difference is within the audible range. Normally, when adjusting the self-oscillating frequency of the different channels, it is best to either match the frequencies accurately, or have them separated by at least 25kHz. With the installed components, it is possible to change the self-oscillating frequency from about 300kHz up to 450kHz, as shown on Fig 30 Switches and Indicators There are four different indicators on the reference design as shown in the figure 31 below: 1. An orange LED, signifying a fault / shutdown condition when lit. 2. A green LED on the motherboard, signifying conditions are normal and no fault condition is present. 3. A blue LED on the daughter board module, signifying there are HO pulses for CH1 4. A blue LED on the daughter board module signifying there are HO pulses for CH2 There are three switches on the reference design: 1. Switch S1 is a trip and reset push-button. Pushing this button has the same effect as a fault condition. The circuit will restart about three seconds after the shutdown button is released. 2. Switch S2 is an internal clock-sync frequency selector. This feature allows the designer to modify the switching frequency in order to avoid AM radio interference. With S3 set to INT, the two settings “H” and “L” will modify the internal clock frequency by about www.irf.com IRAUDAMP5 REV 3.0 Page 27 of 49 20 kHz to 40 kHz, either higher “H” or lower “L.” The actual internal frequency is set by potentiometer R113 - “INT FREQ.” 3. Switch S3 is an oscillator selector. This three-position switch is selectable for internal self oscillator (middle position – “SELF”), or either internal (“INT”) or external (“EXT”) clock synchronization. SW-3WAY_A-B S3A I E S S2 1 2 SW R109 1K D103 1N4148 C110 1nF, 50V R110 100k R111 10K SW_H-L C112 1200pF, 50V 100pF, 50V C111 +5V R120 100R R112 820R Q103 C113 100pF, 50V U_3 1A 1Y VCC 6A 6Y 5A 5Y 4A 4Y C114 10nF, 50V MMBT5551 R113 5K POT 2A 2Y 3A 3Y SW-3WAY_A-B S3B SW S E I R114 100R J8 BNC A24497 R116 47R CLK CLK GND 74HC14 +5V R118 1k R119 1k PROTECTION NORMAL R115 47R EXT. CLK MUTE MUTE R117 47R LED, Switches and Sync frequencies Fig 31 Switching Frequency Lock / Synchronization Feature For single-channel operation, the use of the self-oscillating switching scheme will yield the best audio performance. The self-oscillating frequency, however, changes with the duty ratio. This varying frequency can interfere with AM radio broadcasts, where a constant-switching frequency with its harmonics shifted away from the AM carrier frequency is preferred. In addition to AM broadcasts, multiple channels can also reduce audio performance at low power, and can lead to increased residual noise. Clock frequency locking/synchronization can address these unwanted characteristics. Please note that the switching frequency lock / synchronization feature is not possible for all frequencies and duty ratios, and operates within a limited frequency and duty-ratio range around the self-oscillating frequency (Figure 32 below). www.irf.com IRAUDAMP5 REV 3.0 Page 28 of 49 600 Locking range 500 Suggested clock frequency for maximum locking range Self-oscillating frequency Operating Frequency (kHz) 400 300 200 Self-oscillating frequency 100 0 10% 20% 30% 40% 50% 60% 70% 80% 90% Duty Cycle Typical Lock Frequency Range vs. PWM Duty Ratio (Self-oscillating frequency set to 400 kHz with no input) Fig 32 The output power range, for which frequency-locking is successful, depends on what the locking frequency is with respect to the self-oscillating frequency. As illustrated in Figure 33, the locking frequency is lowered (from 450kHz to 400kHz to 350kHz and then 300kHz) as the output power range (where locking is achieved) is extended. Once locking is lost, however, the audio performance degrades, but the increase in THD seems independent from the clock frequency. Therefore, a 300 kHz clock frequency is recommended, as shown on Fig 34 It is possible to improve the THD performance by increasing the corner frequency of the high pass filter (HPF) (R17 and C15 for Ch1 Fig 33) that is used to inject the clock signal, as shown in Figure 33 below. This drop in THD, however, comes at the cost of reducing the locking range. Resistor values of up to 100 kOhms and capacitor values down to 10pF may be used. . +VAA +B C15 SYNC R22 22k R13 COMP IRS2092S VB HO 0V Q3 IRF6645 33pF 0V . INPUT INCH1 GND LP Filter + Modulator and Shift level Integrator VS VCC LO Q4 IRF6645 . COM -B Switching Frequency Lock / Synchronization Feature Fig 33 www.irf.com IRAUDAMP5 REV 3.0 Page 29 of 49 In IRAUDAMP5, this switching frequency lock/synchronization feature (Fig 31 and Fig 33) is achieved with either an internal or external clock input (selectable through S3). If an internal (INT) clock is selected, an internally-generated clock signal is used, adjusted by setting potentiometer R113 “INT FREQ.” If external (EXT) clock signal is selected, a 0-5V squarewave (~50% duty ratio) logic signal must be applied to BNC connector J17. 10 5 2 1 0. 5 0. 2 % 0. 1 0. 05 0. 02 0. 01 0. 005 0. 002 0. 001 100m 200m 500m 1 2 5 W 10 20 50 100 200 Red Pink Blue Cyan CH1, = Self Oscillator @ 400kHz CH1, = Sync Oscillator @ 400kHz CH1, = Sync Oscillator @ 450kHz CH1, = Sync Oscillator @ 350kHz THD+N Ratio vs. Output Power for Different Switching Frequency Lock/Synchronization Conditions Fig 34 www.irf.com IRAUDAMP5 REV 3.0 Page 30 of 49 Class D, Daughter Board IRS2092S Module CH1 Schematic -B 100K Q7 100C R31 Rp1 Rp1 is thermally connected with Q3 +35V Bus OTP1 R40 33k -B R43 U1 D1 1 R21 P1 1K 1k 2 GND 22uF 3 INR32 4 COMP D6 5 CSD R26 4.7R VSS VREF OCSET IRS2092S 3.3K R13 8.2K 10uF DT 9 R5 COM 10 R9 10R C3 R12 4.7K DS1 LO 11 VCC VCC 10R R30 7 8 R50 open R17 1.2k 6 C12 R19 8.2k 3.3uF 12 2 2 D-FET2 IRF6645 1 3 3 R37 1R VS 13 HO 1nF,250V C30 10nF 1nF C21 10uF C23 1nF,250V C1 14 10R 1 3 3 VB 2 2 D-FET1 IRF6645 15 VAA 10k C5 R25 10K CSH 16 0.0 R41 100K 1K R47 R48 R52 open C18 OTP CH1 C28 47nF CH1 +5V Audio Gnd 1 3.3uF +35V Bus +B R7 VAA 10R C32 0.1uF,100V C17 0.1uF C14 0.1uF,100V TP1 CH1 O J2A GND1 J1A IN-1 OC R46 VSS 1 2 3 4 5 6 3.01k VAA CH1 +B A26568-ND SD C10 D4 R1 SD 9 10 11 12 13 14 15 16 A26570-ND 100R R3 VSS -5V 10R CH1 Output to LPF1 -35V Bus -B -35V Bus Drawing by: M.Rodriguez Mrodrig5@irf.com . www.irf.com IRAUDAMP5 REV 3.0 Page 31 of 49 Class D, Daughter Board IRS2092S Module CH2 Schematic OTP1 -B 100K MMBT5401 Q2 OTP2 R39 33k -B R44 U2 1 VAA GND 22uF 3 1nF,250V 1nF 4 COMP D5 5 CSD R23 4.7R VSS VREF OCSET IRS2092S 3.3K R14 8.2K DT 9 R6 COM 10 R10 10R C4 10uF LO 11 VCC 6 R20 7 8 R49 open D7 R18 1.2k 8.2k 12 VCC 10R R28 2 2 D-FET4 IRF6645 1 3 3 R38 1R VS 13 C22 10uF C24 1nF,1250V C2 R27 INHO 14 10R 1 3 3 2 2 VB 15 10k C6 R29 10K D-FET3 IRF6645 CSH R22 P2 1K 1k SD 16 0.0 R42 D2 C33 0.1uF,100V C13 0.1uF C15 0.1uF,100V TP2 CH2 O J2B 100K 1K R33 R24 C9 47nF 100C R11 100K OTP2 R35 Rp2 Rp2 is thermally connected with Q5 OC Q1 R34 100K +35V Bus R36 10K C19 -B 3.3uF C29 47nF R51 open MMBT5551 OTP CH2 +35V Bus +B VAA R8 +5V Audio Gnd 2 2 10R J1B PWM2 VSS 7 8 9 C31 10nF,50V 10 11 12 VCC A26568-ND IN-2 3.01k R53 CH2 -B SD D3 R2 SD C11 C16 3.3uF 1 2 3 4 5 6 7 8 A26570-ND VSS 100R R4 -5V 10R CH2 Output to LPF2 -35V Bus -B R45 4.7K DS2 CH2 -35V Bus Drawing by: M.Rodriguez Mrodrig5@irf.com . www.irf.com IRAUDAMP5 REV 3.0 Page 32 of 49 Rp1 is thermally connected with Q3 -B 100K MMBT5401DICT-ND Q7 OTP1 R40 33k -B R43 U1 1 R21 P1 1K 2 GND 22uF 3 INCOMP D6 5 CSD R26 2 2 4.7R 10R 1 3 3 R30 7 VREF OCSET IRS2092S C3 10uF Rp2 is thermally connected with Q5 OC -B R34 100K R11 100K OTP1 OTP2 R35 100K MMBT5401 Q2 OTP2 R39 33k R44 U2 1 VAA GND INCOMP CSD VSS 7 8 R49 open D7 R18 1.2k VREF OCSET IRS2092S HO VS VCC LO COM DT 14 13 12 11 10 9 R6 3.3K R14 R10 10R C4 8.2K R45 4.7K DS2 D5 R23 4.7R 6 C16 R20 8.2k 3.3uF VCC 10R R28 VB 15 CSH R22 P2 1K 2 3 1nF,250V 1nF 4 5 C22 10uF C24 1nF,1250V C2 1k SD R53 3.01k C31 10nF,50V 16 D2 10k C6 22uF C33 0.1uF,100V 2 2 R29 10K 10R R27 D-FET3 IRF6645 1 3 3 C13 0.1uF C15 0.1uF,100V TP2 CH2 O J2B 0.0 R42 -B R33 100K R24 1K Rp2 100C DS1 3.3K R13 8.2K 10R 4.7K DT 9 R5 R9 R12 COM 8 R50 open R17 1.2k 10 R37 1R VSS LO 11 VCC 6 R19 8.2k 12 VCC D-FET2 IRF6645 VS 13 3 3 R32 4 TP1 CH1 O J2A HO 1nF,250V C30 10nF R1 1nF C21 10uF C23 1nF,250V C1 14 10R 1 2 2 C17 0.1uF C14 0.1uF,100V VB 15 R25 10K D-FET1 IRF6645 10k C5 1k VAA C32 0.1uF,100V CSH 16 0.0 R41 D1 100K 1K R47 R48 C28 47nF 100C R31 Rp1 Class D, Daughter Board IRS2092S Module Schematic +35V Bus R52 open C18 OTP CH1 CH1 R7 VAA 10R GND1 IN-1 R46 3.01k VAA D4 4 5 6 +35V Bus +B +5V 3.3uF Audio Gnd 1 J1A 1 2 3 OC VSS CH1 +B A26568-ND SD 100R R3 VSS 10R C12 3.3uF SD -5V C10 9 10 11 12 13 14 15 16 A26570-ND CH1 Output to LPF1 -35V Bus -B IR_Logo -35V Bus Q1 +35V Bus R36 10K C19 -B 3.3uF C29 47nF R51 open MMBT5551 OTP CH2 C9 47nF +35V Bus +B R8 VAA 10R VCC +5V J1B 10 11 12 IN-2 VSS GND2 7 8 9 Audio Gnd 2 SD -5V 10R 100R R4 C11 D3 R2 A26568-ND CH2 -B D-FET4 IRF6645 1 3 3 1 2 3 4 2 2 R38 1R 5 6 7 8 A26570-ND SD -5V CH2 Output to LPF2 -35V Bus -B CH2 -35V Bus 10uF Drawing by: M.Rodriguez Mrodrig5@irf.com www.irf.com IRAUDAMP5 REV 3.0 Page 33 of 49 . Class D, Mother Board Control Volume and Power Supplies Schematic C19 R39 470 C15 R17 +B L1 22uH R33 1K C17 150pF, 500V OC -5V +B 0.47uF, 400V C23 R47 10, 1W -B C25 0.1uF, 400V J7 +B CH1 O D5 D7 R49 2.2k 22k R13 3.3K 47k 1% R55 0.0 C5 10uF, 50V IN-1 R31 33pF +5V 2.2uF,16V CLK 47R 74AHC1G04 U3 R27 CH1 Feedback CH1 IN CH1 OUT C27 OPEN J3 1 2 Control Volume C109 R1 J5 4.7uF, 16V U_? 1 ZCEN CS SDATAI AOUTL VD+ DGRD SCLK SDATAOAGNDR MUTE CS3310 R2 3.3K VCC L2 R34 1K C18 150pF, 500V R18 22k CH2 O 22uH 100K R72 OPEN IN-2 R32 47k 1% R40 470 C16 33pF +5V J6 R4 100R R14 R56 0.0 AINR 9 C6 10uF, 50V -5V 10 7 8 9 10 11 12 VCC SD C3 10uF, 50V AOUTR 11 J1B R6 VA+ 12 +5V J2B -B 4.7R 4.7R VA13 -5V 14 C2 10uF, 50V R5 AGNDL 15 J1A J2A AINL R7 2 3 C1 10uF, 50V 6 47R 7 8 R11 47R 5 4 R8 10R 47R 47R 16 +5V 100K R3 100R 4 5 6 1 2 3 R71 OPEN +5V Audio in 9 10 11 12 13 14 15 16 + CH1 - +5V C107 4.7uF, 16V U_2 8 VSS VDD 1 R108 7 VR0 R9 CS 2 CS 6 VR1 SDATA 3 SDATAI C108 10nF, 50V 5 CLK SIMUL 4 +5V IRS2092S_ MODULE Trace under J7 R58 100K C33 OPEN 2 1 3 C31 1000uF,50V R57 100K +35V Gnd -35V 3310S06S SCLK R10 C34 OPEN 1 2 3 4 5 6 7 8 C32 1000uF,50V MUTE Chassis Gnd -B +B D6 C24 0.47uF, 400V R48 10, 1W -B C26 0.1uF, 400V D8 R50 2.2k CH2 IN CH2 Feedback Audio in C20 2.2uF,16V CLK 47R 74AHC1G04 U4 R28 CH2 OUT C28 OPEN J4 1 2 Drawing by: M.Rodriguez Mrodrig5@irf.com + CH2 - VCC UVP Z103 R107 15V 4.7K +B Q102 R106 47K R105 MMBT5401 10R Q101 FX941 VCC HS1 U_6 MC78M12 VCC Power Supply Heat Sink +B Z101 R101 4.7V 47R, 1W ZM4732ADICT +5V Power Supply R102 47R, 1W C101 U_4 Vin GND MC78M05 Vout +5V Z102 -B 4.7V R103 47R, 1W ZM4732ADICT D101 MA2YD2300 10uF, 50V C102 10uF, 50V -5V Power Supply R104 47R, 1W U_5 IN GND MC79M05 OUT -5V Vin Vout GND D102 MA2YD2300 C103 10uF, 50V C104 10uF, 50V Z104 24V C105 10uF, 50V C106 10uF, 50V -B . www.irf.com IRAUDAMP5 REV 3.0 Page 34 of 49 Class D, Mother Board Clock and House Keeping Schematic +B R143 SD 10K +5V R142 68k R139 R138 4.7k 1N4148 OT DCP R144 10k Q109 MMBT5551 UVP SW-3WAY_A-B S3A Q111 MMBT5401 D105 OT 39V Z105 47k R149 47K CStart D107 C117 1N4148 100uF, 16V R148 10k D106 1N4148 Z106 18V R147 47k R140 10k Z107 18V R145 47K I E S SW S2 1 2 R109 1K SP MUTE C112 1200pF, 50V +5V SW_H-L D103 1N4148 R120 100R VCC 6A 6Y 5A 5Y 4A 4Y 10nF, 50V Q108 +5V R118 1k NORMAL 47k R137 R119 1k PROTECTION D104 1N4148 -5V MUTE 47R R150 47k R151 47k Q112 MMBT5551 Z109 8.2V -5V MMBT5551 +5V R133 47k Q107 1 2 3 PVT412 R132 47k P1 6 5 4 J9 2 1 R129 6.8k R127 6.8k MMBT5401 MUTE R117 R130 47K DCP R131 47K R128 6.8k Q104 DC protection 100pF, 50V C111 C110 R112 820R U_3 1A 1Y R113 2A 2Y 3A 3Y R116 47R 74HC14 R134 10k MMBT5401 CLK CLK GND C114 R135 82k R126 100K Q105 10uF, 50V Z108 8.2V Q106 R125 10K C115 R136 68k +B 5K POT -B R110 1nF, 50V 100k R111 10K Q103 Q110 MMBT5551 R141 47k OVP R146 47K S1 C119 SW-PB 0.1uF, 50V MMBT5551 C113 Trip and restart SW-3WAY_A-B 100pF, 50V S3B SW S E I R114 100R CH1 O R124 10k C116 100uF, 16V R123 1K R122 47k CH2 O R121 47k DC_PS EXT. CLK +B Drawing by: M.Rodriguez Mrodrig5@irf.com MMBT5551 R115 47R J8 BNC A24497 MMBT5551 -B www.irf.com IRAUDAMP5 REV 3.0 Page 35 of 49 IRAUDAMP5 Bill of Materials Class D, Daughter Board: Amp5_DB_2092_Rev 3.0_BOM Footprint 805 TAN-A TAN-B 0805 TAN-B TAN-B 0805 1206 0805 0805 SOD-323 SOD-323 SMA SMA 805 CON EISA31 CON EISA31 CON_POWER CON_POWER SOT23-BCE SOT23-BCE Direct Fet SJ 0805 0805 0805 MMBT5401-7 IRF6645 100R 10R 3.3K 2 4 2 11 2 Designator 1nF,250V,COG 10uF, 16V, Tan 10uF, 16V, Tan 47nF,50V, X7R 10uF, 16V, Tan 3.3uF, 16V, X7R 0.1uF,100V, X7R 0.1uF,100V, X7R open 10nF,50V, X7R BAV19WS-7-F 1N4148WS-7-F MURA120T3G ES1D LTST-C171TBKT CON EISA31 CON EISA31 CON_POWER CON_POWER MMBT5551 6 2 2 3 2 4 2 3 1 2 2 2 2 1 2 1 1 1 1 1 PartType Quantity VENDER DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY IR DIGI KEY DIGI KEY DIGI KEY C1, C2, C21,C22,C23,C24 C3, C4 C5, C6 C9, C28, C29 C10, C11 C12, C16, C18, C19 C13, C17 C14, C15, C32, C33 C20 C30, C31 D1, D2 D3, D4 D5, D6 D7 DS1, DS2 J1A J1B J2A J2B Q1 Q2, Q7 D-FET1, D-FET2, D-FET3, D-FET4 R1, R2 R3,R4,R9,R10,R15,R16,R27,R28,R30,R32,R8 R5, R6 PART NO 445-2325-1-ND 495-2236-1-ND 399-3706-1-ND PCC1836CT-ND 399-3706-1-ND 445-1432-1-ND 399-3486-1-ND PCC2239CT-ND open PCC103BNCT-ND BAV19WS-FDICT-ND 1N4148WS-FDICT-ND MURA120T3GOSCT-ND ES1DFSCT-ND 160-1645-1-ND A26568-ND A26568-ND A26570-ND A26570-ND MMBT5551FSCT-ND MMBT5401DICT-ND IRF6645 P100ACT-ND P10ACT-ND P3.3KACT-ND www.irf.com IRAUDAMP5 REV 3.0 Page 36 of 49 R7 0805 0805 0805 0805 805 0805 0805 0805 0805 0805 0805 1206 805 ST-32 3mm SQ 805 SOIC16 IR Driver 3 3.01k 1k 100C 3 open 3 0 3 33K 3 1R 3 10K 5 4.7R 2 1k 2 1.2k 1K 2 8.2K 2 4.7K 2 DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY DIGI KEY MOUSER DIGI KEY DIGI KEY IR 100K 2 DIGI KEY 1206 10R 1 DIGI KEY R11, R31, R33, R34, R35, R47 R12, R45 R13, R14,R19,R20 R24, R48 R7,R18 R21, R22 R23, R26 R25, R29,R36,R41, R42 R37, R38 R39, R40 R43, R44 R49, R50, R51, R52, Rp1, Rp2 P10ECT-ND P100KACT-ND P4.7KACT-ND P8.2KACT-ND P1.0KACT-ND RHM1.2KARCT-ND P1.0KACT-ND P4.7ACT-ND P10KACT-ND P1.0ACT-ND RHM33KARCT-ND RHM0.0ARCT-ND open 594-2322-675-21007 ST32ETB102TR-ND RHM3.01KCCT-ND IRS2092S P1,P2 R46,R53 U1, U2 www.irf.com IRAUDAMP5 REV 3.0 Page 37 of 49 Class D Motherboard: IRAUDAMP5 MOTHERBOARD BILL OF MATERIAL NO 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 Designator C1, C5, C6, C101, C102, C103, C104, C105, C106, C115 C2, C3 C7, C8, C9, C10 C11, C12, C13, C14 C15, C16 C17, C18 C19, C20 C119 C23, C24 C25, C26 C27, C28, C29, C30, C40, C41, C42, C43, C44, C45, C46, C47 R29, R30, R55, R56, R60, R61, R62, R63, R64, R65, R66, R67, R71, R72 C31, C32 C33, C34, C48, C49 C107, C109 C108, C114 C110 C111, C113 C112 C116, C117 D103, D104, D105, D106, D107 D5, D6, D7, D8 D101, D102 HS1 J1A, J1B J2A, J2B J3, J4 J5, J6 J7 J8 J9 L1, L2 NORMAL P1 PROTECTION Q101 Q102, Q104, Q106, Q111 Q103, Q105, Q107, Q108, Q109, Q110, Q112 R1, R2, R57, R58, R110, R126 R3, R4, R114 R5, R6 R7, R8, R10, R11, R27, R28, R115, R116, R117 R9, R105 R13, R14 R17, R18 R106, R121, R122, R130, R131, R132, R133, R137, R139, R141, R145, R146, R147, R149, R150, R151 R152 R55, R56 R39, R40 R21, R22, R23, R24 R120 R29P, R30P R31, R32 R33, R34 R109, R118, R119, R123 R47, R48 R49, R50 R68, R69 # 10 2 4 4 2 2 2 1 2 2 12 14 2 4 2 2 1 2 1 2 5 4 2 1 2 2 2 2 1 1 1 2 1 1 1 1 4 7 6 3 2 9 2 2 2 16 1 2 2 4 1 2 2 2 4 2 2 2 Footprint RB2/5 RB2/5 open open 805 AXIAL0.19R 1206 1206 CAP MKP CAP MKPs 805 805 RB5/12_5 AXIAL0.1R 805 805 805 805 805 rb2/5 SOD-123 SMA SOD-123 Heat_S6in1 CON EISA-31 CON_POWER MKDS5/2-9.5 Blue RCA J HEADER3 BNC_RA CON ED1567 Inductor from Panasonic Led rb2/5 DIP-6 Led rb2/5 SOT89 SOT23-BCE SOT23-BCE 805 805 1206 805 805 805 805 805 805 805 805 open 1206 open 2512 1206 805 2512 1206 AXIAL-0.3 Part Type 10uF, 50V 2.2uF, 50V Part No 565-1106-ND 565-1103-ND Vender Digikey Digikey 33pF 150pF, 500V 2.2uF, 16V 0.1uF, 50V 0.47uF, 400V 0.1uF, 400V OPEN OPEN 1000uF,50V OPEN 4.7uF, 16V 10nF, 50V 1nF, 50V 100pF, 50V 1200pF, 50V 100uF, 16V 478-1281-1-ND 338-1052-ND PCC1931CT-ND PCC104BCT-ND 495-1315-ND 495-1311-ND Digikey Digikey Digikey Digikey Digikey Digikey 565-1114-ND PCC2323CT-ND PCC103BNCT-ND PCC102CGCT-ND PCC101CGCT-ND 478-1372-1-ND 565-1037-ND 1N4148W-7-F MURA120T3G MA2YD2300 HEAT SINK CON EISA31 CON_POWER 277-1022 1N4148W-FDICT-ND MURA120T3GOSCT-ND MA2YD2300LCT-ND 294-1086-ND A26453-ND A26454-ND 277-1271-ND or 651-1714971 RCJ-055 277-1272 BNC ED1567 ETQA21ZA220 or ETQA17B220 404-1106-ND PVT412 404-1109-ND FX941 CP-1422-ND 277-1272-ND or 651-1714984 A32248-ND ED1567 Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey or Mouser Digikey Digikey or Mouser Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey P13504-ND 160-1143-ND PVT412-ND 160-1140-ND FCX491CT-ND MMBT5401-7-F MMBT5551 100K 100R 4.7R 47R 10R 3.3K, 1% 22k 47k OPEN 0.0 Ohms 470R 100R 47K, 1% 1K 1K 10, 1W 2.2k OPEN MMBT5401-FDICT-ND MMBT5551-7DICT-ND P100KACT-ND P100ACT-ND P4.7ECT-ND P47ACT-ND P10ACT-ND P3.3KZCT-ND P22KACT-ND P47KACT-ND P0.0ACT-ND P470ACT-ND P100ECT-ND PT47KAFCT-ND P1.0KECT-ND P1.0KACT-ND PT10XCT P2.2KECT-ND - www.irf.com IRAUDAMP5 REV 3.0 Page 38 of 49 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 R101, R102, R103, R104 R107, R138 R108 R111, R124, R125, R134, R140, R143, R144, R148 R112 R113 R127, R128, R129 R135 R136, R142 S1 S2 S3 U1, U2 U3, U4 U7, U8 U9, U10 U_1 U_2 U_3 U_4 U_5 U_6 Z1, Z2, Z103 Z101, Z102 Z104 Z105 Z106, Z107 Z108, Z109 Volume Knob Thermalloy TO-220 mounting kit with screw 1/2" Standoffs 4-40 4-40 Nut No. 4 Lock Washer 4 2 1 8 1 1 3 1 2 1 1 1 2 2 2 2 1 1 1 1 1 1 3 2 1 1 2 2 1 3 5 5 5 2512 805 V_Control 805 805 POTs 1206 805 805 Switch SW-EG1908-ND SW-EG1944-ND open SOT25 MINI5 SO-8 SOIC16 N8A M14A TO-220 TO-220 TO-220 SOD-123 SMA SOD-123 SOD-123 SOD-123 SOD-123 Blue Knob Kit screw, ROHS Standoff 100 per bag 100 per bag 47R, 1W 4.7K CT2265 10K 820R 5K POT 6.8k 82k 68k SW-PB SW_H-L SW-3WAY 74AHC1G04 open open CS3310 3310S06S 74HC14 PT47XCT-ND P4.7KACT-ND CT2265-ND P10KACT-ND P820ACT-ND Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey 3362H-502LF-ND P6.8KECT-ND P82KACT-ND P68KACT-ND P8010S-ND EG1908-ND EG1944-ND 296-1089-1-ND open open 73C8016 or 72J5420 3310-IR01 296-1194-1-ND Newark *Tachyonix Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Digikey Newark Newark Digikey Digikey Digikey MC78M05CTG LM79M05CT LM78M12CT 15V 4.7V 24V 39V 18V 8.2V MC21060 AAVID 4880G MC78M05CTGOS-ND LM79M05CT-ND LM78M12CT-ND BZT52C15-FDICT-ND 1SMA5917BT3GOSCT-ND BZT52C24-FDICT-ND BZT52C39-13-FDICT-ND BZT52C18-FDICT-ND BZT52C8V2-FDICT-ND 10M7578 82K6096 8401K-ND H724-ND H729-ND *Tachyonix Corporation, 14 Gonaka Jimokuji Jimokuji-cho, Ama-gun Aichi, JAPAN 490-1111 http://www.tachyonix.co.jp info@tachyonix.co.jp www.irf.com IRAUDAMP5 REV 3.0 Page 39 of 49 IRAUDAMP5 Hardware Voltage regulator mounting: Item Description 1 2 3 4 7 Insulator Thermalfilm Shoulder Washer Flat Washer #4 No. 4-40 UNC-2B Hex Nut No. 4-40 UNC-2A X 1/2 Long Phillips Pan Head Screw Lockwasher, No.4 Heatsink PCB 5 6 8 7 8 Item Description 1 2 3 4 7 Insulator Thermalfilm Shoulder Washer Flat Washer #4 No. 4-40 UNC-2B Hex Nut No. 4-40 UNC-2A X 1/2 Long Phillips Pan Head Screw Lockwasher, No.4 Heatsink PCB 5 6 8 7 8 www.irf.com IRAUDAMP5 REV 3.0 Page 40 of 49 IRAUDAMP5 PCB Specifications Figure 34. Motherboard and Daughter-board Layer Stack Daughter board: Material: Layer Stack: Dimensions: Solder Mask: Plating: Silkscreen: FR4, UL 125°C 2 Layers, 1 oz. Cu each, Through-hole plated 3.125” x 1.52” x 0.062” LPI Solder mask, SMOBC on Top and Bottom Layers Open copper solder finish On Top and Bottom Layers Motherboard: Material: Layer Stack: Dimensions: Solder Mask: Plating: Silkscreen: FR4, UL 125°C 2 Layers, 1 oz. Cu 5.2” x 5.8” x 0.062” LPI Solder mask, SMOBC on Top and Bottom Layers Open copper solder finish On Top and Bottom Layers www.irf.com IRAUDAMP5 REV 3.0 Page 41 of 49 IRAUDAMP5 PCB layers Class D, Daughter-board: Figure 40. PCB Layout – Top-Side Solder-Mask and Silkscreen www.irf.com IRAUDAMP5 REV 3.0 Page 42 of 49 Figure 41. PCB Layout – Bottom Layer and Pads and bottom silk screen www.irf.com IRAUDAMP5 REV 3.0 Page 43 of 49 Figure 39. PCB Layout Motherboard: Top Layer www.irf.com IRAUDAMP5 REV 3.0 Page 44 of 49 Top silk screen www.irf.com IRAUDAMP5 REV 3.0 Page 45 of 49 Bottom www.irf.com IRAUDAMP5 REV 3.0 Page 46 of 49 www.irf.com IRAUDAMP5 REV 3.0 Page 47 of 49 4.0 4.0 Bottom Silkscreen WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245 Tel: (310) 252-7105 Data and specifications subject to change without notice. 7/27/2007 www.irf.com IRAUDAMP5 REV 3.0 Page 48 of 49