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| ZXCD1000 HIGH FIDELITY CLASS D AUDIO AMPLIFIER SOLUTION DESCRIPTION The ZXCD1000 provides complete control and modulation functions at the heart of a high efficiency high performance Class D switching audio amplifier solution. In combination with Zetex HDMOS MOSFET devices, the ZXCD1000 provides a high performance audio amplifier with all the inherent benefits of Class D. The ZXCD1000 solution uses proprietary circuit design to realise the true benefits of Class D without the traditional drawback of poor distortion performance. The combination of circuit design, magnetic component choice and layout are essential to realising these benefits. The ZXCD1000 reference designs give output powers up to 100W rms with typical open loop (no feedback) distortion of less than 0.2% THD + N over the entire audio frequency range at 90% full output power. This gives an extremely linear system. The addition of a minimum amount of feedback (10dB) further reduces distortion figures to give < 0.1 % THD + N typical at 1kHz. From an acoustic point of view, even more important than the figures above, is that the residual distortion is almost totally free of any crossover artifacts. This allows the ZXCD1000 to be used in true hi-fi applications. This lack of crossover distortion, sets the ZXCD1000 solutions quite apart from most other presently available low cost solutions, which in general suffer from severe crossover distortion problems. FEATURES * * * * * * >90% efficiency 4 / 8 drive capability Noise Floor -115dB for solution Flat response 20Hz - 20kHz High gate drive capability ( 2200pF) Very low THD + N 0.2% typical full 90% power, full band ( for the solution) Distortion v Power 8 open loop at 1kHz. * Complete absence of crossover artifacts * OSC output available for sync in multi-channel applications THD + N (%) 10W 1W 5W * Available in a 16 pin exposed pad QSOP package Output Power APPLICATIONS * * * * * * * * DVD Players Automotive audio systems Home Theatre Multimedia Wireless speakers Portable audio Sub woofer systems Public Address system The plot shows Distortion v Power into an 8 load at 1kHz. This plot clearly demonstrates the unequalled performance of the Zetex solution. Typical distortion of 0.05% at 1W can be seen with better than 0.15% at 10W. Truly world class performance. ISSUE 2 - APRIL 2002 1 ZXCD1000 ABSOLUTE MAXIMUM RATINGS Terminal Voltage with respect to GND VCC Power Dissipation Package Thermal Resistance ( ja) Operating Temperature Range Maximum Junction Temperature Storage Temperature Range 20V 1W 54 C/W -40 C to 70 C 125 C -50C to 85 C Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS TEST CONDITIONS (unless otherwise stated) VCC = 16V, TA = 25 C SYMBOL V CC I ss F osc F osc(tol) Vol OutA/B Voh OutA/B T Drive 5V5tol 9VA/Btol Audio A / B Triangle A/B Audio A / B Triangle A/B Osc A / B PARAMETER Operating Voltage Range Operating Quiescent Current Switching Frequency Frequency Tolerance Low level output voltage High level output voltage Output Drive Capability (OUT A / B Rise/Fall) Internal Rail Tolerance Internal Rail Tolerance Input Impedence Input Impedence Bias Level Bias Level Amplitude V CC = 12V V CC = 18V, 16V C osc = 330pF C osc = 330pF No load No load Load Capacitance = 2200pF 1F Decoupling 1F Decoupling 5.23 8.32 1.35k 1.35k 2.95 2.95 0.89 7.5 50 5.5 8.75 1.8k 1.8k 3.1 3.1 1.05 5.77 9.18 2.3k 2.3k 3.25 3.25 1.2 V V V 150 200 CONDITIONS LIMITS MIN 12 UNITS MAX 18 45 50 250 +/-25 100 V mA mA kHz % mV V ns V V TYP 16 ISSUE 2 - APRIL 2002 2 ZXCD1000 Pin Connection Diagram Audio A Triangle A Osc A Dist Cosc Osc B Triangle B Audio B 1 2 3 4 5 6 7 8 16 15 14 13 12 11 10 9 5V5 Out A 9VA VCC 9VB Gnd2 Out B Gnd Figure 1 Pin Description Pin number 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Pin Name Audio A Triangle A Osc A Dist C osc Osc B Triangle B Audio B Gnd OUT B Gnd2 9VB VCC 9VA OUT A 5V5 Pin Description Audio Input for Channel A Triangle Input for Channel A Triangle Output No connection External timing capacitor node (to set the switching frequency) Triangle Output (for slave ZXCD1000 in stereo application) Triangle Input for Channel B Audio Input for Channel B Small Signal GND Channel B PWM Output to drive external Bridge MOSFETs Power GND (for Output Drivers) Internal Supply Rail (Decouple with 1F Cap) Input Supply Pin (Max = 18V) Internal Supply Rail (Decouple with 1F Cap). Channel A PWM Output to drive external Bridge MOSFETs Internal Supply Rail (Decouple with 1F Cap) ISSUE 2 - APRIL 2002 3 ZXCD1000 ZXCD1000 Class D controller IC A functional block diagram of the ZXCD1000 is shown in Figure 2. The on chip series regulators drop the external VCC supply (12V-18V) to the approximate 9V (9VA/9VB) and 5.5V (5V5) supplies required by the internal circuitry. A triangular waveform is generated on chip and is brought out at the OscA and OscB outputs. The frequency of this is set (to ~200kHz) by an external capacitor (Cosc) and on chip resistor. The triangular waveform must be externally AC coupled back into the ZXCD1000 at the TriangleA and TriangleB inputs. AC coupling ensures symmetrical operation resulting in minimal system DC offsets. TriangleA is connected to one of the inputs of a comparator and TriangleB is connected to one of the inputs of a second comparator. The other inputs of these two comparators are connected to the AudioA and AudioB inputs, which are anti-phase signals externally derived from the audio input. The triangular wave is an order higher in frequency than the audio input (max 20kHz). The outputs of the comparators toggle every time the TriangleA/B and the (relatively slow) AudioA/B signals cross. 4 5 3 67 Oscillator & Ramp Generator Osc Buffers Triangle A Triangle B Osc A Osc B Cosc Dist 2 Audio A 1 Audio B 8 VCC Internal 5V5 PreDriver PWM Comp A PreDriver PWM Comp B O/P Driver Out A 15 Out B 10 O/P Driver 13 Internal 9V Gnd Figure 2. Functional Block Diagram Gnd2 9VA 9VB 5V5 14 12 16 9 11 ISSUE 2 - APRIL 2002 4 ZXCD1000 PWM Comparator Audio A/B Audio A/B Triangle A/B O/P Triangle A/B Comparator O/P (Duty Cycle = 50%) Figure 3a. Figure 3b. Triangle A/B Audio A/B Triangle A/B Audio A/B O/P Comparator O/P (Duty Cycle = 75%) Comparator O/P (Duty Cycle = 25%) Figure 3c. Figure 3d. Figures 3a,3b,3c and 3d The audio input Pulse Width Modulates the comparator output. With no audio input signal applied, the AudioA/B inputs are biased at the mid-point of the triangular wave, and the duty cycle at the output of the comparators is nominally 50%. As the AudioA/B signal ascends towards the peak level, the crossing points with the (higher frequency) triangular wave also ascend. The comparator monitoring these signals exhibits a corresponding increase in output duty cycle. Similarly, as the AudioA/B signal descends, the duty cycle is correspondingly reduced. Thus the audio input Pulse Width Modulates the comparator outputs. This principle is illustrated in Figures 3a, b, c and d. The comparator outputs are buffered and used to drive the OutA and OutB outputs. These in turn drive the speaker load (with the audio information contained in the PWM signal) via the off chip output bridge and single stage L-C filter network. The ramp amplitude is approximately 1V. The AudioA, AudioB, TriangleA and TriangleB inputs are internally biased to a DC voltage of approximately VCC/5. The mid - point DC level of the OscA and OscB triangular outputs is around 2V. The triangular wave at the Cosc pin traverses between about 2.7Vand 3.8V and the dist pin exhibits a roughly square wave from about 1.4V to 2V. (The above voltages may vary in practice and are included for guidance only). ISSUE 2 - APRIL 2002 5 ZXCD1000 Zetex Class D 25W Mono Open Loop Solution 6 ISSUE 2 - APRIL 2002 Figure 4 ZXCD1000 Class D 25W Mono Open Loop (Bridge Tied Load - BTL) Solution - Circuit Description Proprietary circuit design and high quality magnetics are necessary to yield the high THD performance specified. Deviation from the Zetex recommended solution could significantly degrade performance. The speaker is connected as a Bridge Tied Load (BTL). This means that both sides of the speaker are driven from the output bridge and therefore neither side of the speaker connects to ground. This allows maximum power to be delivered to the load, from a given supply voltage. The supply voltage for this solution is nominally 16V for 25W into a 4 load. A schematic diagram for the solution is shown in Figure 4. The audio input is AC coupled and applied to a low pass filter and a phase splitter built around the NE5532 dual op-amp. One of these op-amps is configured as a voltage follower and the other as a X1 inverting amplifier. This produces in phase and inverted signals for application to the ZXCD1000. The op-amp outputs are AC coupled into the ZXCD1000 Audio A and Audio B inputs via simple R-C low pass filters (R16/C3 and R15/C7). The op-amps are biased to a DC level of approximately 6V by R11 and R12. The Pulse Width Modulated (PWM) outputs, OutA and OutB, which contain the audio information, are AC coupled and DC restored before driving the Zetex ZXM64P03X and ZXM64N03X PMOS and NMOS output bridge FET's. AC coupling is via C17, C18, C19 and C20. DC restoration is provided by the D2(A1a)/R4, D1(A4a)/R2 and D3(A1a)/R6, D4(A4a)/R9 components. This technique allows the output stage supply voltage to be higher than the high level of the OutA and OutB outputs (approximately 8.5V), whilst still supplying almost the full output voltage swing to the gates of the bridge FET's (thereby ensuring good turn on). This can be exploited to yield higher power solutions with higher supply voltages - this is discussed later. The resistor/diode combinations (R5/D2(A16b), R3/D1(A4b), R7/D3(A1b) and R8/D4(A4b)) in series with the bridge FET gates, assist in controlling the switching of the bridge FET's. This design minimises shoot through currents whilst still achieving the low distortion characteristics of the system. The purpose of the special inductors in conjunction with the output capacitors C23, C24, C25 and C26 is to low pass filter the high frequency switching PWM signal that comes from the bridge. Thus the lower frequency audio signal is recovered and is available at the speakerA and speakerB outputs across which the speaker should be connected. Zetex can offer advice on suitable source for the specialist magnetics. The optional components R17 and C3 form a Zobel network. The applicability of these depends upon the application and speaker characteristics. Suggested values are 47nF and 10 ohms Efficiency The following plots show the measured efficiency of the Zetex solution at various power levels into both 4 and 8 loads. As a comparison, typical efficiency is plotted for a class A-B amplifier. They clearly demonstrate the major efficiency benefits available from the Zetex class D solution. Figure 5 ISSUE 2 - APRIL 2002 7 ZXCD1000 Class D Mono Open Loop solution (Bridge Tied Load - BTL) Solution - Demonstration board The circuit design shown in figure 4 is available as a demonstration board to enable evaluation of the circuit excellent performance. Full bill of materials (BOM) and Gerber files are also available. The demonstration board part number is ZXCD1000EVMOL. Layout and component selection are critical to maximising performance from this solution, the demonstration board and circuit can be used as a guide to facilitate design of production circuits. Zetex applications can advise if any circuit modifications are required for specific requirements. The board can be used to demonstrate the ZXCD amplifier capability with output power typically of 25W into 4 or 8 load depending on chosen supply voltage. Operating instructions are included in the demonstration board literature. It is well known that this kind of distortion is particularly unpleasant to the listener. The two scope traces of Figure 7 clearly show the lack of such artifacts with the Zetex solution Figure 7a ZETEX Class D Solution. (10W into 4) Note lack of Crossover Artifacts Figure 6 Mono solution demonstration board A very important feature of the Zetex solution is that the residual distortion is almost totally free of any crossover artifacts. This lack of crossover distortion sets the ZXCD1000 solutions quite apart from most other presently available low cost solutions, which in general suffer from severe crossover distortion problems. Figure 7b Typical Class D Solution. Note Large Crossover Artifacts ISSUE 2 - APRIL 2002 8 ZXCD1000 Other Solutions - Stereo, Closed Loop and Higher Powers. STEREO It is possible to duplicate the above solution to give a 2 channel stereo solution. However if the oscillator frequencies are not locked together, a beat can occur which is acoustically audible. This is undesirable. A stereo solution which avoids this problem can be achieved by synchronising the operating frequencies of both ZXCD1000's class D controller IC's, by slaving one device from the other. This is illustrated in Figure 8. Great care must be taken when linking the triangle from the master to the slave. Any pickup can cause slicing errors and result in increased distortion. The best connection method is to run two tracks, side by side, from the master to the slave. One of these tracks would be the triangle itself, and the other would be the direct local ground linking the master pin9 ground to the slave pin 9 ground. A demonstration board, ZXCD1000EVSOL, is available for a stereo 25W solution. MASTER Figure 8 Frequency synchronisation for stereo applications SLAVE ISSUE 2 - APRIL 2002 9 ZXCD1000 50W Master Channel with feed back 10 ISSUE 2 - APRIL 2002 Figure 9 ZXCD1000 Class D 50W Mono Bridge Tied Load (BTL) Solution with Feedback - Circuit Description With the addition of feedback (hence closed loop solution) it is possible to obtain even better THD performance. A schematic diagram for this is shown in Figure 9. Again proprietary circuit and special magnetic design is necessary to yield the high THD p e r fo r manc e and de v i a t i on f rom t hi s co u l d significantly reduce performance. Much of the circuitry is the same as described for the open loop solution. The main differences being a consequence of using the feedback circuitry. The audio input is ac coupled and applied to an op-amp (1/2 of U3) configured as a non-inverting amplifier with a gain of approximately 4. Feedback is applied differentially from the bridge outputs via the other half of U3 op-amp. A portion of the single ended output from this op-amp is subtracted from the output of the non-inverting op-amp output above. Overall negative feedback is applied due to the polarity and connection of the signals involved. The audio signal from the above circuitry is applied to a phase splitter as was done for the open loop solution. This is built around the other 5532 dual op-amp (U2). One of these op-amps is configured as a voltage follower and the other as a X1 inverting amplifier. This produces in phase and inverted signals for application to the ZXCD1000 Audio A and Audio B inputs respectively. The output circuitry downstream of the ZXCD1000 is as described for the open loop solution. In order to support the 50W output power of this solution a 25V rail is required for a 4 load. The MOSFETs used are SOT223 packaged (ZXM64N035G and ZXM64P035). Further information on this design is available through Zetex applications. Higher Power Solutions With some modifications the applications solutions can be extended to give output power up to 100W. The main differences being the supply voltage, the TO220 MOSFETs, and the output magnetics. The magnetics for 100W are necessarily larger than required for 25/50W in order to handle the higher load currents. For 100W operation the supply voltage to the circuit is nominally 35V with a 4 load. However the maximum supply voltage to the ZXCD1000 class D controller IC is 18V, hence a voltage dropper is required. This could be done, for example, as in the open loop solution described previously. A 100W circuit is shown on figure 10. This features a 35V bridge supply TO220 MOSFETs (ZXM64N035L3 and ZXM64P035L3) and also proposed protection circuits for over current and over temperature and an alternative anti pop circuit. Further information on this 100W reference design can be obtained through Zetex applications. The ZXCD1000 class D controller IC is inherently capable of driving even higher power solutions, with the appropriate external circuitry. However as stated above the maximum supply voltage to the ZXCD1000 class D controller IC is 18V and the higher supply voltages must therefore be dropped. Also due consideration must be given to the ZXCD1000 output drive levels and the characteristics of the bridge MOSFET's. The latter must be sufficiently enhanced by the OutA and OutB outputs to ensure the filter and load network is driven properly. If the gate drive of the ZXCD1000 is too low for the chosen MOSFET then the OUTA and OUTB signal must be buffered using an appropriate MOSFET driver circuit. Additionally, suitable magnetics are essential to achieve good THD performance. Package details The ZXCD1000 is available in a 16 pin exposed pad QSOP package. The exposed pad on the underside of the package should be soldered down to an area of copper on the PCB, to function as a heatsink. The PCB should have plated through vias to the underside of the board, again connecting to an area of copper. ISSUE 2 - APRIL 2002 11 ZXCD1000 100W Mono Class D Solution 12 ISSUE 2 - APRIL 2002 Figure 10 ZXCD1000 ZXCD1000 Solution performance figures Typical performance graphs for the Zetex 25W open loop solution are shown here for both 4 and 8 loads. These graphs further demonstrate the true high fidelity performance achieved by the Zetex solutions. THD + N (%) 10W 1W 5W Output Power dB f(Hz) THD v Power into 8 at 1kHz FFT of distortion and noise floor at 1W (8 load) dB dB f(Hz) f(Hz) Frequency response (8 load) FFT of distortion and noise floor at 10W (8 load) ISSUE 2 - APRIL 2002 13 ZXCD1000 THD + N (%) 20W 1W 5W 10W Output Power dB f(Hz) THD v Power into 4 at 1kHz FFT of distortion and noise floor at 1W (4 load) dB f(Hz) dB f(Hz) Frequency response (4 load) Note roll off. This can be corrected by using an alternative values for output filter components. FFT of distortion and noise floor at 20W (4 load) ISSUE 2 - APRIL 2002 14 ZXCD1000 ISSUE 2 - APRIL 2002 15 ZXCD1000 PACKAGE DIMENSIONS EXPOSED PAD C S h x 45 3 2 1 H E SEE DETAIL "A" BOTTOM VIEW TOP VIEW END VIEW S Y M B O L e b .010 A2 A SEATING PLANE L O C DETAIL "A" D A1 SEATING PLANE SIDE VIEW DIMENSIONS IN INCHES MIN. NOM. MAX. A .058 .061 .066 A1 .001 .003 .005 A2 .055 .058 .061 .012 b .008 .010 c .007 D .189 .194 .196 E .150 .154 .157 e .025 BSC H .228 .236 .244 h .010 .016 .013 .035 .025 L .016 .005 .007 S .002 O C 0 5 8 C ORDERING INFORMATION Device ZXCD1000EQ16 Description Class D modulator Package eQSOP16 T&R Suffix TA, TC Information on Zetex reference designs, MOSFETs and demonstration boards can be obtain by contacting Zetex applications or by visiting www.zetex.com/audio (c) Zetex plc 2001 Zetex plc Fields New Road Chadderton Oldham, OL9 8NP United Kingdom Telephone (44) 161 622 4422 Fax: (44) 161 622 4420 Zetex GmbH Streitfeldstrae 19 D-81673 Munchen Germany Telefon: (49) 89 45 49 49 0 Fax: (49) 89 45 49 49 49 Zetex Inc 700 Veterans Memorial Hwy Hauppauge, NY11788 USA Telephone: (631) 360 2222 Fax: (631) 360 8222 Zetex (Asia) Ltd 3701-04 Metroplaza, Tower 1 Hing Fong Road Kwai Fong Hong Kong Telephone: (852) 26100 611 Fax: (852) 24250 494 These offices are supported by agents and distributors in major countries world-wide. This publication is issued to provide outline information only which (unless agreed by the Company in writing) may not be used, applied or reproduced for any purpose or form part of any order or contract or be regarded as a representation relating to the products or services concerned. The Company reserves the right to alter without notice the specification, design, price or conditions of supply of any product or service. For the latest product information, log on to www.zetex.com C ISSUE 2 - APRIL 2002 16 |
Price & Availability of ZXCD1000
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