Audio Switching Amplifier AD1994 FEATURES GENERAL DESCRIPTION Integrated stereo modulator and power stage <0.005% THD + N 105 dB dynamic range (A-weighted) 2 × 25 W output power (6 Ω, 10% THD + N) 1 × 50 W output power (3 Ω, 10% THD + N) RDS-ON < 0.3 Ω (per transistor) PSRR > 65 dB On-off-mute pop noise suppression EMI optimized modulator Short-circuit protection Overtemperature protection Low cost DMOS process The AD1994 is a 2-channel, bridge tied load (BTL), switching audio power amplifier with integrated Σ-Δ modulator. The modulator accepts a single-ended, analog input signal and converts it to a switching waveform to drive speakers directly. One of the two modulators can control both output stages providing twice the current and almost twice the efficiency for single-channel applications. Both modulators can also control external power devices for arbitrarily high output power. A digital, microprocessor-compatible interface provides control of reset, mute, and PGA gain, as well as feedback signals for thermal and overcurrent error conditions. The output stage can operate over a power supply voltages range of 8 V to 20 V. The analog modulator and digital logic operate from a 5 V supply. APPLICATIONS Advanced televisions Compact multimedia systems Minicomponents FUNCTIONAL BLOCK DIAGRAM PGA0 AVDD NFL– PGA1 NFL+ FEEDBACK NETWORK DVDD PVDD AD1994 AINL MOD_FILT LEVEL SHIFTER AND DEAD TIME CONTROL Σ-Δ MODULATOR PGA OUTL+ A2 B1 ORDER REDUCER AINR A1 Σ-Δ MODULATOR PGA OUTL– B2 H-BRIDGE C1 OUTR+ C2 CLKI CLKO OSCILLATOR REF_FILT VOLTAGE REFERENCE MODE CONTROL LOGIC AND POP/CLICK SUPPRESSION D1 PGND FEEDBACK NETWORK 05775-001 DCTRL0 DCTRL1 DCTRL2 NFR– NFR+ ERR0 ERR1 ERR2 MUTE RESET AGND OUTR– D2 Figure 1. Rev. 0 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.461.3113 ©2006 Analog Devices, Inc. All rights reserved. AD1994 TABLE OF CONTENTS Features .............................................................................................. 1 Σ-Δ Modulator............................................................................ 15 Applications....................................................................................... 1 MUTE and RESET ..................................................................... 15 General Description ......................................................................... 1 Mono Mode................................................................................. 16 Functional Block Diagram .............................................................. 1 Modulator Mode ........................................................................ 16 Revision History ............................................................................... 2 Gain Structure............................................................................. 16 Specifications..................................................................................... 3 Power Stage ................................................................................. 17 Absolute Maximum Ratings............................................................ 5 Clocking....................................................................................... 18 ESD Caution.................................................................................. 5 Protection Circuits and Error Reporting ................................ 19 Pin Configuration and Function Descriptions............................. 6 Application Circuits ....................................................................... 20 Typical Performance Characteristics ............................................. 8 Outline Dimensions ....................................................................... 21 Theory of Operation ...................................................................... 15 Ordering Guide .......................................................................... 21 Overview...................................................................................... 15 REVISION HISTORY 2/06—Revision 0: Initial Version Rev. 0 | Page 2 of 24 AD1994 SPECIFICATIONS Test conditions, unless otherwise specified. Table 1. Parameter SUPPLY VOLTAGES AVDD DVDD PVDD AMBIENT TEMPERATURE LOAD IMPEDANCE CLOCK FREQUENCY PGA GAIN MEASUREMENT BANDWIDTH Ratings 5V 5V 12 V 25°C 6Ω 12.288 MHz 0 dB 20 Hz to 20 kHz Table 2. Parameter RDS-ON Per High-Side Transistor Per Low-Side Transistor MAXIMUM CURRENT THROUGH OUTx THERMAL WARNING ACTIVE THERMAL SHUTDOWN ACTIVE RESTORE TEMPERATURE AFTER THERMAL SHUTDOWN Min Typ Max Unit Test Conditions/Comments 260 210 5 135 150 120 355 265 mΩ mΩ A °C °C °C T = 25°C T = 25°C Peak Die temperature Die temperature Die temperature Table 3. Performance Specifications Parameter TOTAL HARMONIC DISTORTION AND NOISE (THD + N) SIGNAL-TO-NOISE RATIO (SNR) DYNAMIC RANGE (DNR) CROSSTALK (LEFT-TO-RIGHT OR RIGHT-TO-LEFT) Typ 0.003 0.006 0.01 0.02 105 105 −100 Unit % % % % dB dB dB Test Conditions/Comments PGA = 0 dB, PO = 1 W, 1 kHz PGA = 6 dB, PO = 1 W, 1 kHz PGA = 12 dB, PO = 1 W, 1 kHz PGA = 18 dB, PO = 1 W, 1 kHz 1 kHz, A-weighted, 0 dB referred to 1% THD + N output 1 kHz, A-weighted, −60 dB referred to 1% THD + N output PGA = 0 dB, PO = 5 W, 1 kHz Table 4. DC Specifications Parameter INPUT IMPEDANCE OUTPUT DC OFFSET Typ 20 ±4 Unit kΩ mV Rev. 0 | Page 3 of 24 Test Conditions/Comments AINL, AINR input pins Independent of PGA setting AD1994 Table 5. Power Supplies Parameter ANALOG SUPPLY, AVDD Min 4.5 Typ 5.0 Max 5.5 Unit V DIGITAL SUPPLY, DVDD 4.5 5.0 5.5 V POWER TRANSISTOR SUPPLY, PVDD 6.5 8 to 20 22.5 V 0.6 7.5 19 1 11 40 μA μA μA RESET/POWER-DOWN CURRENT AVDD DVDD PVDD QUIESCENT CURRENT AVDD DVDD PVDD OPERATING CURRENT AVDD DVDD PVDD 20 5.5 30 mA mA mA 20 5.5 218 27 7 260 mA mA mA Test Conditions/Comments RESET held low 5V 5V 12 V Inputs grounded, nonoverlap = minimum 5V 5V 12 V VIN = 1 V rms, RL = 6 Ω, PO = 1 W 5V 5V 12 V Table 6. Digital I/O Parameter INPUT LOGIC HIGH INPUT LOGIC LOW OUTPUT LOGIC HIGH OUTPUT LOGIC LOW LEAKAGE CURRENT ON DIGITAL OUTPUTS Min 2.0 Typ Max 0.8 2.4 0.4 10 Unit V V V V μA Test Conditions/Comments @ 4 mA @ 4 mA Table 7. Digital Timing Typ 10 34 Unit μs μs Test Conditions/Comments Delay after MUTE is asserted until output stops switching Delay after MUTE is deasserted until output starts switching tMD tUD MUTE 05775-002 Parameter tMD tUD OUTx Figure 2. Mute and Unmute Delay Timing Rev. 0 | Page 4 of 24 AD1994 ABSOLUTE MAXIMUM RATINGS Table 8. Parameter AVDD, DVDD to AGND, DGND PVDDx to PGNDx 1 AGND to DGND to PGNDx AVDD, to DVDD Operating Temperature Range Storage Temperature Range Maximum Junction Temperature Thermal Resistance θJA θJC (at the Exposed Pad Surface) θJB (on JEDEC Standard PCB) 1 Rating −0.3 V to +6.5 V −0.3 V to +30.0 V −0.3 V to +0.3 V −0.5 V to +0.5 V –40°C to +85°C –65°C to +150°C 150°C Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 19.2°C/W 0.9°C/W 9.7°C/W Including any induced voltage due to inductive load. ESD CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although this product features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. Rev. 0 | Page 5 of 24 AD1994 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 MONO_EN NFL+ NFL– NC AINL NC MOD_FILT AVDD AGND REF_FILT NC AINR NC NFR– NFR+ MOD_EN PIN CONFIGURATION AND FUNCTION DESCRIPTIONS AD1994 TOP VIEW (Not to Scale) ERR2 ERR1 MODL/ERR0 MODR/DCTRL2 DCTRL1 DCTRL0 DGND DVDD DVDD DGND CLKI CLKO MUTE RESET PGA1 PGA0 NC = NO CONNECT PIN 1 INDICATOR 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 PGND2 PGND2 PGND2 OUTR+ OUTR+ OUTR+ PVDD2 PVDD2 PVDD2 PVDD2 OUTR– OUTR– OUTR– PGND2 PGND2 PGND2 05775-003 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 PGND1 PGND1 PGND1 OUTL+ OUTL+ OUTL+ PVDD1 PVDD1 PVDD1 PVDD1 OUTL– OUTL– OUTL– PGND1 PGND1 PGND1 Figure 3. Pin Configuration Table 9. Pin Function Descriptions Pin No. 1, 2, 3 4, 5, 6 7, 8, 9, 10 11, 12, 13 14, 15, 16 17 18 19 20 21 22 23, 26 24, 25 27 28 29 30 31 32 33, 34, 35 36, 37, 38 39, 40, 41, 42 43, 44, 45 46, 47, 48 49 Mnemonic PGND1 OUTL+ PVDD1 OUTL− PGND1 ERR2 ERR1 MODL/ERR0 MODR/DCTRL2 DCTRL1 DCTRL0 DGND DVDD CLKI CLKO MUTE RESET PGA1 PGA0 PGND2 OUTR− PVDD2 OUTR+ PGND2 MOD_EN In/Out O O O O O I/O I I I O I I I I O O I Description Negative Power Supply. Used for the A2 and B2 high power transistors. Output of Transistor Pair A1 and A2. Positive Power Supply. Used for the A1 and B1 high power transistors. Output of Transistor Pair B1 and B2. Negative Power Supply. Used for the A2 and B2 high power transistors. Active Low Thermal Shutdown. Active Low Thermal Warning Error Output. Active Low Overcurrent Error Output/Modulator Output Left. Nonoverlap Time Setting MSB/Modulator Output Right. Nonoverlap Time Setting. Nonoverlap Time Setting LSB. Negative Power Supply for Low Power Digital Circuitry. Positive Power Supply for Low Power Digital Circuitry. Clock Input for 256 × fS Audio Modulator Clock. Inverted Version of CLKI for Use with an External XTAL Oscillator. Active Low Mute Input. Active Low Reset Input. PGA Gain Control MSB. PGA Gain Control LSB. Negative Power Supply for High Power Transistors C2 and D2. Output of Transistor Pair D1 and D2. Positive Power Supply for High Power Transistors C1 and D1. Output of Transistor Pair C1 and C2. Negative Power Supply for High Power Transistors C2 and D2. Modulator Mode Enable Pin when Pulled to Logic High. Rev. 0 | Page 6 of 24 AD1994 Pin No. 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 Mnemonic NFR+ NFR− NC AINR NC REF_FILT AGND AVDD MOD_FILT NC AINL NC NFL− NFL+ MONO_EN In/Out I I I O O O I I I Description Right Channel Negative Feedback—Noninverting Input. Right Channel Negative Feedback—Inverting Input. No Connection—Should Be Left Floating. Analog Input for Right Channel. No Connection—Should Be Left Floating. Filter Pin for Band Gap Reference—Should Be Bypassed to AGND. Negative Power Supply for Low Power Analog Circuitry. Positive Power Supply for Low Power Analog Circuitry. Modulator Filter Pin—Used to Set Time Constant of Modulator Order Reduction Circuit. No Connection—Should Be Left Floating. Analog Input for Left Channel. No connection—Should Be Left Floating. Left Channel Negative Feedback—Inverting Input. Left Channel Negative Feedback—Noninverting Input. Mono Mode Enable Pin—When Pulled Up to Logic High. Rev. 0 | Page 7 of 24 AD1994 0 –20 –20 –80 –100 –120 –140 –160 0 2 4 6 8 10 12 14 16 18 20 FREQUENCY (kHz) –60 –80 –100 –120 –140 –160 0 –20 POWER (dBFS: 0dB = Power at which THD = 1% (10.1W)) –20 –40 –60 –80 –100 –120 –140 4 6 8 10 12 14 16 18 20 FREQUENCY (kHz) 0 POWER (dBFS: 0dB = Power at which THD = 1% (7.9W)) –80 –100 –120 –140 12 14 16 FREQUENCY (kHz) 2 4 6 8 10 12 14 16 18 20 18 20 FREQUENCY (kHz) 18 20 05775-006 POWER (dBFS: 0dB = Power at which THD = 1% (7.9W)) –60 10 20 Figure 8. −60 dBFS Output Power into 6 Ω Load –40 8 18 –140 –20 6 16 –120 –20 4 14 –100 0 2 12 –80 0 0 10 –60 Figure 5. 1 W Output Power into 6 Ω Load –160 8 –40 –160 05775-005 POWER (dBFS: 0dB = Power at which THD = 1% (10.1W)) 0 2 6 Figure 7. −60 dBFS Output Power into 4 Ω Load 0 0 4 FREQUENCY (kHz) Figure 4. 1 W Output Power into 4 Ω Load –160 2 05775-007 –60 –40 05775-008 –40 05775-009 POWER (dBFS: 0dB = Power at which THD = 1% (13.8W)) 0 05775-004 POWER (dBFS: 0dB = Power at which THD = 1% (13.8W)) TYPICAL PERFORMANCE CHARACTERISTICS Figure 6. 1 W Output Power into 8 Ω Load –40 –60 –80 –100 –120 –140 –160 0 2 4 6 8 10 12 14 16 FREQUENCY (kHz) Figure 9. −60 dBFS Output Power into 8 Ω Load Rev. 0 | Page 8 of 24 AD1994 0 0.1 –60 –70 THD (%) –40 –60 0.01 –80 –80 –90 0.001 –100 –100 –110 100 10k 1k FREQUENCY (Hz) Figure 10. IMD for 19 kHz/20 kHz Twin-Tone Stimulus with 1 W Total Output Power 0.0001 100 1k 10k FREQUENCY (Hz) Figure 13. THD vs. Frequency, 1 W Output Power into 4 Ω Load, PVDD = 12 V 40 0 –40 PGA GAIN = 18dB 35 25 PGA GAIN = 6dB 20 0.1 –60 –70 THD (%) PGA GAIN = 12dB PGA GAIN = 0dB 0.01 –80 15 –90 10 0.001 –100 5 –110 0.0001 1k 10k –120 FREQUENCY (Hz) Figure 11. Amplifier Gain vs. Frequency, 6 Ω Load, PVDD = 12 V Figure 14. THD vs. Frequency, 1 W Output Power into 6 Ω Load, PVDD = 12 V 0 0 –40 0.1 –60 –40 THD (%) –70 –60 L CHANNEL DRIVEN, R CHANNEL IDLE 0.01 –80 –90 –80 0.001 –100 –100 1k 10k FREQUENCY (Hz) Figure 12. Channel Separation vs. Frequency, Driven Channel Has 1 W Output Power into 6 Ω Load 0.0001 100 1k FREQUENCY (Hz) 10k –120 05775-015 –110 L CHANNEL IDLE, R CHANNEL DRIVEN 100 THD (dB, Relative to Fundamental) –50 –20 05775-012 SIGNAL IN IDLE CHANNEL (dB, Relative to Driven Channel Signal) 100 05775-014 10k 1k 05775-011 100 FREQUENCY (Hz) –120 THD (dB, Relative to Fundamental) –50 30 0 –120 05775-013 –120 THD (dB, Relative to Fundamental) –50 –20 –140 AMPLIFIER GAIN (dB) –40 0 05775-010 POWER (dB, Relative to 500mW) (Output Power in the 19k and 20k Tones) 20 Figure 15. THD vs. Frequency, 1 W Output Power into 8 Ω Load, PVDD = 12 V Rev. 0 | Page 9 of 24 AD1994 0.01 THD + N –80 –90 THD 0.001 0.1 10 1 –100 OUTPUT POWER (W) –90 –50 –60 0.1 –70 THD + N –80 0.01 –90 THD 0.001 0.1 10 1 –100 OUTPUT POWER (W) –50 –60 0.1 –70 0.01 THD + N –80 –90 0.001 0.1 THD 1 OUTPUT POWER (W) 10 –100 –50 –60 0.1 –70 THD + N –80 –90 0.001 0.1 1 10 –100 OUTPUT POWER (W) Figure 20. THD and THD + N vs. Output Power, 1 kHz Sine, 6 Ω Load, PVDD = 15 V 100 0 –10 –20 10 –30 THD or THD + N (%) –40 –40 1 THD THD or THD + N (dB, Relative to Fundamental) THD or THD + N (%) –30 1 –20 –30 0.01 –40 1 –50 –60 0.1 –70 0.01 THD + N –80 –90 05775-018 –20 10 0 10 0 –10 –100 –10 Figure 17. THD and THD + N vs. Output Power, 1 kHz Sine, 6 Ω Load, PVDD = 12 V 100 10 Figure 19. THD and THD + N vs. Output Power, 1 kHz Sine, 4 Ω Load, PVDD = 15 V THD or THD + N (%) –40 1 1 OUTPUT POWER (W) 05775-017 THD or THD + N (%) –30 THD 0.001 0.1 100 THD or THD + N (dB, Relative to Fundamental) –20 10 –80 0.01 0 –10 –70 THD + N Figure 16. THD and THD + N vs. Output Power, 1 kHz Sine, 4 Ω Load, PVDD = 12 V 100 –60 0.1 Figure 18. THD and THD + N vs. Output Power, 1 kHz Sine, 8 Ω Load, PVDD = 12 V THD or THD + N (dB, Relative to Fundamental) –70 –50 05775-019 –60 0.1 –40 1 THD or THD + N (dB, Relative to Fundamental) –50 –30 05775-020 –40 1 –20 10 0.001 0.1 THD 1 OUTPUT POWER (W) 10 –100 THD or THD + N (dB, Relative to Fundamental) THD or THD + N (%) –30 05775-021 –20 10 0 –10 THD or THD + N (%) –10 100 THD or THD + N (dB, Relative to Fundamental) 0 05775-016 100 Figure 21. THD and THD + N vs. Output Power, 1 kHz Sine, 8 Ω Load, PVDD = 15 V Rev. 0 | Page 10 of 24 AD1994 0.01 THD + N –80 –90 THD 0.001 0.1 10 1 –100 OUTPUT POWER (W) –90 –50 –60 0.1 –70 0.01 THD + N –80 –90 0.001 0.1 THD 10 1 –100 OUTPUT POWER (W) –40 1 –50 –60 0.1 –70 0.01 THD + N –80 –90 0.001 0.1 THD 1 OUTPUT POWER (W) 10 –100 –50 –60 0.1 –70 –80 –90 THD 0.001 0.1 10 1 –100 OUTPUT POWER (W) Figure 26. THD and THD + N vs. Output Power, 1 kHz Sine, 6 Ω Load, PVDD = 20 V 100 0 –10 –20 10 –30 THD or THD + N (%) –30 –40 1 THD + N THD or THD + N (dB, Relative to Fundamental) THD or THD + N (%) 10 –30 0.01 –40 1 –50 –60 0.1 –70 0.01 THD + N –80 –90 05775-024 –20 –20 10 0 –10 0 –10 Figure 23. THD and THD + N vs. Output Power, 1 kHz Sine, 6 Ω Load, PVDD = 18 V 100 –100 Figure 25. THD and THD + N vs. Output Power, 1 kHz Sine, 4 Ω Load, PVDD = 20 V THD or THD + N (%) –40 1 10 1 OUTPUT POWER (W) 05775-023 THD or THD + N (%) –30 THD 0.001 0.1 100 THD or THD + N (dB, Relative to Fundamental) –20 10 –80 0.01 0 –10 –70 THD + N Figure 22. THD and THD + N vs. Output Power, 1 kHz Sine, 4 Ω Load, PVDD = 18 V 100 –60 0.1 Figure 24. THD and THD + N vs. Output Power, 1 kHz Sine, 8 Ω Load, PVDD = 18 V THD or THD + N (dB, Relative to Fundamental) –70 –50 05775-025 –60 0.1 –40 1 THD or THD + N (dB, Relative to Fundamental) –50 –30 05775-026 –40 1 –20 10 0.001 0.1 THD 1 OUTPUT POWER (W) 10 –100 THD or THD + N (dB, Relative to Fundamental) THD or THD + N (%) –30 05775-027 –20 10 0 –10 THD or THD + N (%) –10 100 THD or THD + N (dB, Relative to Fundamental) 0 05775-022 100 Figure 27. THD and THD + N vs. Output Power, 1 kHz Sine, 8 Ω Load, PVDD = 20 V Rev. 0 | Page 11 of 24 50 100 45 90 40 80 THD = 10% 25 20 THD = 1% 15 10 10 12 14 16 18 20 0 45 90 40 80 35 70 OUTPUT POWER (W) 100 30 THD = 10% 20 THD = 1% 15 50 10 14 16 18 20 PVDD VOLTAGE (V) 0 05775-029 12 90 40 80 35 70 OUTPUT POWER (W) 100 45 30 25 THD = 10% 15 THD = 1% THD = 1% 8 10 12 14 16 18 20 60 50 40 THD = 10% 30 THD = 1% 20 8 10 12 14 16 18 20 PVDD VOLTAGE (V) Figure 30. Maximum Power vs. PVDD, Stereo Mode, 8 Ω Load 0 8 10 12 14 16 18 20 PVDD VOLTAGE (V) Figure 33. Maximum Power vs. PVDD, Mono Mode, 4 Ω Load Rev. 0 | Page 12 of 24 05775-033 10 05775-030 5 0 20 Figure 32. Maximum Power vs. PVDD, Mono Mode, 3 Ω Load 50 10 18 PVDD VOLTAGE (V) Figure 29. Maximum Power vs. PVDD, Stereo Mode, 6 Ω Load 20 16 THD = 10% 30 5 10 14 40 20 8 12 60 10 0 10 Figure 31. Maximum Power vs. PVDD, Mono Mode, 2 Ω Load 50 25 8 PVDD VOLTAGE (V) Figure 28. Maximum Power vs. PVDD, Stereo Mode, 4 Ω Load OUTPUT POWER PER CHANNEL (W) 30 5 8 THD = 1% 40 20 PVDD VOLTAGE (V) OUTPUT POWER PER CHANNEL (W) 50 10 0 THD = 10% 60 05775-032 30 70 05775-031 OUTPUT POWER (W) 35 05775-028 OUTPUT POWER PER CHANNEL (W) AD1994 AD1994 100 100 90 90 2 x8Ω LOAD 2 x4Ω LOAD 60 50 40 30 40 30 10 10 10 OUTPUT POWER PER CHANNEL (W) 0 0.1 Figure 37. Power Efficiency vs. Output Power, Mono Mode, PVDD = 12 V 4.0 8 ON-CHIP POWER DISSIPATION (W) 3.5 2 x4Ω LOAD 3.0 2.5 2.0 2 x6Ω LOAD 1.5 1.0 2 x8Ω LOAD 7 1 x2Ω LOAD 6 5 4 1 x3Ω LOAD 3 2 1 x4Ω LOAD 1 2 4 6 8 10 12 14 16 18 20 OUTPUT POWER PER CHANNEL (W) 0 05775-035 0 10 15 20 25 30 35 40 OUTPUT POWER (W) Figure 35. On-Chip Power Dissipation vs. Output Power, Stereo Mode, PVDD = 12 V Figure 38. On-Chip Power Dissipation vs. Output Power, Mono Mode, PVDD = 12 V 250 20 10 200 –30 –40 –50 150 COUNT 0 –10 –20 –60 –70 –80 –90 P-TYPE 25°C N-TYPE 25°C P-TYPE 130°C N-TYPE 130°C 100 –100 –110 –120 50 50 100 200 500 1k 2k 5k 10k 20k FREQUENCY (Hz) 05775-039 –130 –140 20 5 Figure 36. Power Supply Rejection Ratio (PSRR) vs. Frequency 0 100 120 140 160 180 200 220 240 260 280 300 320 340 360 380 400 MOSFET ON-RESISTANCE (mΩ) Figure 39. Histogram Showing Manufacturing Variation of RDS-ON of the Output MOSFETS at 25°C and 130°C Rev. 0 | Page 13 of 24 05775-036 0 05775-038 0.5 PSRR (dB) 10 1 OUTPUT POWER (W) Figure 34. Power Efficiency vs. Output Power, Stereo Mode, PVDD = 12 V ON-CHIP POWER DISSIPATION PER CHANNEL (W) 50 20 1 1 x2Ω LOAD 60 20 0 0.1 1 x3Ω LOAD 70 05775-037 POWER EFFICIENCY (%) 70 0 1 x4Ω LOAD 80 2 x6Ω LOAD 05775-034 POWER EFFICIENCY (%) 80 AD1994 100 20 90 18 ON-CHIP POWER DISSIPATION (W) 2 x8Ω LOAD 2 x6Ω LOAD 70 2 x4Ω LOAD 60 50 40 30 20 10 1 x2Ω LOAD 16 14 12 10 1 x3Ω LOAD 8 6 1 x4Ω LOAD 4 2 10 1 0 05775-040 0 0.1 OUTPUT POWER PER CHANNEL (W) 0 10 20 30 40 50 60 70 80 OUTPUT POWER (W) Figure 40. Power Efficiency vs. Output Power, Stereo Mode, PVDD = 18 V 05775-043 POWER EFFICIENCY (%) 80 Figure 42. On-Chip Power Dissipation vs. Output Power, Mono Mode, PVDD = 18 V 10 100 9 90 8 80 POWER EFFICIENCY (%) 2 x4Ω LOAD 7 6 5 4 2 x6Ω LOAD 3 2 x8Ω LOAD 2 1 x2Ω LOAD 60 50 40 30 10 0 5 10 15 20 25 30 OUTPUT POWER PER CHANNEL (W) Figure 41. On-Chip Power Dissipation vs. Output Power, Stereo Mode, PVDD = 18 V 35 40 0 0.1 1 OUTPUT POWER (W) 10 05775-042 1 0 1 x3Ω LOAD 70 20 05775-041 ON-CHIP POWER DISSIPATION PER CHANNEL (W) 1 x4Ω LOAD Figure 43. Power Efficiency vs. Output Power, Mono Mode, PVDD = 18 V Rev. 0 | Page 14 of 24 AD1994 THEORY OF OPERATION OVERVIEW The AD1994 is a 2-channel, high performance, switching, audio power amplifier. Each of the two Σ-Δ modulators converts a single-ended analog input into a 2-level pulse stream that controls the differential, full H-bridge, power output stage. The combination of an Σ-Δ modulator and a switching power stage provides an inherently linear and efficient means of amplifying the entire range of audio frequencies. The AD1994 also offers warning and protection circuits for overcurrent and overtemperature conditions, as well as silent turn-on and turn-off transitions. Σ-Δ MODULATOR The AD1994 is a switching type, also known as a Class-D, audio power amplifier. This class of amplifiers maximizes efficiency by only using its power output devices in full-on or full-off states. While most Class-D amplifiers use some variation of pulse-width modulation (PWM), the AD1994 uses Σ-Δ modulation to determine the switching pattern of the output devices. This provides a number of important benefits. Σ-Δ modulators do not produce a sharp peak with many harmonics in the AM frequency band as pulse-width modulators (PWM) often do. In addition, the 1-bit quantizer produces excellent linearity across the full amplitude range. Σ-Δ modulators require feedback to generate an error signal with respect to the input. The feedback voltages for the AD1994 modulators come from the outputs of the power devices and before the passive low-pass filters (see Figure 45). This compensates for nonlinear behavior in the power stage, such as nonoverlap time, mismatched rise and fall times, and propagation delays. It also reduces sensitivity to both dc and transient changes of the power supply voltage. Σ-Δ modulators operate in discrete time. As with all timequantized systems, the Nyquist frequency is equal to half of the sampling frequency and input signals above that point aliases back into the base band. The AD1994 sampling frequency (master clock) is equal to half the frequency of the input clock, approximately 6 MHz, so images only alias for input frequencies above approximately 3 MHz. This is far enough above the audio band that bandwidth and aliasing are not a problem in real applications. The AD1994 implements a seventh-order, Σ-Δ modulator with a 1-bit quantizer. Traditionally, higher-order designs such as this are not suitable for driving a Class-D amplifier because of stability problems at higher modulation factors. The modulator design of the AD1994 is unusual in that it is stable to 90% modulation. To allow the amplifier to drive even further, the AD1994 dynamically reverts from seventh order to second order above a fixed modulation threshold. The second-order modulator is unconditionally stable, including during prolonged voltage clipping conditions, enabling stable operation at full modulation. The dynamic-order reduction circuit uses the high-order modulator, except during the crests of the highest waveform peaks. During these peaks, the quantization noise increases, but the SNR is still quite high. These modulator order transitions are fast and smooth enough to avoid audible artifacts. The modulator has a noise shaping effect, and SNR is increased in the audio band by shifting the quantization noise upward in frequency. For a nominal input clock frequency of 12.288 MHz, the noise floor rises sharply above 20 kHz. The actual clock frequency used in an application circuit can deviate from this rate by as much as ±10%, and the corner frequency of the noise scales proportionately. The frequency at which the quantization noise dominates the output determines the amplifier’s practical bandwidth. The expected transition rate at the output of a typical seventhorder, Σ-Δ modulator would be high enough to negate much of the efficiency benefit of a switching amplifier. However, the AD1994 incorporates a proprietary, dynamic, switching rate, reduction scheme that lowers that average switching frequency by approximately a factor of four. This results in slightly increased output energy between 450 kHz and 500 kHz and efficiency on par with other Class-D amplifiers. This low-Q spectral boost is an artifact of the noise shaping and is in no way related to the carrier frequency visible in the spectrum of PWM Class-D amplifiers. MUTE AND RESET When power is applied and the RESET pin remains asserted, the AD1994 is in its lowest power consumption mode. The analog modulator is not running, and the power stage is tristated. On deasserting the RESET pin, the modulator begins a start-up sequence that includes initialization of the modulator, the protection circuits, and other functions. Once the start-up sequence is complete, the amplifier is in a state in which the modulator is running, but the output stage is not driven. When MUTE is deasserted, the output is started using a soft-start sequence that avoids any audible pop or click noise in the output signal. The output power transistors do not switch while MUTE remains asserted. Unlike the analog mute circuits found on some amplifiers that can be limited in their attenuation by the control logic or crosstalk, the mute attenuation on the AD1994 is greater than its dynamic range. The noise floor of the output signal also drops while in MUTE because the output transistors are not switching. Rev. 0 | Page 15 of 24 AD1994 Careful power-up is necessary when using the AD1994 to ensure correct operation and to avoid possible latch-up issues. The AD1994 should be powered up with RESET and MUTE held low until all the power supplies have stabilized. Once the supplies have stabilized, bring the AD1994 out of RESET by bringing RESET high. Begin the soft unmute sequence by bringing MUTE high at least 1 sec after the RESET rising edge. The amplifier produces audio using a shorter start-up sequence (as shown in Table 7), but the amplifier can produce an audible pop or click noise as the output starts switching. This is because the ac coupling capacitors at the analog input have a long time constant. If MUTE is deasserted substantially less than 1 sec after deasserting RESET, then these capacitors may not have charged to a steady state. They need ample time to settle at a bias voltage of VREF, the reference voltage for the single-ended inputs, or the amplifier starts with a slight dc offset. MONO MODE The power supply voltage and the limited current that the output transistors can source combine to dictate that maximum total output power of the AD1994. For higher impedance loads, the system is voltage limited, and for lower impedance loads, the system is current limited. In normal stereo operation, each output is driven by four MOSFET devices arranged in a full H-bridge configuration, also known as bridge-tied load (BTL). This provides the maximum differential output voltage swing, equal to twice the voltage of the power supply. However, operating in mono mode doubles the maximum achievable output current. When MONO_EN (Pin 64) is logic level high at the rising edge of RESET, the right channel modulator is disabled, and the left channel modulator is used to drive both the left and right output stages in parallel. When using mono mode, connect OUTL+ directly to OUTR+, connect OUTL− directly to OUTR−, and use the combined differential pair to a drive a single load. Connect the feedback pair to the positive and negative feedback input of the left modulator. The right channel feedback pins are unused in mono mode. The RDS-ON of the power FETs drops to half of its value in stereo operation because the devices are in parallel, and the AD1994 delivers its full current capability to a single channel. When the load impedance is substantially less than 4 Ω, the system would be current limited if configured for normal stereo operation, and the amplifier would enter the overcurrent error state when a nominal input signal is applied. Under these conditions, the amount of real power delivered to the load increases in mono mode. The minimum recommended impedance in mono mode is 2 Ω (as compared to 4 Ω for stereo operation), so the effective power delivered to a single channel can be as much as twice the maximum achievable in stereo mode. For reactive loads, the impedance can only be below the recommended threshold over a small portion of the amplifier’s bandwidth. In these cases, the amplifier can enter overcurrent shutdown in response to even small input signals in those frequency bands. When designing a system, use the minimum load impedance over the entire range of amplified frequencies when calculating current output rather than the average or nominal load impedance ratings often cited by loudspeaker driver manufacturers. MODULATOR MODE The AD1994 is capable of operating as a modulator for controlling external power devices. When MOD_EN (Pin 49) is logic level high at the rising edge of RESET, both the left and right internal power stages are disabled. The error output flags (ERR2, ERR1, and ERR0) and the nonoverlap delay inputs (DCNTL2, DCNTL1, and DCNTL0) no longer have meaning because they apply only to the internal power stages. The logic level outputs from the two modulators appear on Pin 19 (MODL) and Pin 20 (MODR). GAIN STRUCTURE Analog Input Levels The AD1994 has single-ended inputs for the left and right channels. The analog input section uses an internal amplifier to bias the input signal to the reference level, VREF, which is nominally equal to AVDD/2. A dc-blocking capacitor, as shown in Figure 44, prevents this bias voltage from affecting the signal source. In combination with the nominal 20 kΩ input impedance, the value of this capacitor should be large enough to produce a flat frequency response at the lowest input frequency of interest. Note that the amplifier is capable of dc-coupled operation if the circuit includes some means to account for this bias voltage. Note that the practical effect of mono mode depends greatly on the load impedance. If the load is 4 Ω or greater, the efficiency of the amplifier increases due to the reduced effective resistance of power FETs, and the amplifier dissipates less heat. However, the amount of real power delivered to the load does not increase because the system is voltage limited (that is, the output waveform voltage clips before current limiting occurs). Rev. 0 | Page 16 of 24 0V + AINL/ AINR 05775-044 Power-Up Sequencing Figure 44. AC-Coupled Input Signal AD1994 Setting the Modulator Gain Programmable Gain Amplifier (PGA) The AD1994 modulator uses a combination of the input signal and feedback from the power output stage to calculate its twostate output pattern. The feedback input nodes are part of the internal analog circuit that operates from the AVDD (nominal 5 V) power supply. Because the voltage measured at the power outputs is nominally between 0 V and PVDD, and thus beyond the 0 V to AVDD range, a voltage divider is required to scale the feedback to an appropriate level. The Σ-Δ modulator itself requires a fixed gain for a given value of PVDD to maintain optimal stability. This gain can be appropriate, but many applications require more gain to account for low source signal levels. The AD1994 includes a programmable gain amplifier (PGA) to boost the overall amplifier gain. PGA1 (Pin 31) and PGA0 (Pin 32) select one of four PGA gain values, as shown in Table 11. Table 11. PGA Gain Settings Resistor voltage dividers should sense the voltage on each side of the differential output and provide these feedback signals to the modulator, as shown in Figure 45. PVDD PGA1 0 0 1 1 PVDD EXTERNAL COMPONENTS D1 L RL OUTx+ D2 R1 C D3 L OUTx– C R3 D4 PGND PGND NFx– R2 R4 05775-045 NFx+ The AD1994 incorporates a single-ended-to-differential converter for each channel in the analog front-end section. The PGA is also part of this analog front-end, and it affects the analog input signal before it enters the Σ-Δ modulator. The PGA1 and PGA0 pins are continuously monitored and allow the gain to be changed at any time. The H-Bridge The resistor values should satisfy the following equation to maintain modulator stability. R1 + R2 R3 + R 4 PVDD = = 3.635 R2 R4 Selecting a gain that meets this criterion ensures that the modulator remains in a stable operating condition. The ratio of the resistances sets the gain rather than the absolute values. However, the dividers provide a path from the high voltage supply to ground; therefore, the values should be large enough to produce negligible loss due to quiescent current. The chip contains a calibration circuit to minimize voltage offsets at the speaker, which helps to minimize clicks and pops when muting or unmuting. Optimal performance is achieved for the offset calibration circuit when the feedback divider resistors sum to 6 kΩ, that is, (R1 + R2) = 6 kΩ, and (R3 + R4) = 6 kΩ. The output stage of the AD1994 includes four integrated MOSFET devices arranged in a full H-bridge, as shown in Figure 45. The P-Type, high-side transistor of one leg and the N-Type, low-side transistor of the opposite leg switch on and off as a pair producing a total voltage swing across the load of −PVDD to +PVDD. The drive is floating and differential, and it is important that neither output terminal be shorted to ground. The power supply for the output stage of the AD1994, PVDD, should be in the 8 V to 20 V range and should be capable of supplying enough current to drive the load. Connect the power supply across the PVDD and PGND pins. The feedback pins, NFR+, NFR−, NFL+, and NFL−, supply negative feedback to the modulator as described in the Setting the Modulator Gain section. Table 10. Recommended Feedback Resistor Values PVDD (V) 12 15 18 20 R1 (kΩ) 4.2 4.55 4.8 4.91 R2 (kΩ) 1.8 1.45 1.2 1.09 PGA Gain (dB) 0 6 12 18 POWER STAGE Figure 45. H-Bridge Configuration Gain = PGA0 0 1 0 1 Gain 3.3 (+10.4 dB) 4.1 (+12.3 dB) 5.0 (+14.0 dB) 5.5 (+14.8 dB) Rev. 0 | Page 17 of 24 AD1994 Output Transistor Nonoverlap Time The AD1994 allows the user to select from one of eight different nonoverlap times, as shown in Figure 46. Nonoverlap time prevents or minimizes the period during which both the highside and low-side devices are on simultaneously due to propagation delays and nonzero rise and fall times. If both the upper and lower portions of a half-bridge conduct simultaneously, there is a path directly from the power supply to ground and an induced current flow known as shoot-through. However, introducing this delay increases distortion by pushing the switching pattern further from an ideal two-state waveform. Selecting the nonoverlap delay requires a compromise between distortion and efficiency. The logic levels on the three delay control pins, DCTRL2, DCTRL1, and DCTRL0, set the nonoverlap time according to Table 12. The state of DCTRL[2:0] is read on the rising edge of RESET and should not be changed while RESET is logic high. Table 12. Nonoverlap Time Settings DCTRL2 DCTRL1 DCTRL0 Nonoverlap Time (ns)1 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 62 49 37 24 15 13.5 12 9 The clock frequency does not have to be exactly equal to 12.288 kHz and can vary by up to ±10%. For other rates, the noise corner scales linearly with frequency. When the modulator runs at a rate lower than nominal, the average power stage switching frequency decreases, the efficiency increases slightly, and the noise floor begins to rise at a slightly lower frequency. Likewise, a faster clock gives slightly increased bandwidth and slightly lower efficiency. Using a Crystal Oscillator The AD1994 can use a crystal connected to the CLKI and CLKO pins as a master clock source, as shown in Figure 47. The CLKI and CLKO pins connect to an internal inverter to create a full resonator. The typical values shown work in many applications, but the crystal manufacturer should provide the exact type and value of the capacitors and the resistor. 22pF XTAL 22pF 47Ω CLKI HIGH-SIDE GATE DRIVE tNOL tNOL 05775-046 LOW-SIDE GATE DRIVE 05775-047 Values are typical and are not production tested. CLKO 1 As mentioned in the Σ-Δ Modulator section, the modulator has a noise-shaping effect such that SNR is increased within the audio band by shifting modulator quantization noise upward in frequency. For external clock frequency of 12.288 MHz, the modulator’s noise-shaping works in a manner that results in a flat noise floor at the amplifier output for frequencies 20 kHz and below. Above 20 kHz, the amplifier noise rises due to the spectral shaping of the modulator quantization noise. At very high frequencies, the noise floor levels off and decreases due to poles in the modulator noise-transfer function and in the external LC filter. Figure 47. Crystal Connection Using an External Clock Source Figure 46. Half-Bridge Nonoverlap Delay Timing The shortest setting (DCTRL[2:0] = 111) or the second shortest setting (DCTRL[2:0] = 111) is recommended for most applications. These two settings allow a small trade-off between efficiency and distortion. Longer nonoverlap times generally increase distortion while providing little or no decrease in shootthrough current. CLOCKING The AD1994 Σ-Δ modulator requires an external clock source with a nominal frequency of 12.288 MHz. This clock can come from a crystal or from an existing clock signal in the application circuit. The discrete time portions of the modulator run internally at 6.144 MHz, corresponding to 128 × fS, where fS = 48 kHz. If a clock signal of the appropriate frequency already exists in the application circuit, connect it directly to CLKI and leave CLKO floating. The logic levels of the square wave should be compatible with those defined in Specifications section. Large amounts of jitter on the clock input degrade performance. Whenever possible, avoid passing the clock signal though programmable logic and other circuits with unknown or variable propagation delay. In general, clock signals suitable for audio ADCs or DACs are also appropriate for use with the AD1994. Rev. 0 | Page 18 of 24 AD1994 Clocking Multiple Amplifiers in Parallel Overcurrent Protection If there are multiple AD199x family amplifiers connected to the same PVDD supply, use the same clock source (or synchronous derivatives) for each amplifier as previously described. Avoid clocking amplifiers from similar but asynchronous clocks if they use the same power supply because this can result in beat frequencies. The AD1994 features over current or short-circuit protection. If the current through any power transistors exceeds approximately 4 A, the part enters a mute state and the overcurrent error output (ERR0) is asserted. This is a latched error and does not clear automatically. Restore normal operation and clear the error condition by either asserting and then negating RESET or by asserting and then negating MUTE. PROTECTION CIRCUITS AND ERROR REPORTING Thermal Protection The AD1994 features thermal protection. When the die temperature exceeds approximately 135°C, the thermal warning error output (ERR1) is asserted. If the die temperature exceeds approximately 150°C, the thermal shutdown error output (ERR2) is asserted. If this occurs, the part shuts down to prevent damage to the part. When the die temperature drops below approximately 120°C, the part returns to normal operation automatically and negates both error outputs. Rev. 0 | Page 19 of 24 AD1994 APPLICATION CIRCUITS DVDD PVDD + 0.1µF + 47µF AVDD PVDD + 0.1µF 0.1µF 1000µF + 0.1µF 47µF + PVDD2 PVDD1 10µF DVDD AVDD 1000µF PVDD L AINL OUTL+ C R1 NFL+ 10µF + R2 AINL R2 NFL– 6.8µF + MOD_FILT PVDD R1 10kΩ OUTL– L AD1994 PVDD REF_FILT 4.7µF + C 0.1µF L OUTR+ C R1 NFR+ PGA0 R2 PGA1 DCTRL2 DIGITAL INPUTS R2 DCTRL1 NFR– DCTRL0 R1 MUTE OUTR– RESET THERMAL SHUTDOWN ERR2 THERMAL WARNING ERR1 OVERCURRENT ERR0 PVDD L C R1 = 4.2kΩ R2 = 1.8kΩ L = 18µH C = 1µF LOAD = 6Ω 05775-048 PGND2 PGND1 DGND CLKO AGND CLKI Figure 48. Typical Stereo Circuit Rev. 0 | Page 20 of 24 AD1994 OUTLINE DIMENSIONS 9.00 BSC SQ 0.30 0.25 0.18 0.60 MAX 0.60 MAX 64 1 48 49 PIN 1 INDICATOR PIN 1 INDICATOR 8.75 BSC SQ TOP VIEW (BOTTOM VIEW) 0.45 0.40 0.35 12° MAX SEATING PLANE 33 17 16 32 7.50 REF 0.80 MAX 0.65 TYP 0.25 MIN 0.05 MAX 0.02 NOM 0.50 BSC 0.20 REF COMPLIANT TO JEDEC STANDARDS MO-220-VMMD-4 122105-0 1.00 0.85 0.80 7.25 7.10 SQ 6.95 EXPOSED PAD Figure 49. 64-Lead Lead Frame Chip Scale Package [LFCSP_VQ] 9 mm × 9 mm Body, Very Thin Quad (CP-64-3) Dimension shown in millimeters ORDERING GUIDE Model AD1994ACPZ 1 AD1994ACPZRL1 AD1994ACPZRL71 EVAL-AD1994EB 1 Temperature Range −40°C to +85°C −40°C to +85°C −40°C to +85°C Package Description 64-Lead Lead Frame Chip Scale Package (LFCSP_VQ) 64-Lead Lead Frame Chip Scale Package (LFCSP_VQ), 13” Tape and Reel 64-Lead Lead Frame Chip Scale Package (LFCSP_VQ), 7” Tape and Reel Evaluation Board Z = Pb-free part. Rev. 0 | Page 21 of 24 Package Option CP-64-3 CP-64-3 CP-64-3 AD1994 NOTES Rev. 0 | Page 22 of 24 AD1994 NOTES Rev. 0 | Page 23 of 24 AD1994 NOTES ©2006 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D05775-0-2/06(0) Rev. 0 | Page 24 of 24