TAS5342DDV6EVM

User's Guide SLAU239A – February 2008 – Revised September 2015 TAS5342DDV6EVM This user’s guide describes the operation of the evaluation module for the TAS5342 Digital Amplifier Power Output Stage using the TAS5508B Digital Audio PWM Processor from Texas Instruments. The user’s guide also provides measurement data and design information like schematic, bill of materials, and PCB layout. 1 2 3 4 5 Contents Overview ...................................................................................................................... 3 1.1 TAS5342DDV6EVM Features..................................................................................... 4 1.2 PCB Key Map ....................................................................................................... 5 Quick Setup Guide........................................................................................................... 6 2.1 Electrostatic Discharge Warning .................................................................................. 6 2.2 Unpacking the EVM ................................................................................................ 7 2.3 Power Supply Setup ................................................................................................ 7 2.4 Speaker Connection ................................................................................................ 7 2.5 GUI Software Installation .......................................................................................... 8 Protection ..................................................................................................................... 8 3.1 Short-Circuit Protection and Fault-Reporting Circuitry ......................................................... 8 3.2 Fault Reporting ...................................................................................................... 8 TAS5342DDV6EVM Performance ......................................................................................... 9 4.1 THD+N vs Power (BTL –4 Ω) ................................................................................... 11 4.2 THD+N vs Power (BTL –6 Ω) ................................................................................... 11 4.3 THD+N vs Power (BTL –8 Ω) ................................................................................... 12 4.4 THD+N vs Power (PBTL –2 Ω) .................................................................................. 12 4.5 THD+N vs Power (PBTL –3 Ω) .................................................................................. 13 4.6 THD+N vs Frequency (BTL –4 Ω) .............................................................................. 14 4.7 THD+N vs Frequency (BTL – 6 Ω).............................................................................. 14 4.8 THD+N vs Frequency (BTL –8 Ω) .............................................................................. 15 4.9 THD+N vs Frequency (PBTL –2 Ω) ............................................................................. 15 4.10 THD+N vs Frequency (PBTL –3 Ω) ............................................................................. 16 4.11 FFT Spectrum with –60-dBFS Tone (BTL) .................................................................... 16 4.12 FFT Spectrum With –60-dBFS Tone (PBTL) .................................................................. 16 4.13 Idle Noise FFT Spectrum (BTL) ................................................................................. 17 4.14 Idle Noise FFT Spectrum (PBTL) ............................................................................... 17 4.15 Channel Separation ............................................................................................... 18 4.16 Frequency Response (BTL)...................................................................................... 19 4.17 Frequency Response (PBTL) .................................................................................... 19 4.18 High-Current Protection (BTL) ................................................................................... 19 4.19 High-Current Protection (PBTL) ................................................................................. 20 4.20 Pop/Click (BTL) .................................................................................................... 21 4.21 Pop/Click (PBTL) .................................................................................................. 21 4.22 Output Stage Efficiency .......................................................................................... 22 4.23 Subwoofer Lineout THD vs Output Voltage ................................................................... 22 4.24 Subwoofer Lineout THD vs Frequency ......................................................................... 23 4.25 Subwoofer Lineout Frequency Response ...................................................................... 23 Related Documentation from Texas Instruments ...................................................................... 24 PurePath Digital, Equibit are trademarks of Texas Instruments. Microsoft, Windows are registered trademarks of Microsoft Corporation. SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated TAS5342DDV6EVM 1 www.ti.com 5.1 Appendix A Additional Documentation ........................................................................................ 24 Design Documents ................................................................................................ 25 List of Figures 1 Integrated PurePath Digital™ Amplifier System ......................................................................... 5 2 Physical Structure for the TAS5342DDV6EVM (Approximate Layout) ............................................... 6 3 TAS5508 GUI Window ...................................................................................................... 8 4 THD+N vs Power (BTL – 4 Ω) ............................................................................................ 11 5 THD+N vs Power (BTL –6 Ω) 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 ............................................................................................ THD+N vs Power (BTL –8 Ω) ............................................................................................ THD+N vs Power (PBTL –2 Ω) ........................................................................................... THD+N vs Power (PBTL –3 Ω) ........................................................................................... THD+N vs Frequency (BTL –4 Ω) ....................................................................................... THD+N vs Frequency (BTL – 6 Ω)....................................................................................... THD+N vs Frequency (BTL –8 Ω) ....................................................................................... THD+N vs Frequency (PBTL –2 Ω) ...................................................................................... THD+N vs Frequency (PBTL –3 Ω) ...................................................................................... FFT Spectrum with –60-dBFS Tone (BTL) ............................................................................. FFT Spectrum with –60-dBFS Tone (PBTL) ............................................................................ Idle Noise FFT Spectrum (BTL) .......................................................................................... Idle Noise FFT Spectrum (PBTL) ........................................................................................ Channel Separation ........................................................................................................ Frequency Response (BTL)............................................................................................... Frequency Response (PBTL) ............................................................................................. High-Current Protection (BTL) ............................................................................................ High-Current Protection (PBTL) .......................................................................................... Pop/Click (BTL) ............................................................................................................. Pop/Click (PBTL) ........................................................................................................... Output Stage Efficiency ................................................................................................... Subwoofer Lineout THD vs Output Voltage ............................................................................ Subwoofer Lineout THD vs Frequency .................................................................................. Subwoofer Lineout Frequency Response ............................................................................... 12 12 13 13 14 14 15 15 16 16 17 17 18 18 19 19 20 20 21 21 22 22 23 23 List of Tables 1 TAS5342DDV6EVM Specification ......................................................................................... 3 2 Recommended Supply Voltages for Power Stage 3 4 5 6 7 8 9 10 11 12 2 ...................................................................... 7 Supply Adapter for System Power, Logic and Gate Driver Characteristics .......................................... 7 TAS5342 Warning/Error Signal Decoding ................................................................................ 9 General Test Conditions .................................................................................................... 9 TAS5508B Register Settings ............................................................................................... 9 Electrical Data ................................................................................................................ 9 Audio Performance ......................................................................................................... 10 Audio Performance Subwoofer Line Output ............................................................................ 10 Thermal Specification ...................................................................................................... 10 Physical Specifications .................................................................................................... 11 Related Documentation from Texas Instruments ...................................................................... 24 TAS5342DDV6EVM SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated Overview www.ti.com 1 Overview The TAS5342DDV6EVM PurePath Digital™ customer evaluation module demonstrates the integrated circuits TAS5342DDV and TAS5508BPAG from Texas Instruments (TI). The TAS5342DDV is a high-performance, integrated stereo Digital Amplifier Power Stage designed to drive 4-Ω speakers at up to 100 W per channel. The device incorporates TI Equibit™ technology and is designed to be used with TI Equibit™ modulators. This system requires only a simple passive demodulation filter to deliver high-quality, high-efficiency audio amplification. The TAS5508BPAG is a high-performance, 32-bit (24-bit input) multichannel PurePath Digital™ pulse width modulator (PWM) based on Equibit™ technology with fully symmetrical AD modulation scheme. The device also has digital audio processing (DAP) that provides 48-bit signal processing, advanced performance, and a high level of system integration. The device has interfaces for headphone output and power supply volume control (PSVC). This EVM is configured with four BTL channels, one PBTL (parallel BTL) channel for the center channel, and a subwoofer lineout using the DRV600 line driver. The DRV600RTJ is a stereo line driver designed to allow the removal of the DC-blocking capacitors for reduced component count and cost. The DRV600RTJ is ideal for single-supply electronics where size and cost are critical design parameters. The DRV600RTJ is capable of driving two VRMS into a 600-Ω load with a 3.3-V supply. The DRV600RTJ has a fixed gain of –1.5 V/V. Independent shutdown control for the left and right audio channels is implemented. This EVM, together with a TI input-USB board, is a complete 5-channel + subwoofer line-output digital audio amplifier system which includes digital input (S/PDIF), analog inputs, interface to a personal computer (PC), and DAP features like digital volume control, input and output mixers, automute, tone controls, loudness, EQ filters, and dynamic range compression (DRC). Configuration options are available for power stage failure protection. Table 1. TAS5342DDV6EVM Specification Key Parameters Output stage supply voltage 0 V – 31.5 V Number of channels 4 × BTL, 1 x PBTL 4–8 Ω Load impedance BTL 2–8 Ω Load impedance PBTL 120 W / 4 Ω 10% THD or 87 W / 6 Ω / 10% THD Output power BTL 225 W / 2 Ω / 10% THD Output power PBTL DNR >102 dB PWM processor TAS5508BPAG Output stage TAS5342DDV Other features Subwoofer line output This 5-channel system plus subwoofer line output is designed for home theater applications such as A/V receivers, DVD receivers, DVD mini-component systems, or home theater in a box (HTIB). This document covers EVM specifications, audio performance and power efficiency measurements graphs, and design documentation that includes schematics, parts list, layout, and mechanical design. SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated TAS5342DDV6EVM 3 Overview www.ti.com Gerber (layout) files are available at www.ti.com. The EVM is delivered with cables and an Input-USB board to connect to an input source and be controlled from a PC. An external power adapter is required for supplying the voltage to the Input USB-2 Control Board. Refer to the Power Supply Setup section for more information. 1.1 TAS5342DDV6EVM Features • • • • • 4 5/6-channel PurePath Digital™ evaluation module Subwoofer line output (LFE Output). Self-contained protection system (short circuit and thermal). Standard I2S and I2C/control connector for TI input board Double-sided, plated-through PCB layout. TAS5342DDV6EVM SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated Overview www.ti.com Subwoofer Line Out 8 Channel Analog Input Control Interface USB Interface Optical and Coaxia S/Pl DIF Input TAS5342DDV6EVM MODULE 5/6 Channel Speaker Output I2C Bus I2S Bus Example TI Input- USB board Power Supply Figure 1. Integrated PurePath Digital™ Amplifier System 1.2 PCB Key Map Physical structure for the TAS5342DDV6EVM is illustrated in Figure 2. SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated TAS5342DDV6EVM 5 Quick Setup Guide J107 BTL* www.ti.com J117 PBTL J104 BTL J108 BTL* J102 BTL SPEAKER OUTPUTS J101 BTL SPEAKER OUTPUTS PSU INTERFACE (J901) OUTPUT STAGE CHANNEL 1 OUTPUT STAGE CHANNEL 2 OUTPUT STAGE CHANNEL 3 OUTPUT STAGE CHANNEL 4 OUTPUT STAGE CHANNEL 5 OUTPUT STAGE CHANNEL 6 PSU CONTROL (J902) SPEAKER OUTPUTS J103 BTL TAS5508b SUBWOOFER OUTPUT (J600) DRV600 3.3V Regulator INPUT SIGNAL & CONTROL INTERFACE (J10) *: Config Option Figure 2. Physical Structure for the TAS5342DDV6EVM (Approximate Layout) 2 Quick Setup Guide This section describes the TAS5342DDV6EVM board in regards to power supplies and system interfaces. Included is information regarding handling and unpacking, absolute operating conditions, and a description of the factory default switch and jumper configuration. A step-by-step guide explains how to configure the TAS5342DDV6EVM for device evaluation. 2.1 Electrostatic Discharge Warning Many of the components on the TAS5342DDV6EVM are susceptible to damage by electrostatic discharge (ESD). Customers are advised to observe proper ESD handling precautions when unpacking and handling the EVM, including the use of a grounded wrist strap at an approved ESD workstation. CAUTION Failure to observe ESD handling procedures may result in damage to EVM components. 6 TAS5342DDV6EVM SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated Quick Setup Guide www.ti.com 2.2 Unpacking the EVM On opening the TAS5342DDV6EVM package, ensure that the following items are included: • 1 pc. TAS5342DDV6EVM board using one TAS5508BPAG and three TAS5342DDV. • 1 pc. TI Input USB Board 2 for interfacing TAS5342DDV6EVM with S/PDIF/analog sources and PC for control. • 1 pc. Signal and Control Interface IDC cable for connection to a TI Input USB Board 2. • 1 pc. Cable for connecting Input-USB board to a USB port on a PC for TAS5508B control by software. • 1 pc. Power supply cable for a regulated power supply (H-bridge supply). If any of the items are missing, contact the Texas Instruments Product Information Center nearest you to inquire about a replacement. Connect Input-USB board to TAS5342DDV6EVM using the delivered IDC cable. 2.3 Power Supply Setup To power up the EVM, two power supplies are needed. One for system power, logic, and gate-drive, and one for output stage supply. The H-bridge power supply is connected to the EVM using the delivered power cable White/Black, White/Black. The system, logic and gate drive power supply must be supplied from an external 15-V, 1-A adapter. The characteristics of this adapter can be found in Table 3. Table 2. Recommended Supply Voltages for Power Stage Description Voltage Limitations Current Requirement Cable Output stage power supply 0 – 31.5 V 10 A White/Black Table 3. Supply Adapter for System Power, Logic and Gate Driver Characteristics Description Requirement DC Output Voltage 15 V Output Current 1A Max Power Rating 15 W DC Output Connector 5.5 mm x 2.1 mm x 10 mm center positive barrel plug CAUTION Applying voltages above the limitations given in Table 2 may cause permanent damage to your hardware. NOTE: The length of the power supply cable must be minimized. Increasing the length of the PSU cable is equal to increasing the distortion for the amplifier at high output levels and low frequencies. 2.4 Speaker Connection CAUTION Both positive and negative speaker outputs are floating and may not be connected to ground (e.g., through an oscilloscope). SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated TAS5342DDV6EVM 7 Quick Setup Guide 2.5 www.ti.com GUI Software Installation The TAS5508 GUI provides easy control of all registers in TAS5508B. The latest TAS5508 GUI can be downloaded from the TAS5342DDV6EVM product folder on www.ti.com. To install the software, run the setup file of the GUI. After installation, turn on power supplies and connect USB cable to Input-USB board. Start the GUI program from Microsoft® Windows® menu. Start up of the GUI takes a few seconds. Figure 3. TAS5508 GUI Window For more advanced use of the GUI, see the GUI User’s Guide and data manual for TAS5508B (SLES162). 3 Protection This section describes the short-circuit protection and fault-reporting circuitry of the TAS5342 device. 3.1 Short-Circuit Protection and Fault-Reporting Circuitry The TAS5342 is a self-protecting device that provides fault reporting (including high-temperature protection and short-circuit protection). The TAS5342 is configured in back-end auto-recovery mode and therefore resets automatically after all errors (M1, M2, and M3 is set low); see the data sheet (SLAS557) for further explanation. This mean that the device restart itself after an error occasion and reports shortly thereafter through the SD error signal. 3.2 Fault Reporting The OTW and SD outputs from TAS5342 indicate fault conditions. See the TAS5342 data manual for a description of these pins. 8 TAS5342DDV6EVM SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated TAS5342DDV6EVM Performance www.ti.com Table 4. TAS5342 Warning/Error Signal Decoding OTW SD 0 0 Device Condition High-temperature error and/or high-current error 0 1 High-temperature warning 1 0 Undervoltage lockout or high-current error 1 1 Normal operation, no errors/warnings The temperature warning signals at the TAS5342DDV6EVM board are wired-OR to one temperature warning signal (OTW – pin 22 in the control interface connector). Shutdown signals are wired-OR into one shutdown signal (SD – pin 20 in the control interface connector). The shutdown signals together with the temperature warning signal give chip-state information as described in the Table 4. device fault-reporting outputs are open-drain outputs. 4 TAS5342DDV6EVM Performance Table 5. General Test Conditions General Test Conditions Notes Output stage supply voltage: 31.5 V Laboratory power supply (EA-PS 7065-10A) Load impedance BTL: 4–8 Ω Load impedance PBTL: 2–4 Ω Input signal 1 kHz sine Sampling frequency 48 kHz Gain setting in TAS5508B 0 dB Measurement filter AES17 and AUX0025 TI input board Input-USB2 Rev 1 EVM configuration file Ver 1.00 TAS5342DDV6EVM Configuration (1.00).cfg Note: These test conditions are used for all tests, unless otherwise specified. Table 6. TAS5508B Register Settings Register Register Value Notes Modulation Index Limit 0x16 0x02 Set modulation index to 97.7% Master Volume 0xD9 00 00 00 48 Master volume set to 0 dB Note: These register settings are used for all test, unless otherwise specified. Table 7. Electrical Data Electrical Data Output power, BTL, 4 Ω: Output power, BTL, 4 Ω: Output power, BTL, 6 Ω: Output power, BTL, 6 Ω: Output power, BTL, 8 Ω: Output power, BTL, 8 Ω: Output power, PBTL, 2 Ω: Output power, PBTL, 2 Ω: Output power, PBTL, 3 Ω: Output power, PBTL, 3 Ω: Maximum peak current, BTL: Maximum peak current, PBTL: Output stage efficiency: Damping factor BTL: 90 W 120 W 66 W 87 W 51 W 68 W 170 W 225 W 130 W 170 W >10 A >20 A 90% 8.5 Notes/Conditions 1 kHz, unclipped (0 dBFS), TA = 25°C 1 kHz, 10% THD+N, TA = 25°C 1 kHz, unclipped (0 dBFS), TA = 25°C 1 kHz, 10% THD+N, TA = 25°C 1 kHz, unclipped (0 dBFS), TA = 25°C 1 kHz, 10% THD+N, TA = 25°C 1 kHz, unclipped (0 dBFS), TA = 25°C 1 kHz, 10% THD+N, TA = 25°C 1 kHz, unclipped (0 dBFS), TA = 25°C 1 kHz, 10% THD+N, TA = 25°C 1-kHz burst, 1 Ω, ROC = 27 kΩ 1-kHz burst, 1 Ω, ROC = 27 kΩ 2 x channels, 8 Ω 1 kHz, relative to 4-Ω load SLAU239A – February 2008 – Revised September 2015 Submit Documentation Feedback Copyright © 2008–2015, Texas Instruments Incorporated TAS5342DDV6EVM 9 TAS5342DDV6EVM Performance www.ti.com Table 7. Electrical Data (continued) Electrical Data Damping factor PBTL: H-bridge supply current: Idle power consumption: Notes/Conditions 9.4 1 kHz, relative to 2-Ω load