Author Chassaing, Rulph
Title Digital Signal Processing and Applications with the C6713 and C6416 DSK
Imprint Hoboken : John Wiley & Sons, Incorporated, 2004
©2005
book jacket
Edition 1st ed
Descript 1 online resource (542 pages)
text txt rdacontent
computer c rdamedia
online resource cr rdacarrier
Series Topics in Digital Signal Processing Ser. ; v.16
Topics in Digital Signal Processing Ser
Note Intro -- Digital Signal Processing and Applications with the C6713 and C6416 DSK -- TOPICS IN DIGITAL SIGNAL PROCESSING -- Contents -- Preface -- List of Examples -- Programs/Files on Accompanying CD -- 1 DSP Development System -- 1.1 Introduction -- 1.2 DSK Support Tools -- 1.2.1 DSK Board -- 1.2.2 TMS320C6713 Digital Signal Processor -- 1.3 Code Composer Studio -- 1.3.1 CCS Installation and Support -- 1.3.2 Useful Types of Files -- 1.4 Quick Test of DSK -- 1.5 Support Files -- 1.6 Programming Examples to Test the DSK Tools -- 1.7 Support Programs/Files Considerations -- 1.7.1 Initialization/Communication File -- 1.7.2 Vector File -- 1.7.3 Linker Command File -- 1.8 Compiler/Assembler/Linker Shell -- 1.8.1 Compiler -- 1.8.2 Assembler -- 1.8.3 Linker -- 1.9 Assignments -- References -- 2 Input and Output with the DSK -- 2.1 Introduction -- 2.2 TLV320AIC23 (AIC23) Onboard Stereo Codec for Input and Output -- 2.3 Programming Examples Using C Code -- 2.4 Assignments -- References -- 3 Architecture and Instruction Set of the C6x Processor -- 3.1 Introduction -- 3.2 TMS320C6x Architecture -- 3.3 Functional Units -- 3.4 Fetch and Execute Packets -- 3.5 Pipelining -- 3.6 Registers -- 3.7 Linear and Circular Addressing Modes -- 3.7.1 Indirect Addressing -- 3.7.2 Circular Addressing -- 3.8 TMS320C6x Instruction Set -- 3.8.1 Assembly Code Format -- 3.8.2 Types of Instructions -- 3.9 Assembler Directives -- 3.10 Linear Assembly -- 3.11 ASM Statement within C -- 3.12 C-Callable Assembly Function -- 3.13 Timers -- 3.14 Interrupts -- 3.14.1 Interrupt Control Registers -- 3.14.2 Interrupt Acknowledgment -- 3.15 Multichannel Buffered Serial Ports -- 3.16 Direct Memory Access -- 3.17 Memory Considerations -- 3.17.1 Data Allocation -- 3.17.2 Data Alignment -- 3.17.3 Pragma Directives -- 3.17.4 Memory Models -- 3.18 Fixed- and Floating-Point Format
3.18.1 Data Types -- 3.18.2 Floating-Point Format -- 3.18.3 Division -- 3.19 Code Improvement -- 3.19.1 Intrinsics -- 3.19.2 Trip Directive for Loop Count -- 3.19.3 Cross-Paths -- 3.19.4 Software Pipelining -- 3.20 Constraints -- 3.20.1 Memory Constraints -- 3.20.2 Cross-Path Constraints -- 3.20.3 Load/Store Constraints -- 3.20.4 Pipelining Effects with More Than One EP within an FP -- 3.21 Programming Examples Using C, Assembly, and Linear Assembly -- 3.22 Assignments -- References -- 4 Finite Impulse Response Filters -- 4.1 Introduction to the z-Transform -- 4.1.1 Mapping from s-Plane to z-Plane -- 4.1.2 Difference Equations -- 4.2 Discrete Signals -- 4.3 FIR Filters -- 4.4 FIR Lattice Structure -- 4.5 FIR Implementation Using Fourier Series -- 4.6 Window Functions -- 4.6.1 Hamming Window -- 4.6.2 Hanning Window -- 4.6.3 Blackman Window -- 4.6.4 Kaiser Window -- 4.6.5 Computer-Aided Approximation -- 4.7 Programming Examples Using C and ASM Code -- 4.8 Assignments -- References -- 5 Infinite Impulse Response Filters -- 5.1 Introduction -- 5.2 IIR Filter Structures -- 5.2.1 Direct Form I Structure -- 5.2.2 Direct Form II Structure -- 5.2.3 Direct Form II Transpose -- 5.2.4 Cascade Structure -- 5.2.5 Parallel Form Structure -- 5.2.6 Lattice Structure -- 5.3 Bilinear Transformation -- 5.3.1 BLT Design Procedure -- 5.4 Programming Examples Using C and ASM Code -- 5.5 Assignments -- References -- 6 Fast Fourier Transform -- 6.1 Introduction -- 6.2 Development of the FFT Algorithm with Radix-2 -- 6.3 Decimation-in-Frequency FFT Algorithm with Radix-2 -- 6.4 Decimation-in-Time FFT Algorithm with Radix-2 -- 6.5 Bit Reversal for Unscrambling -- 6.6 Development of the FFT Algorithm with Radix-4 -- 6.7 Inverse Fast Fourier Transform -- 6.8 Programming Examples -- 6.8.1 Fast Convolution -- 6.9 Assignments -- References -- 7 Adaptive Filters -- 7.1 Introduction
7.2 Adaptive Structures -- 7.3 Adaptive Linear Combiner -- 7.4 Performance Function -- 7.5 Searching for the Minimum -- 7.6 Programming Examples for Noise Cancellation and System Identification -- References -- 8 Code Optimization -- 8.1 Introduction -- 8.2 Optimization Steps -- 8.2.1 Compiler Options -- 8.2.2 Intrinsic C Functions -- 8.3 Procedure for Code Optimization -- 8.4 Programming Examples Using Code Optimization Techniques -- 8.5 Software Pipelining for Code Optimization -- 8.5.1 Procedure for Hand-Coded Software Pipelining -- 8.5.2 Dependency Graph -- 8.5.3 Scheduling Table -- 8.6 Execution Cycles for Different Optimization Schemes -- References -- 9 DSP/BIOS and RTDX Using MATLAB, Visual C++, Visual Basic, and LabVIEW -- 9.1 Introduction to DSP/BIOS -- 9.2 RTDX Using MATLAB to Provide Interface Between PC and DSK -- 9.3 RTDX Using Visual C++ to Interface with DSK -- 9.4 RTDX Using Visual Basic to Provide Interface Between PC and DSK -- 9.5 RTDX Using LabVIEW to Provide Interface Between PC and DSK -- Acknowledgments -- References -- 10 DSP Applications and Student Projects -- 10.1 DTMF Detection Using Correlation, FFT, and Goertzel Algorithm -- 10.1.1 Using a Correlation Scheme and Onboard LEDs for Verifying Detection -- 10.1.2 Using RTDX with Visual C++ to Display Detected DTMF Signals on the PC -- 10.1.3 Using FFT and Onboard LEDs for Verifying Detection -- 10.1.4 Using Goertzel Algorithm -- 10.2 Beat Detection Using Onboard LEDs -- 10.3 FIR with RTDX Using Visual C++ for Transfer of Filter Coefficients -- 10.4 Radix-4 FFT with Frequency Domain Filtering -- 10.5 Radix-4 FFT with RTDX Using Visual C++ and MATLAB for Plotting -- 10.6 Spectrum Display Through EMIF Using a Bank of 32 LEDs -- 10.7 Spectrum Display Through EMIF Using LCDs -- 10.8 Time-Frequency Analysis of Signals with Spectrogram -- 10.8.1 Simulation Using MATLAB
10.8.2 Spectrogram with RTDX Using MATLAB -- 10.8.3 Spectrogram with RTDX Using Visual C++ -- 10.9 Audio Effects (Echo and Reverb, Harmonics, and Distortion) -- 10.10 Voice Detection and Reverse Playback -- 10.11 Phase Shift Keying-BPSK Encoding and Decoding with PLL -- 10.11.1 BPSK Single-Board Transmitter/Receiver Simulation -- 10.11.2 BPSK Transmitter/Voice Encoder with Real-Time Input -- 10.11.3 Phase-Locked Loop -- 10.11.4 BPSK Transmitter and Receiver with PLL -- 10.12 Binary Phase Shift Keying -- 10.13 Modulation Schemes-PAM and PSK -- 10.13.1 Pulse Amplitude Modulation -- 10.13.2 Phase-Shift Keying -- 10.14 Selectable IIR Filter and Scrambling Scheme Using Onboard Switches -- 10.15 Convolutional Encoding and Viterbi Decoding -- 10.16 Speech Synthesis Using Linear Prediction of Speech Signals -- 10.17 Automatic Speaker Recognition -- 10.18 µ-Law for Speech Companding -- 10.19 Voice Scrambler Using DMA and User Switches -- 10.20 SB-ADPCM Encoder/Decoder: Implementation of G.722 Audio Coding -- 10.21 Encryption Using the Data Encryption Standard Algorithm -- 10.22 Phase-Locked Loop -- 10.23 Miscellaneous Projects -- 10.23.1 Multirate Filter -- 10.23.2 Acoustic Direction Tracker -- 10.23.3 Neural Network for Signal Recognition -- 10.23.4 Adaptive Temporal Attenuator -- 10.23.5 FSK Modem -- 10.23.6 Image Processing -- 10.23.7 Filter Design and Implementation Using a Modified Prony's Method -- 10.23.8 PID Controller -- 10.23.9 Four-Channel Multiplexer for Fast Data Acquisition -- 10.23.10 Video Line Rate Analysis -- Acknowledgments -- References -- Appendix A TMS320C6x Instruction Set -- A.1 Instructions for Fixed- and Floating-Point Operations -- A.2 Instructions for Floating-Point Operations -- References -- Appendix B Registers for Circular Addressing and Interrupts -- Reference -- Appendix C Fixed-Point Considerations
C.1 Binary and Two's-Complement Representation -- C.2 Fractional Fixed-Point Representation -- C.3 Multiplication -- Reference -- Appendix D MATLAB Support Tools -- D.1 SPTool and FDATool for FIR Filter Design -- D.2 SPTool and FDATool for IIR Filter Design -- D.3 MATLAB for FIR Filter Design Using the Student Version -- D.4 MATLAB for IIR Filter Design Using the Student Version -- D.5 BLT Using MATLAB and Support Programs on CD -- D.6 FFT and IFFT -- References -- Appendix E Additional Support Tools -- E.1 Goldwave Shareware Utility as a Virtual Instrument -- E.2 Filter Design Using DigiFilter -- E.2.1 FIR Filter Design -- E.2.2 IIR Filter Design -- E.3 FIR Filter Design Using a Filter Development Package -- E.3.1 Kaiser Window -- E.3.2 Hamming Window -- E.4 Visual Application Builder and LabVIEW -- E.5 Alternative Input/Output -- References -- Appendix F Fast Hartley Transform -- References -- Appendix G Goertzel Algorithm -- G.1 Design Considerations -- References -- Appendix H TMS320C6416 DSK -- H.1 TMS320C64x Processor -- H.2 Programming Examples Using the C6416 DSK -- References -- Appendix I TMS320C6711 DSK -- Reference -- Index
RULPH CHASSAING, PhD, teaches Real-Time DSP at Worcester Polytechnic Institute (WPI). In addition to offering many DSP training workshops and seminars, he has authored four other books: DSP Applications Using C and the TMS320C6x DSK, Digital Signal Processing: Laboratory Experiments Using C and the TMS320C31 DSK, Digital Signal Processing with C and the TMS320C30, and Digital Signal Processing with the TMS320C25, all published by Wiley
Description based on publisher supplied metadata and other sources
Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2020. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries
Link Print version: Chassaing, Rulph Digital Signal Processing and Applications with the C6713 and C6416 DSK Hoboken : John Wiley & Sons, Incorporated,c2004 9780471690078
Subject Signal processing -- Digital techniques.;Texas Instruments TMS320 series microprocessors
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