| Description |
1 online resource (361 p.) |
| Series |
New York Academy of Sciences Ser |
|
New York Academy of Sciences Ser
|
| Contents |
Digital Signal Processing and Applications with the OMAP-L138 eXperimenter -- Contents -- Preface -- List of Examples -- 1. OMAP-L138 Development System -- 1.1 Introduction -- 1.1.1 Digital Signal Processors -- 1.2 Hardware and Software Tools -- 1.2.1 Zoom OMAP-L138 eXperimenter Board -- 1.2.2 C6748 Processor -- 1.2.3 Code Composer Studio IDE -- 1.2.4 Installation of Code Composer Studio Software Version 4 and Support Files -- 1.3 Initial Test of the Experimenter Using a Program Supplied with this Book -- 1.4 Programming Examples to Test the Experimenter -- 1.5 Support Files |
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1.5.1 Initialization and Configuration File (L138_aic3106_init.c) -- 1.5.2 Header File (L138_aic3106_init.h) -- 1.5.3 Vector Files (vectors_intr.asm and vectors_poll.asm) -- 1.5.4 Linker Command File (linker_dsp.cmd) -- Exercises -- References -- 2. Analog Input and Output with the OMAP-L138 eXperimenter -- 2.1 Introduction -- 2.1.1 Sampling, Reconstruction, and Aliasing -- 2.2 TLV320AIC3106 (AIC3106) On-Board Stereo Codec for Analog Input and Output -- 2.3 Programming Examples Using C Code -- 2.3.1 Real-Time Input and Output Using Polling, Interrupts, and Direct Memory Access |
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2.3.2 Real-Time Sine Wave Generation -- References -- 3. Finite Impulse Response Filters -- 3.1 Introduction to Digital Filters -- 3.1.1 FIR Filter -- 3.1.2 Introduction to the z-Transform -- 3.1.3 Properties of the z-Transform -- 3.1.4 z-Transfer Functions -- 3.1.5 Mapping from the s-Plane to the z-Plane -- 3.1.6 Difference Equations -- 3.1.7 Frequency Response and the z-Transform -- 3.1.8 Ideal Filter Response Classifications: LP, HP, BP, and BS -- 3.1.9 Window Method of Filter Design -- 3.1.10 Window Functions -- 3.1.11 Design of Band-Pass and High-Pass Filters Using Frequency Shifting |
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3.2 Programming Examples Using C And ASM Code -- References -- 4. Infinite Impulse Response Filters -- 4.1 Introduction -- 4.2 IIR Filter Structures -- 4.2.1 Direct Form I Structure -- 4.2.2 Direct Form II Structure -- 4.2.3 Direct Form II Transpose -- 4.2.4 Cascade Structure -- 4.2.5 Parallel Form Structure -- 4.3 Impulse Invariance -- 4.4 Bilinear Transformation -- 4.4.1 Bilinear Transform Design Procedure -- 4.5 Programming Examples Using C and ASM Code -- 4.5.1 Design of a Simple IIR Low-Pass Filter -- Reference -- 5. Fast Fourier Transform -- 5.1 Introduction |
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5.2 Development of the FFT Algorithm with Radix-2 -- 5.3 Decimation-In-Frequency FFT Algorithm with Radix-2 -- 5.4 Decimation-In-Time FFT Algorithm with RADIX-2 -- 5.4.1 Reordered Sequences in the Radix-2 FFT and Bit-Reversed Addressing -- 5.5 Decimation-In-Frequency FFT Algorithm with Radix-4 -- 5.6 Inverse Fast Fourier Transform -- 5.7 Programming Examples Using C Code -- 5.7.1 Frame- or Block-Based Processing -- 5.7.2 Fast Convolution -- References -- 6. Adaptive Filters -- 6.1 Introduction -- 6.2 Adaptive Filter Configurations -- 6.2.1 Adaptive Prediction |
| Notes |
Description based upon print version of record |
|
6.2.2 System Identification or Direct Modeling |
| Genre/Form |
Electronic books
|
| Form |
Electronic book
|
| ISBN |
9781118229125 |
|
1118229126 |
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