5.4.15 HSI Header Utility
5.4.16 Secondary Bootloader
5.4.17 mmWave SDK - System Initialization
5.4.17.1 ESM
5.4.17.2 SOC
5.4.17.3 Pinmux
5.4.18 Usecases
5.4.18.1 Data Path tests using Test vector method
5.4.18.2 CSI-2 based streaming of ADC data
5.4.18.3 Basic configuration of Front end and capturing ADC data in L3 memory
6 Appendix
6.1 Memory usage
6.2 Register layout
6.3 Enable DebugP logs
6.4 Shared memory usage by SDK demos
6.5 mmWave Device Image Creator
6.6 mmw Demo: cryptic message seen on DebugP_assert
6.7 How to execute Idle instruction in idle task when using SYSBIOS
6.8 Range Bias and Rx Channel Gain/Offset Measurement and Compensation
6.9 Guidelines on optimizing memory usage
6.10 How to add a .const (table) beyond L3 heap in mmWave application where overlay is enabled
6.11 Enabling L3 cache for DSP/C674x on mmWave devices
6.12 DSPlib integration in mmWave C674x based application (Using 2 libraries simultaneously)
6.12.1 Integrating individual functions from each library
6.12.2 Patching the installation
6.13 SDK Demos: miscellaneous information
6.14 Data size restriction for a given session when sending data over LVDS
6.15 CCS Debugging of real time application
6.15.1 Inter-chirp debugging
6.15.2 Inter-frame debugging
6.15.3 Using non-real time chain test code
6.15.4 Using printfs in real time
6.15.5 Viewing hardware registers
6.15.6 Viewing expressions/memory in real time
6.16 Size of Enum
LIST OF FIGURES
Figure 1: mmWave Demo Visualizer- mmWave Device Connectivity
Figure 2: Chirp Diagram
Figure 3: mmWave EVM PC Connectivity - Device Manager - COM Ports
Figure 4: Creating a mmWave device CCXML in CCS
Figure 5: Connecting to mmWave Device in CCS
Figure 6: Autonomous mmWave sensor (Standalone mode)
Figure 7: SDK Layered block diagram
Figure 8: Typical mmWave radar processing chain
Figure 9: Typical mmWave radar processing chain using mmWave SDK components
Figure 10: Scalable data processing chain using mmWave SDK
Figure 11: Typical mmWave radar control flow
Figure 12: mmWave Isolation mode: Detailed Control Flow (Init sequence)
Figure 13: mmWave Isolation mode: Detailed Control Flow (Config sequence)
Figure 14: mmWave Isolation mode: Detailed Control Flow (start sequence)
Figure 15: mmWave Co-operative Mode: Detailed Control Flow (Init sequence)
Figure 16: mmWave Co-operative Mode: Detailed Control Flow (Config sequence)
Figure 17: mmWave Co-operative Mode: Detailed Control Flow (Start sequence)
Figure 18: Typical mmWave Detection Processing Layers
Figure 19: Data processing flow with local domain control (init/config)
Figure 20: Data processing flow with local domain control (start/chirp/frame/stop)
Figure 21: Data processing flow with remote domain control (init/config)
Figure 22: Data processing flow with remote domain control (start/chirp/frame/stop)
Figure 23: Distributed Data processing flow and control (init/config)
Figure 24: Distributed Data processing flow and control (start/chirp/frame/stop)
Figure 25: mmWave SDK Drivers - Internal software design
Figure 26: mmWaveLink - Internal software design
Figure 27: mmWave API - Internal software design
Figure 28: mmWave API - 'Minimal' Config - Sample flow (mmWave devices with MSS and DSS cores and module in co-operative mode)
Figure 29: mmWave API - 'Minimal' Config - Sample flow (mmWave devices with single core or when module is used in isolation mode)
Figure 30: DPU - Internal software design
Figure 31: DPU - typical call flow
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