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DS90UB953/954 System Design & Operation: Basic Design Rules

Understanding what hardware and software settings are important is critical to establishing a foundation for the 953/954 system. These settings can occur during or after power up and may need to be changed via software. As a result, these settings are routinely checked and verified before checking any of the other links in the system.

Specifically, this sections discusses: Diagnostics post power up, Mode and IDX Pins, Clocking Modes between the 953/954, Aliasing, I2C Pass Through, Port selection on 954, Analog Launch Pad (ALP), and Successful I2C Communication

DS90UB953/954 System Design & Operation: 953-954 Link Design

This section analyzes the link between the 953 and 954 and establishes how to identify the health and operation of the link. Since the link between the 953-954 is the most fundamental link used to communicate between devices, it is often checked first.

Specifically, this section discusses: Back Channel configuration, Built in Self Test (BIST), Adaptive Equalization (AEQ), and Channel Monitor Loop (CMLOUT)

DS90UB953/954 System Design & Operation: Sensor-953 Link Design

This is the Sensor and 953 Link Design section in DS90UB953/954 System Design & Operation video series. This video discusses how to use the sensor-953 link, as well as, the specific settings that are used with this link.

DS90UB953/954 System Design & Operation: 954-ISP/SoC Link Design

This section discusses what frame synchronization (FrameSync) is and how to configure in on the 953 and 954 and how CSI2 data is transferred across the link from the 954 to the ISP/SoC

Specifically, this section discusses: Frame Synchronization (FrameSync), Controlling 953 GPIOs locally and remotely via I2C, Unsynchronized and synchronized sensors, Internal and External Frame Sync, Port Forwarding, Accessing Indirect Registers, and Pattern Generation on 953 & 954

DS90UB953/954 System Design & Operation: Hardware Design

This section discusses how design a 953/954 using Power over Coax (PoC), and various hardware checks and concepts that need to be considered when analyzing a 953/954 system.

Specifically, this section discusses: Power Over Coax (PoC), AC Coupling Capacitors, PoC Inductors, Typical PoC Schematic, Critical Signal Routing, I2C Pullups, Loop Filter Capacitors on 953, Insertion Loss, Return Loss, and Time Domain Reflection (TDR) measurements.

Introduction to FPD-Link SerDes

These introduction videos describe the evolution of FPD-Link product families, and introduction to FPD-Link III SerDes for use in Infotainment and ADAS applications.

Diagnostic & Data Protection

This video series provides an overview of diagnostic capabilities of FPD-Link III and basic tips to simplify troubleshooting.

FPD-Link Parameters & Transmission Channel

This video series describes the key parameters used in the FPD-Link high-speed serial link consisting of the serializer, transmission medium and the de-serializer.

Power over Coax (PoC)

This video series describes the concept, design and evaluation of PoC (power over coax) commonly used in ADAS sub-systems.

Interfaces

This video series describes the interfaces to sensor or video IO's of a graphics processor.

Tools

This video series describe the supporting tools for evaluating FPD-Link SerDes.

Introduction to TDA2 Evaluation Module

This section introduces the evaluation module available from TI for Jacinto TDA2 SoC. The video series provide a quick overview of the TI EVM and its capabilities for ADAS solutions along with providing information on the setup and getting started with development

Introduction to TDA3 Evaluation Module

This section introduces the evaluation module available from TI for Jacinto TDA3 SoC. The video series provide a quick overview of the TI EVM and its capabilities for ADAS solutions along with providing information on the setup and getting started with development

Processor SDK Vision

TI provides key run-time software components and documentation to further ease development on TI's TDA SoC platforms for ADAS solutions. This section provides an introduction to the Processor SDK and how to use this software to start building applications on TI processors.

Processor SDK Radar

TI provides key run-time software components and documentation to further ease development of radar applications for automotive on TI's TDA SoC platforms. This section provides an introduction to the Processor SDK Radar and how to use this software to start building radar applications on TI processors.

Software Frameworks & Components

TI Processor SDK framework allows users to create different ADAS application data flows involving radar and video capture, radar processing, video pre-processing, video analytics algorithms & video display. The software offering is scalable and open across multiple device variants with in the TDA2 and TDA3 family of devices. This section provides introduction and overview videos for some specific software components that are packaged in the Processor SDK Vision and/or Processor SDK Radar

Automotive mid and long range radar using AWR1243 automotive radar sensor

Date:
May 12, 2017

Duration:
02:50
Watch this video to understand how TI's AWR1243 mmWave radar sensor enables high-performance mid and long-range applications.
Overview of Power Management Software for TI TDA ADAS SoCs

Introduction to ADAS Power Management Software

Date:
October 26, 2017

Duration:
34:21
This video provides an overview of various power management features of TI TDA ADAS SoCs and explains how to configure the SoC in software for managing power
Imaging radar demonstration using mmWave radar sensors

Imaging radar using multiple single-chip FMCW transceivers

Date:
December 19, 2017

Duration:
02:35
In this video we’ve cascaded four 77GHz AWR1243 mmWave radar FMCW transceivers to demonstrate how TI’s sensors can enable high-accuracy systems in dense scenes.
Driver vital sign detection demonstration using mmWave radar sensors

Driver vital sign detection demonstration using mmWave radar sensors

Date:
December 19, 2017

Duration:
00:47
This video demonstrates how developers can embed the single-chip 77GHz AWR1642 mmWave sensor into a driver seat and accurately detect driver vital signs.
102 Results
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