注意:各項之間請以逗號分隔

例如 , 12/13/2019

例如 , 12/13/2019

注意:各項之間請以逗號分隔

例如 , 12/13/2019

例如 , 12/13/2019

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128 結果

The future of shopping

日期:
2019年 11月 19日

時間長度:
00:13
No more long checkout lines, out-of-stock items or frustrating searches. Sensor-rich stores will make shopping a breeze.
RSLK

Connect: Build a robot in under 15 minutes!

日期:
2019年 10月 9日

時間長度:
06:18
Join Adrian and Mark to learn how to build a robot in under 15 minutes with the TI Robotic Systems Learning Kit (TI-RSLK).

TI intern design competition

日期:
2019年 10月 4日

時間長度:
01:45
Texas Instruments college interns enjoy developing robotic solutions using the TI-RSLK MAX
Troubleshooting general board clean amplifier FPD Link integrated circuit PCB printed circuit board application linear ADC converter sensor datasheet verification failure analysis debugging debug submission FA customer return DAC audio ABA WCSP

Troubleshooting Tips: Board Level

This video section gives recommendations and best practices for application debugging techniques at the printed circuit board level.
Troubleshooting general board clean amplifier FPD Link integrated circuit PCB printed circuit board application linear ADC converter sensor datasheet verification failure analysis debugging debug submission FA customer return DAC audio ABA WCSP

Troubleshooting Tips: FA Submissions

This video section gives recommendations and best practices for application debugging techniques to assist during the FA submission process. 

TI-RSLK MAX Module - 1 Running code on the LaunchPad using CCS

The purpose of this module is to learn software development methodology and understand how to set up an Integrated Development Environment (IDE), to then import and export Code Composer Studio (CCS) projects, as well as critical debugging information to understand the memory usage and performance of the software on the processor.

TI-RSLK MAX Module 2 – Voltage, current, and power

The purpose of this course is to review basic electronic components and the electrical properties needed to interface sensors and actuators to a microcontroller. You will learn how to measure reactance of a capacitor and use your project to measure current and voltage. The electrical properties of the capacitor will help you design circuits that “filter” or remove noise from your robot.

TI-RSLK MAX Module 3 – ARM Cortex M

This module serves as a brief introduction to the ARM Cortex-M microcontroller, assembly programming language and some debugging techniques. Understanding how the processor works is essential for the design of embedded systems, such as the one used in your robot.  

TI-RSLK MAX Module 4 – Software design using MSP432

This module is an introduction to C, a general-purpose programming language, in addition to the concepts of compiling and debugging using the MSP432 and TI Code Composer Studio™.  Debugging skills are a valuable tool when developing complex systems involved with robotics.

TI-RSLK MAX Module 5 – Building the robot

In this module, you will create the robot. You will then be able to measure the voltage, current and energy for a battery while managing voltage regulation. This will allow you to build the circuits needed to power the robot.

TI-RSLK MAX Module 6 – GPIO

In this module, you will interface a line sensor (infra-red sensor) to the microcontroller and learn how to write software to initialize GPIO pins.  The line sensor is a simple and accurate sensor for solving robotic challenges.

TI-RSLK MAX Module 8 – Interfacing input and output

The purpose of this module is to develop interface switches and an LED so the robot can effectively detect wall collisions. Many sensors and actuators deploy LEDs, so understanding how they operate will be important to building your robot.

TI-RSLK MAX Module 10 – Debugging real-time systems-interrupts

This module provides an intro to how flash memory operates, including debugging techniques for real-time systems and how to generate periodic interrupts using SysTick. Minimally intrusive debugging is essential for real-time systems to evaluate performance while the system runs in real-life situations.

TI-RSLK MAX Module 11 – Liquid Crystal Display (LCD)

This module will show you how to display characters and provide real-time debugging on a display screen. An LCD or OLED on your robot provides a convenient way to observe what it is thinking.

TI-RSLK MAX Module 12 – DC motors

The purpose of this lab is to interface the motors to the TI LaunchPad to make the robot move. Understanding how duty cycle, voltage and current combine to affect speed is required when building your robot.

TI-RSLK MAX Module 14 – Real-time systems

This module demonstrates how to use priority interrupts for creating real-time systems.  As your robot system becomes more complex, period interrupts are one way to combine multiple threads onto one microcontroller.

TI-RSLK MAX Module 15 – Data acquisition systems

This module will teach you how to interface the infrared distance sensors using the analog-to-digital converter. IR distance sensors are an essential component for solving robot challenges where avoiding walls is necessary to achieve the goal.

TI-RSLK MAX Module 16 – Tachometer

In this module, you will learn how to interface the tachometers that enable the robot to measure motor rotational speed. Tachometer data allows your software to drive straight, drive for a prescribed amount of distance or turn at a prescribed angle.

TI-RSLK MAX Module 17 – Control systems

The purpose of this module is to create a control system by combining the sensors with the actuators. Incremental and integral control are simple algorithms for controlling motor speed.

TI-RSLK MAX Module 18 – Serial communication

The purpose of this module is to understand the operation and use of first in first out (FIFO) queue to interface the robot to the PC using a serial channel. You will create two FIFO queues and design a command interpreter to assist in the robot challenge. You will develop an interrupting device driver using the universal asynchronous receiver/transmitter (UART). This serial port allows the microcontroller to communicate with devices such as other computers, input sensors, and output displays.

128 結果
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