Experiment with Innovative Sensing Techniques Using DLP® Technology to Determine Material Properties
This DLP® training series provides an innovative applications introduction for spectroscopy. The series includes the following key content:
- Spectroscopy Agenda
- Introduction to DLP technology
- Overview of near-infrared (NIR) spectroscopy & DLP spectroscopy architecture
- Spectroscopy development tools using DLP technology
- Target application overview in spectroscopy
- Scanning process for DLP spectroscopy
- Developing your own spectrometer
- Additional DLP spectroscopy resources
This training series discusses the key requirements of local oscillator in microwave/RF and GHz clocks in radio applications. The topics covered establish the key relationships between the requirements of a signal source and their impact in a radio system. After this training, you will be armed with the ability to understand the system requirements of your customer and how they pertain to a signal source so you can engage with your customer in a very meaningful way.
Delta-sigma analog-to-digital converters (ADCs) are oversampling converters typically used in applications requiring higher resolution. However, ADCs do not work by themselves. In fact, they require several key components around them, including a front-end amplifier, a voltage reference, a clock source, power supplies, and a good layout. Many devices integrate these features together with the ADC to offer a complete system solution, which simplifies the design for customers and minimizes board space.
The JESD204B video blog series explores the basic concepts related to the JESD204B SerDes standard in relation to High Speed Data Converter products.
This series explores the new realm of RF sampling converters for use in high frequency, large bandwidth systems.
This series explores advanced topics related to the JESD204B SerDes standard associated with extending the link length and multi-device synchronization.
This series covers general updates on Texas Instruments' high-speed signal chain portfolio.
Before we dive into specific application-based examples of noise and EMI mitigation, let's start with the basics. What is noise? What is EMI? What is ripple? How are they measured? What are some common approaches to limiting their effects? This section discusses these topics with a more conceptual approach to serve as a primer for the rest of the series.
Now that we understand the sources of EMI and noise in switching regulators, and some of the common approaches to mitigating each, let's take a closer look at real-world examples of reducing their effects. In this section we will examine the impacts of various mitigation techniques to help you decide which approach makes the most sense in your design. Techniques covered in this discussion include external component placement, filter options and design, frequency manipulation via spread spectrum or dithering, snubbers, boot resistors, and more.
Noise and EMI can be detrimental to sensitive analog signal chain circuitry. For this reason, many engineers automatically default to linear regulators. But, in doing so, they are essentially trading one problem (noise) for another (heat dissipation). In this section we will discuss what types of signal chain loads can be driven directly by a switching regulator to get low noise and EMI without sacrificing efficiency. We will also discuss when a linear regulator is absolutely needed to reach levels of noise not possible with a switcher.
Because of the potential havoc that interference can wreak in radio and safety critical systems, automotive electronics are subject to the most stringent EMI standards- the most common being CISPR25 Class-5. The materials below provide a discussion around the sources of EMI in an automotive environment and a comprehensive blueprint to understanding how to minimize it's effects.
Mitigating switching regulator EMI and noise is seen by engineers as a black art. Mess with the feng shui of the PCB layout too much, and the system may not pass CISPR standards. Because of this, many power designers simply turn to linear regulators as a guaranteed way to avoid the headache of reducing emissions.
Learn how C2000 devices excel in sensing and DSP processing applications.
- In the first module, The architecture of a multi-channel data acquisition system and how a multiplexer can be used to facilitate the implementation. Possible causes of fault condition in a typical data acquisition system are discussed, and how the fault condition can severely impact the normal operation of the system is explained.
- In the second module, protection schemes that can be implemented to protect the system in fault condition using discrete components are discussed.
Applications Engineer Jason Tao discusses PFC basics, topology comparisons and design considerations to achieve a cost-optimized and efficient PFC design.