Boost converters, also known as step-up converters, are DC/DC power converters with an output voltage greater than its input voltage. The device boosts the voltage of the power source that is less than the VOUT.
|PDF 434 KB||White Paper|
Example of Driving an MCU from a Low-Voltage Power Supply by Using a Step-Up DC/DC Converter and Start-Up ICPDF 91 KB
|PDF 59 KB||Application Note|
Intersil introduces ISL78227 and ISL78229 automotive-grade, 55V, 2-phase, synchronous boost controllers. The ISL78229 offers a PMBus interface for advanced control, telemetry and diagnostics. Intersil also demonstrates how these devices can offer solutions to common challenges in automotive power design.
Hi, I'm Steve Schulte, Application Engineering Manager for automotive power management products at Intersil. Today I'd like to introduce Intersil's new automotive grade boost controllers, ISL78227 and ISL78229. The ISL78229 offers a PMBus interface for advanced control, telemetry and diagnostics.
I'm going to demonstrate how these devices provide several means to solve a common challenge in automotive power supply design. Often a system needs to dynamically adjust, scale, or modulate the power supply voltage based on load demands or system needs. For example, whenever the battery supply is low, power consumption of various components, such as audio amplifiers, must be limited, especially when the engine is restarted in start/stop operation.
The ISL78227 and ISL78229 offer a unique envelope tracking feature that dynamically adjusts or scales the output voltage on the fly to meet all system load demands.
Let me show you how this works on this ISL78229 evaluation board. Here I've set up the ISL78229, with an input supply of 12V and configured the output voltage to 36V. In this configuration it is set up to deliver a 3A current to the load. In addition, I have provided an analog envelope signal to the track pin via a function generator. The tracking bandwidth of the track pin is approximately 400Hz. Here I am providing a sinusoidal envelope at 200Hz. On the oscilloscope you can see the track signal on channel 1 in yellow and the corresponding output voltage on channel 4 in green. As you can see, the output voltage is proportional to the track input and is varying between 16V and 36V.
For systems that find it more convenient to create a digital PWM signal, such as a DSP or microcontroller based system, the track pin can also follow such a signal. Here I have provided a PWM signal, whose duty cycle varies in a triangular pattern. Now I'm going to switch to the output, which is varying between 16V and 36V, in the shape defined by the duty cycle of the PWM input.
In summary, the ISL78227 and ISL78229 are easy to use and also the industry's most robust and highly integrated boost controllers. Some of the key features include: two layers of overcurrent protection prevent runaway system damage, negative current protection prevents large currents that can damage the high-side FET, average current limiting allows high current for brief heavy load periods and prevents long durations that can cause overheating, diagnostic features to aid in ASIL compliance.
We have a complete set of support tools, such as evaluation boards, user guides and a white paper.