Based on cost-effective RGB LED driving solution

One of the fastest growing areas of LED applications is effect lighting, also known as architectural lighting. Effect lighting can use RGB LEDs, which use three chips, each responsible for generating a color of light (red, green, and blue). Another way to generate different colors of light is to use red, green, and blue single-color LEDs and then mix the light from these LEDs. Infineon offers LED drivers for low-power, high-efficiency, and high-power LEDs (Figure 1), as well as microcontrollers for controlling the color of LED modules.

Figure 1: Infineon Technologies offers LED drivers for low-power, high-efficiency, and high-power LEDs.

Figure caption:

LED drivers for general lighting and industrial applications: LED drivers for general lighting and industrial applications; Supply voltage: Supply voltage; Ext. transistor: External transistor; Ext. MOSFET: External MOSFET; LED drivers for low power LED: LED drivers for low power LED; LED drivers for high power LED: LED drivers for high power LED; LED drivers for 0.5W LED: LED drivers for 0.5W LED; Offline LED driving solutions: Offline LED driving solutions

For low-power RGB LEDs, the extremely low-cost BCR40x high-side linear LED drivers can be used. The color of the LED light can be controlled using a PWM signal generated by a microcontroller. For high-power (0.5W) RGB LEDs or single-color LEDs, the new low-side LED drivers BCR321U and BCR421U are ideal. The BCR321U can regulate currents up to 250mA. Both driver models have a direct logic level input that can be directly controlled by a microcontroller.

All BCR-type LED drivers have a negative thermal coefficient, which means that the current will drop at a rate of 0.2%/K when the temperature rises. LED drivers such as BCR321U, BCR421U and BCR40xU all use a very small SC-74 package (2.9x2.5x1.1mm) with a power consumption of 1W. The application circuit diagram is shown in Figure 2. LED driver BCR40xW uses an even smaller SOT343 package. Applications for BCR 320U/420U include: architectural LED lighting; advertising channel letters; decorative lighting LED strips; commercial lighting for refrigerators and freezers; emergency lighting (step lighting, exit lights, etc.); and interior lighting for ships, trains and airplanes.

Figure 2: Low-cost LED driver application circuit for high-efficiency LEDs.

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Low cost LED drivers for medium power LED: Low cost LED drivers for high power LEDs;

Application example: application example;

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For low-power LEDs (sometimes including high-efficiency LEDs), the bias resistor is still the most commonly used method. This method has major disadvantages, such as uneven light emission and shortened LED life. As an alternative, the switch-mode driver cannot meet the price requirements of 0.5W LED products, and the drive circuit is relatively complex.

The new BCR321 and BCR421 LED drivers are tailored to overcome the shortcomings of 0.5W LED applications. The proven BCR40x LED driver portfolio is ideal for 0.1W LED applications. All models of LED drivers offer extremely low cost, simplified solutions and small form factors.

For high-power LEDs, switch-mode drivers are the most commonly used LED drivers. Infineon Technologies introduces the new ILD4xxx step-down converters for driving high-power LEDs. The ILD4035 with a typical output current of 350mA is designed to drive 1W LEDs. For LEDs above 3W, Infineon introduces the ILD4120 and ILD4180 with output currents of 1200mA and 1800mA respectively.

In addition to high efficiency and overvoltage and overcurrent protection, all ILD models also feature thermal protection. When the junction temperature reaches 125°C, the output current is significantly reduced, ensuring a long LED life. The ILD4001 is an LED controller that can be used in conjunction with a high-current external MOSFET (700mA to several amps). Both the ILD4035 and ILD4001 are available in a small SC4 package.

Infineon Technologies has launched a microcontroller for lighting applications. In addition to controlling multi-channel LED lamps or modules, the microcontroller can also bring more value to the lighting system, such as dimming, lamp temperature control, and connection to the lighting network. Connection to the lighting network can ensure the realization of daylight adjustment, motion control switch, unified remote control, HMI interface, maintenance monitoring, lamp verification and other functions.

Infineon's XC800 microcontroller family includes a variety of products that can bring rich features to lighting systems (Figure 3). The main features of these lighting application products are: 48MHz capture compare unit (CCU6) generates 4 PWM control signals, and a direct hardware connection with a 10-bit analog-to-digital converter (up to 8 channels); serial communication I/F includes UART, SPI, I2C; power-down mode results in a typical power consumption of only 2μA; DALI slave protocol stack; long service life, and the product has been optimized for high temperature resistance.

Figure 3: Infineon’s XC800 microcontroller family includes a variety of products that bring rich features to lighting systems.

In addition to products for fast and precise control of multi-channel LEDs, Infineon also offers the XC82x and XC83x families, which feature suitable HMI interfaces such as inductive touch wheels by integrating capacitive touch controllers, such as the new XC822T.

In addition to microcontrollers, Infineon also provides a variety of development tools to accelerate hardware and software development, from USB entry-level tool kits that ensure rapid evaluation of key features such as ACD and CCU6 to simple kits that can configure microcontroller pins, all kits have a complete tool chain. With the new XC82x and XC83x series, Infineon will be able to launch a new free Eclipse-based tool chain DAVE Bench. Application kits for lighting solutions are currently being developed to showcase the entire solution, including microcontrollers, power semiconductors and software.