A new LED controller expedites the next level of smart lighting

The new XDPL8221, a digital LED-driver IC from Infineon, provides an alternative way to implement smart lighting systems.

Many lighting installations are conceived to make the use of artificial lighting more comfortable and energy efficient. Usually, we refer to such features with the term “smart lighting”. This immediately raises the question: what smart lighting actually is? Still, no common definition is available. This buzzword is overused to promote a variety of features: starting from simply connected luminaires – potentially with smartphone control – up to a fully connected lighting installation with sensors and devices controlled through a cloud application. In other words, the Infineon definition of the term “smart lighting” describes the capability of the lighting system to adapt automatically to the needs of the users and the room. A common denominator of all definitions is the demand for communication and information.

Addressing smart lighting features and customer requirements can add significant cost to lighting installations. Extra costs are caused by additional sensor components and the need for microcontrollers with numerous ADC channels. A microcontroller may also be required to control multiple operating parameters, including controlling LED-array brightness and dimming level. Sometimes the microcontroller’s influence on the system/driver control may cause unwanted instabilities within the system. This is seen as variation of brightness, usually called flicker, and non-linearity of the brightness control, and luminaires that turn dark due to software bugs.

The new XDPL8221, a digital LED-driver IC from Infineon, provides an alternative way to implement smart lighting systems.

The distinctive ‘universal asynchronous receiver transmitter’ (UART) serial communication interface offers a new measure for control and analysis. The UART communication can control the power conversion in an AC/DC converter as a typical mixed-signal controller, with the added benefits of updates, communication, and storing the data of the converter’s health and operating conditions. System issues and failures like output over- or undervoltage can be instantly tracked through the UART monitoring functions. It permits to keep an eye on the device functioning or activated protections, bringing the considerable benefit of accurately determining the nature and location of any deficiency. This eases then the issue analysis process and permits to save costs and time by supporting a technician to identify the failing device, fix it instantly and efficiently thanks to the information read through the UART interface. In short, maintenance personnel can be purposefully sent to the right place with the needed replacement parts to fix the failing device. This saves significant cost as the maintenance personnel does not need to browse through the buildings to find failed devices and fetch the spare part from stock until repair can start.

Additionally, real-time measurement data are available via the UART. Operating data, like output voltage and output current, can be read at any moment. The constant availability of these values permits, for example, to determine the actual output power, and therefore gives insight into detailed information about the device’s power consumption, and manage it. Moreover, regular monitoring of LED current/voltage provides insight into the device aging. This allows the user to analyse the healthiness of the device and therefore permits the planning of maintenance. With this predictive maintenance, only necessary activities produce cost and downtimes are minimised. Considering a large building equipped with LED luminaries, the existence of a UART in each of these luminaries makes it possible to access the real-time data in every LED array. Any device showing deviations from ‘normal’ could be precisely detected, and therefore easily replaced before final failure.

The UART’s SET commands can influence many operating modes. For instance, the SET command configures the behaviour of power conversion in multiple ways, i.e., determining the value for the maximum output defines the maximum brightness of the LED. Additionally, the SET command, which sets the dimming level, determines the final brightness. The numeric values of the parameters in the SET command eliminate uncertainty in recognition of an analog or PWM input signal. In PWM, for example, imprecise data results from the sampling of the input signal for measurement. During the input sampling and quantization, for the high and low times, the precision of the calculated duty cycle depends on the sampling frequency, the threshold for the input stage, or the slope of the input signal. Inaccuracies of both high- and low-time measurements add up to the uncertainties of the duty-cycle value. Higher sampling frequency would reduce the error at the price of higher energy consumption and additional noise. Whereas the UART provides exact numerical values without any inaccuracies.

Another highlight is the multi-control operation, with the automatic selection of constant current (CC), constant voltage (CV), and limited power (LP). This facilitates its use for a wide variety of LED-driver products, based on the same hardware design. The mode is selected in accordance with the operating situations such as load and configuration. The LP mode is a special feature and allows utilising the limits of the hardware to the full extent without jeopardizing safe operation. During LP mode, the device controls current and voltage in a way that the output power never exceeds the defined value. An additional advantage of this mode is the safe operation of cold LEDs, for example, in outdoor luminaires. In fact, the LED forward voltage and temperature are inversely proportional. This constitutes a problem in conventional constant current controls, which might run into overvoltage protection before any current flows through the LEDs. The result of this behaviour might be that illumination will not start up from low temperatures. The XDPL8221, on the contrary, will at least drive current until the maximum output voltage is reached, which can be much higher than usual as the maximum power is also taken into account if some current reduction is doubted.

The market demand for ever-expanding LED-driver lifetime requires thorough design, testing including ´highly accelerated lifetime testing´ (HALT) and ´highly accelerated stress testing´ (HAST), and that the controller recognises potentially dangerous situations and reacts appropriately.

The comprehensive set of protection features of the XDPL8221 makes the driver robust against failures and unsafe conditions. Two of the protections are output under- and overvoltage protections that commonly occur when the output is shorted or disconnected from the LED array.

The XDPL8221 offers multiple parameters to configure the reaction; this includes the override of the default reaction, such as auto-restart or latch mode. Furthermore, an adjustable blanking time permits monitored signal perturbations due to the possibility of masking the switching noise and disallowing false triggering of the protection schemes.

Similarly, the input over- and under-voltage protection allows for a flexible system while maintaining stability from adverse events on the AC line. This allows, for example, the adaptation of the LED driver behaviour to a weak power grid. In fact, frequent voltage fluctuation in these grids usually triggers the under-voltage protection for classic devices. The XDPL8821 offers, in contrast, a more significant margin by configuring the threshold values and prevents most light-off situations due to grid fluctuations.

Another important feature is over-temperature protection as the long-term reliability of the LED array and the LED driver is often dependent on their operating temperature and exposure to over-temperature events. An internal or external temperature sensor can be employed to sense, and trigger this protection function. The XDPL8221’s internal sensor protects the IC and any external components that have sufficient thermal couplings with the device. The external sensor can be placed strategically to protect external components such as transformer, MOSFETs or the LED array.

The internal temperature protection initiates a shutdown in case the temperature exceeds a critical level. The external temperature protection reacts if a critical ‘negative temperature coefficient’ (NTC) resistance passes a threshold. This feature provides additional functionality like adaptive temperature protection. It reduces the output current until the temperature is below the respective threshold to protect the load or the driver against over-temperature. Its functioning principle is quite simple: as long as the resistance of the NTC is below its temperature threshold, the XDPL8221 reduces the current by a programmable step size. Once the resistance of the NTC is higher than the temperature threshold, the device increases the output current stepwise again. In short, the controller ensures operation below a critical temperature extending the operating life of the driver. If a reduction down to a minimum current level does not stop the over temperature situation, the XDPL8221 will then trigger over-temperature protection and shuts the LED current off. For all over-temperature protection cases, the controller will only restart after the temperature drops below a configurable threshold. Over temperature-protections are essential to ensure the safety of users by preventing severe accidents and by saving components from failures. In fact, high temperatures are generally associated with faster device aging and deteriorating performance. Additionally, the GET command of the UART, temperatures can be read out. This enables the user to implement regular monitoring of the driver temperature. Some ways of using these data are the recording of temperatures, forecasting the lifetime of the driver, and supporting predictive maintenance.

The extensive set of configurable protection mechanisms ensures safe, reliable, and robust LED drivers for a wide set of use cases.

Unique features like the UART interface, multi-control-operation mode, or the incorporation of robust and comprehensive protections make the XDPL8221 an excellent LED-driver IC and a perfect match for sophisticated applications. It is also worth mentioning that the XDPL8221 was designed for primary side regulation (PSR). PSR permits to save external components and reduce noise. Programmable parameters similar to multimode operation enable using the same hardware for several applications thanks to a simple software configuration and then saves many different variants, making it possible to save costs thanks to a smaller bill of materials (BoM).


For more information, visit www.infineon.com/xdpl8221
Author
Kurt Marquardt
Senior Director – LED Lighting Systems and Product Marketing,
Infineon Technologies

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