![]() From the light-output perspective, the brightness depends on the duty cycle of the switch off-time. By using shunt-FET dimming with these type of drivers, current is continually flowing and regulated accordingly, regardless of whether the dimming switch is on or off. With the nature of hysteretic converters or constant on-time converters that don’t form feedback loops, the response on the variation of output voltage is fast and the load change is instant. You will need a fast-responding LED driver that enables abrupt changes in load, yet maintains good current regulation and prevents current overshoot from destroying the LEDs. How about connecting a switch parallel to the LEDs? When the switch is off, current flows through the LEDs and shines light when the switch is on, current flows through the switch and there is no light. To achieve a better contrast ratio, you must either use a lower PWM dimming frequency or try to further increase the loop bandwidth. That imposes a limit on the contrast ratio to about 25-to-1 with a 2kHz PWM dimming frequency. For a fixed-frequency switched-mode power supply-type LED driver using a DC-to-DC conversion architecture, the loop bandwidth is typically designed at or below 50kHz. However, the bandwidth of the LED driver limits the dimming frequency and contrast ratio. To achieve high-frequency dimming, most LED drivers have a PWM dimming input. In short, to use PWM dimming and avoid its drawbacks, you should set the PWM dimming frequency higher than 2kHz. PWM dimming can also create the stroboscopic effect, which is when moving/rotational objects look stationary. A banding effect might occur when taking photos or recording videos if the dimming frequency is in such a range. Low-frequency dimming is in the 100Hz to 2kH range, making it perceptible by humans (subtly) and inducing eye strain or fatigue. While PWM dimming provides advantages in LED brightness control, are there any drawbacks? Yes: it comes down to the quality of light with PWM dimming and its effect on different objects. Since human eyes are not responsive to any frequency above 30 Hz, brightness seems linearly changing according to the duty cycle of the PWM signal as seen by human eyes. ![]() The concept of PWM dimming is to leverage the slow response of human eyes by quickly turning the LED on and off (at a frequency above 100Hz) without changing the LED current flowing through during turn-on time. This is not desirable in rear lamp that requires precise color control per governmental regulations. Some older red LEDs might even change from red to orange because of flowing current-level changes. ![]() Once the current changes, the brightness and color change accordingly. The brightness and color of an LED depends on the current flowing through. Let’s review why PWM dimming is preferable to analog dimming in some applications, such as rear lamp. In this post, I will elaborate more on PWM dimming and how to get its frequency fast enough in order to reduce its effect on humans or other living creatures. In one of my previous blog posts, I introduced different dimming methods for light-emitting diode (LED) drivers: analog and pulse-width modulation (PWM) dimming.
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