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LED Backlight Flicker in LCD Displays

What Causes Flicker in LCD Monitors?

Computer monitors have come a long way from the bulky, heavy CRTs to the sleek, modern LCDs of today. One of the most significants improvements in display technology as of late is the LED backlight, which results in a brighter, sharper picture while reducing the power consumption. Manufacturers tout the benefits of LEDs over the older CCFL (fluorescent) backlights. However, some people experience issues like unusual eye strain, pain, or headaches which seem to be caused by their new monitor. And the most likely culprit is the LED backlight flicker.

"But wait," you might say, "I thought LCD displays were supposed to be flicker-free!". Indeed, while CRT monitors redraw the whole screen many times a second (determined by their refresh rate), LCD monitors provide a constant image, simply changing the pixel colors from one to another. The speed of this process depends on the monitor's response time, which is different from refresh rate. So, the source of flicker in modern liquid crystal displays isn't the LCD matrix itself, but rather the backlight.

In LED monitors, this flickering occurs when the brightness is reduced from 100% due to a backlight dimming method called PWM (Pulse-Width Modulation). In many cases, when a laptop is running on battery power, PWM will kick in even at maximum brightness to save energy. CCFL monitors also use PWM, but the resulting flicker might actually be less noticeable than with LEDs - more about that below.

An example of PWM dimming in LCD monitors.

An example of PWM dimming in LCD monitors.

How Does PWM Work In LED LCDs?

More information on pulse-width modulation dimming in LCD screens

Pulse-width modulation, or PWM, is a technique that is used for dimming LCD backlights, among other things. It involves cycling the backlight on and off faster than the human eye can see. PWM dimming kicks in as soon as you reduce the brightness setting on your monitor from its maximum value. It has many advantages over analog dimming, which provides continuous lighting: PWM is cheaper to implement, offers a wider range of adjustment, and prevents color shifting at lower brightness settings.

So if PWM-dimmed LEDs are so great, can they really cause problems like extra eye strain or headaches? Humans cannot see the LCD backlight flicker with a naked eye, after all. Certainly, provided a sufficiently high PWM switching frequency is used - such as 500 Hz - even the most sensitive people shouldn't be affected. However, it seems that many LCD monitors currently on the market use backlight frequencies between 100 Hz and 200 Hz. Humans still can't perceive the backlight cycling on and off at that frequency, but it doesn't mean that this LED PWM flicker won't hurt their eyes or affect their nervous system. Consider the following information:

  • According to studies about 1 in 4,000 people are highly susceptible to flashing lights cycling in the 3 to 70 Hz range [...] Less well known is the fact that long-term exposure to higher frequency flickering (in the 70 to 160 Hz range) can also cause malaise, headaches, and visual impairment.

  • There is good evidence that fluctuations in the light signal are detected by the nervous system up to perhaps 200 Hz.

  • Physiological evidence in humans and monkeys shows that flicker rates above the perceptual critical flicker frequency threshold can nevertheless generate cortical and subcortical visual responses.

    Martinez-Conde, S., Macknik, S.L., and Hubel, D.H. (2002). Proc Natl Acad Sci, USA 99, 13920-13925.

  • Different points in the visual system have very different critical flicker fusion rate (CFF) sensitivities. Each cell type integrates signals differently. [...] some retinal ganglion cells can maintain firing rates up to 250 Hz.

More links on the subject can be found further down the page.

LCD LED Flicker Video

See what LED PWM flickering actually looks like

This video shows the the LED backlight of a MacBook Pro flickering 40 times slower, so you can actually see what's happening when you dim the brightness on your LCD screen. This video was taken with high speed camera by crew.

CCFL vs LED Backlights in LCD Screens

Why PWM on CCFL backlights might be easier on the eyes

You might wonder why people who never had a problem with CCFL-backlit screens are now complaining about their new LED monitors or TVs hurting their eyes. CCFLs in LCD panels also use PWM dimming, so why don't they cause the same issues? There are two main reasons for this. First of all, a LED can be turned on and off almost instantly, but a fluorescent lamp will glow briefly even after the power is cut, providing a smoother transition between "on" and "off" states. The second reason is that WLED backlights tend to be quite a lot brighter than their CCFL counterparts. This means not only that more people will use lower brightness settings (thus increasing the flicker), but also that the difference between "on" and "off" states is more pronounced. After all, your backlight is blasting full brightness pulses between brief periods of darkness.

"Strobe Effect" Due to Low Backlight Frequency

You can check a monitor for backlight flicker yourself

There is a way to see the effects of low frequency PWM in LED backlights with a naked eye. Simply set your monitor to the lowest brightness possible and wave your hand, finger, or a pencil in front of a white background. If the object has sharply-defined edges, the backlight is operating at a fairly low frequency. If the edges are blurry, then either your monitor uses constant current dimming, or high frequency PWM undetectable by the human eye. This is demonstrated in the video below, which also compares CCFL and LED backlights:

LED Backlight LCD Discussion

Share your experience with LED backlights in modern monitors and TVs. Do you experience any extra eye strain when using LED-backlit LCDs?

Flicker-Free, No-PWM LED LCD Monitor

If PWM-controlled LEDs hurt your eyes, consider this monitor

Dell UltraSharp U2414H is one of the new LED-backlit displays which do not use PWM dimming, as tested by TFTCentral using an oscilloscope. In other words, it uses a constant control backlight and deserves the title of a truly "flicker-free" LCD monitor. Other advantages include IPS matrix for great image quality, fast response time and low input lag, as well as a thin bezel. The minimum brightness was measured to be just over 32 cd/m2, which means you can dim this monitor to almost nothing, and use it in a dark room comfortably.

Interesting articles for further reading

  • is probably the first website on the net to bring up the topic of PWM switching in liquid crystal displays, and the potential issues associated with this method. Their recommendation to manufacturers is increasing the PWM frequency to at least 250 Hz, or using other methods of dimming which do not produce any flicker at all.
  • has a detailed article on pulse-width modulation in LCD monitors. They offer a lot of excellent illustrations, and include instructions on measuring the PWM frequency of a display backlight using a digital camera, something you can do yourself without any complex equipment.
  • Vasya from Ukraine is a computer enthusiast who modded his LCD monitor to use a regular incandescent light bulb as a backlight. His page has a lot of information on the topic of screen flicker, and also many testimonials from other people who experience eye strain, pain, stress, migraine, and other issues when using digital screens. He also talks about the potential issues with fluorescent lighting in general. (Note: the webpage is no longer available, so the link leads to a copy on

If you know of any other interesting and useful articles on the topic, please mention them in the comments below.


anonymous on May 09, 2013:

Prad discovered another monitor that is 100% flicker-free by having an always-on backlight: BenQ BL2411PT

Scroll to Continue

Also, have a look at Asus PB248Q. Prad tested it to be flickering, but with the very high rate of 9400 Hz!

anonymous on March 23, 2013:

@anonymous: If you read the article you would understand that ccfl never entirely turns off during the off part of the cycle because of the fluorescent glow from the phosphorus in the ccfl even when it's in the off phase, so the flicker is not coticed by the brain. I can used ccfl fine, but not led.

anonymous on February 28, 2013:

Funny those claiming the flicker on LEDs give you headaches yet ccfl doesn't. You can't have it both ways. Flicker is flicker.

anonymous on January 15, 2013:

Took me the better part of five years to figure out what my 'flicker' problem was. I spent a small fortune on replacement hardware thinking the problem lay either with my graphics card, cables, EMI, RFI, peripherals, manufacturers etc, the list was endless. It's a very difficult problem to resolve if, like me, you have limited technical knowledge about such things: the flicker effect (i.e with the monitor backlight) lies hidden behind the image. horrid.

I'm very glad to see these articles appearing on the net. More of us need to respond, especially gamers, who are a significant demographic of the flat-screen market.

I would not wish the frustration I went through on anyone...

anonymous on November 30, 2012:

I too faced same issue with LED-LCD. So, I switched backed to CCFL-LCD.

anonymous on November 05, 2012:

Great post, glad I found it.... explains the issues i have with the newer laptops out. If it aint broke don't fix it is my theory. CCFL displays were just fine, CRT monitors didn't even bother me that much, but LED gloss screens..... the worst!

anonymous on October 02, 2012:

Great Post! I wonder if this is the cause with the screen in the ipad. I get eye strain and headaches after 15 mins of use.

TopFiveBestDeals on July 06, 2012:

cool lens!

Matt_Lowe on July 01, 2012:

Very informative. Now I know why I've been experiencing such horrible eye strain lately.


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