TV Diffraction

When taking a picture of my new 55″ TV (humblebrag) I noticed a diffraction pattern of the reflection of the camera flash. Fortuitously, I had also recently bought a slightly too-powerful laser pointer from China which is the perfect tool to investigate such problems. Here’s a little write-up of my DIY measurements.

The picture in question was this:

Reflection of a camera flash from my new TV. Did I mention it’s curved? Yeah it’s totally curved.

Most of the light from the flash is reflected straight back, causing the white region in the centre of the image. However some light is reflected back at an angle, causing it to appear displaced from the centre of the image. Furthermore, red wavelengths are deflected outwards to greater angles, causing the light to be spectrally dispersed in the reflection.

This kind of device is known as a diffraction grating, used extensively in experiments to split a light source up into different frequency components. In this case fine structures in the TV screen are causing the reflected flash light to diffract. The camera lens then maps diffraction angles to positions on the camera CCD.

Geometry for the diffraction effects observed in the photo above.

I wanted to measure this more precisely, without relying on knowing any details of the lens and CCD in my phone camera. Luckily for me, I’d recently acquired this beastie:

Premium Shenzhen-grade probably-legal laser pointer. I’m shining it at a black diffuse reflector (neck pillow) so that the spot doesn’t completely blind the camera.

A high power laser pointer! As someone who works with properly high power lasers on a frequent basis, I knew that it wasn’t safe to be playing with a CW (constant-wave) laser of this power, especially when there are specular reflections from smooth surfaces involved.

When we need to attenuate a laser in the lab, one method is to use a set of polarisers. If the polarisers are rotated relative to one another the total fraction of light transmitted through them can be substantially reduced. I don’t keep that many polarisers around in my flat, until I remembered I had 3D glasses by the dozen.

Thanks Cineworld!

Now I’m not exactly sure which polarisers are in 3D glasses you get from the cinema (hello future blog post), but I do know that if you turn a second pair backwards and rotate them it’s possible to drastically cut light transmission. Two small pieces cut from each lens, arranged appropriately, and I had a homemade variable attenuator for my laser pen.

To get a more accurate measurement of the diffraction angles, I needed to know the displacement of the reflected light relative to the incoming light. The configuration I imagined was something like this:

Sadly this diagram is superior to many setup drawings in scientific papers.

I cobbled together, after finding some card, sellotape and blu-tack, the following:

One polariser is missing, and the marks correspond to centimetre offsets.

After shining my contraption on the TV, I snapped several images like this:

For an experimental physicist, I am really bad at holding things steady.

Those 4 dots around the edges correspond to the diffracted streaks in the original image. Because the laser light is (approximately) monochromatic, we get diffracted dots rather than streaks.

Without a willing assistant in my endeavours, I only managed to take pictures at an oblique angle. To correct for this, I applied a a projective transformation to the image to flatten it out as if the picture had been taken on-axis:

The font is DIN Alternate Bold for those curious few.

The circle marks a radius of 36mm from the centre of the diffraction pattern, and shows that the four spots diffract at the same angle. If I plot the image intensity along a diagonal line through the two spots, it looks like:

Nice font for plots, don’t you think?

The standard equation for diffraction gratings states that the angle of the diffracted light depends on the wavelength and the grating period through

I was standing around 35cm from the TV screen for these photos, which plugging in to the above means the diagonal structures are around 5 microns in size. This is far too small, by a factor of 100, to be caused by the pixels (did I mention the TV is really big?), so must be caused by something else. Perhaps some structure in the matte plastic coating in front of the display? If anyone has an idea, please mention in the comments.


For the sake of completeness, we can also derive what we expected the diffracted light to look like, under a set of simplifying assumptions. Assuming that the pattern on the TV has a sinusoidal pattern of wavelength , the light on the card a distance away is formed from the superposition of many wavefronts reflected from across the width of the laser beam :

The amplitude of light on the card is then the integral

where , which after some quality time with a pen and paper (and Wolfram Alpha) evaluates to

The WordPress implementation of Latex didn’t handle this expression so well.

where the paraxial approximation was assumed. Calculating the intensity, i.e. , on the screen, the result is something like this:

Here was assume d = 5.1 microns and the laser is 3mm wide.

This doesn’t look too bad, but does still require a small feature size. For comparison, modelling different laser sizes and feature sizes generates the following plots:

w = 1mm, d = 5 microns

w = 1mm, d = 500 microns

w = 50 microns, d = 5 microns

w = 50 microns, d = 500 microns

The best agreement is therefore a very small feature illuminated by a large laser spot. As I said before, any ideas – let me know!

稿源:jasmcole (源链) | 关于 | 阅读提示

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