I have a raw image that was taken with v4l2-ctl after the camera had been setup like:

# media-ctl -d /dev/media0 -l "'rzg2l_csi2 10830400.csi2':1 -> 'CRU output':0 [1]"
# media-ctl -d /dev/media0 -V "'rzg2l_csi2 10830400.csi2':1 [fmt:UYVY8_2X8/1280x960 field:none]"
# media-ctl -d /dev/media0 -V "'ov5645 0-003c':0 [fmt:UYVY8_2X8/1280x960 field:none]"

and then the picture got snapped with:

# v4l2-ctl --device /dev/video0 --stream-mmap --stream-to=frame.raw --stream-count=1

now I've tried multiple methods to convert this into a jpeg but nothing seems to yield the expected output

the raw file can be downloaded here: https://drive.google.com/file/d/1VqXnrJDYbzdtSsWfTlm2mX9rl1-Rl_7F/view?usp=sharing

I tried out the following command:

convert -verbose -size 1280x960 UYVY:frame.raw frame.bmp

which I found on Converting from YUV(UYVY) to RGB using imagemagick

but it doesn't do the trick

  • 1
    Maybe you could share the raw file via Google Drive or Dropbox or similar. Feb 2, 2022 at 20:50
  • @MarkSetchell I did add a link to the post above.
    – stdcerr
    Feb 2, 2022 at 22:08
  • 1
    It's late here now so I'll take a look tomorrow if no-one else has helped by then. Feb 2, 2022 at 22:33
  • Thank you @MarkSetchell , I will do more research myself too! I'm looking forward to getting your response tomorrow then, have a good evening & night!
    – stdcerr
    Feb 2, 2022 at 23:00

1 Answer 1


Your frame is 2457600 bytes and your pixel dimensions are 1280x960, so you have:

bits per pixel = 2457600 * 8 / (1280 * 960) = 16

You can get a list of the pixel formats that ffmpeg supports using:

ffmpeg -pix_fmts 2> /dev/null

Sample Output

IO... yuv420p                3            12
IO... yuyv422                3            16
IO... rgb24                  3            24
IO... bgr24                  3            24
IO... yuv422p                3            16
IO... yuv444p                3            24
IO... yuv410p                3             9

That means you can get a list of pixel formats that contain Y, U and V with 16 bits per pixel like this:

ffmpeg -pix_fmts 2> /dev/null | awk '/y/ && /u/ && /16$/ {print}'  

IO... yuyv422                3            16
IO... yuv422p                3            16
IO... yuvj422p               3            16
IO... uyvy422                3            16
IO... yuv440p                3            16
IO... yuvj440p               3            16
IO... yvyu422                3            16

Now you can run a loop, iterating over all the 16-bit per pixel YUV formats and see what ffmpeg makes of your image - naming each result after the format so you can identify which is which:

ffmpeg -pix_fmts 2> /dev/null | 
   awk '/y/ && /u/ && /16$/ {print $2}' | 
      while read f; do 
         ffmpeg -y -s:v 1280x960 -pix_fmt $f -i frame.raw $f.jpg

That gives you these files:

-rw-r--r--  1 mark  staff  304916  3 Feb 09:38 yuv440p.jpg
-rw-r--r--  1 mark  staff  227123  3 Feb 09:38 yuvj422p.jpg
-rw-r--r--  1 mark  staff   39543  3 Feb 09:38 yuyv422.jpg
-rw-r--r--  1 mark  staff   39545  3 Feb 09:38 yvyu422.jpg

And I guess that yuyv422.jpg is your image, so that means you can extract it with:

ffmpeg -y -s:v 1280x960 -pix_fmt yuyv422 -i frame.raw result.jpg

enter image description here

If you wanted to do that with ImageMagick, you could do something like this:


python3 <<EOF
import numpy as np
h, w = 960, 1280

# Load raw file into Numpy array
raw = np.fromfile('frame.raw', np.uint8)
raw[0::2].tofile('Y')     # Starting at the 1st byte, write every 2nd byte to file "Y"
raw[1::4].tofile('U')     # Starting at the 2nd byte, write every 4th byte to file "U"
raw[3::4].tofile('V')     # Starting at the 3rd byte, write every 4th byte to file "V"

# Load the Y channel, then the U and V channels forcibly resizing them, then combine and go to sRGB
magick -depth 8 -size 1280x960 gray:Y \
  \( -size 640x960 gray:U gray:V -resize 1280x960\! \) \
  -set colorspace YUV -combine -colorspace sRGB result.jpg

If yo don't like/have Python, that part can be replaced with some basic C as follows:

#include <stdint.h>
#include <stdio.h>

// Split YUYV file called "frame.raw" into separate channels with filenames "Y", "U" and "V"
// Compile with: clang -O3 splitter.c -o splitter

int main(){

   FILE    *in, *Y, *U, *V;
   uint8_t buffer[4];
   size_t  bytesRead;

   // Open input file and 1 output file per channel
   in = fopen("frame.raw", "rb");   
   Y  = fopen("Y", "wb");   
   U  = fopen("U", "wb");   
   V  = fopen("V", "wb");   

   // read up to sizeof(buffer) bytes
   while ((bytesRead = fread(buffer, 1, sizeof(buffer), in)) > 0)
      fputc(buffer[0], Y);
      fputc(buffer[1], U);
      fputc(buffer[2], Y);
      fputc(buffer[3], V);

Having had so much fun doing ffmpeg, Python, and C versions, I thought I'd try just doing it in the shell - converting bytes to lines and so I could pick alternate lines instead of alternate bytes. This works the same as the above:


# Build JPEG image from YUYV image with packed bytes in order YUYVYUYV...
# Use "xxd" to convert bytes into lines, then extract alternate lines - which is easier than extracting bytes


# Take top byte of every uint16 and put into "Y.pgm"
xxd -c1 -p "$INPUT" | sed -n 'p;n' | xxd -r -p | magick -size ${W}x${H} -depth 8 gray:- Y.pgm

# Take bottom byte of every 2nd uint16, starting at the 1st, resize up to full width and put into "U.pgm"
xxd -c1 -p "$INPUT" | sed -n 'n;p' | sed -n 'p;n' | xxd -r -p | magick -size $((W/2))x${H} -depth 8 gray:- -resize ${W}x${H}\! U.pgm

# Take bottom byte of every 2nd uint16, starting at the 2nd, resize up to full width and put into "V.pgm"
xxd -c1 -p "$INPUT" | sed -n 'n;p' | sed -n 'n;p' | xxd -r -p | magick -size $((W/2))x${H} -depth 8 gray:- -resize ${W}x${H}\! V.pgm

# Load the 3 channels, combine and convert to JPEG
magick {Y,U,V}.pgm -set colorspace YUV -combine -colorspace sRGB result.jpg

# Remove litter
rm {Y,U,V}.pgm

As regards colour cast removal, as I said in the comments, the " normal" way, AFAIK, is to get the average colour of the image and invert its Hue then blend that "negated cast" back with the original image to offset the original colour cast. Here is a crude attempt - if anyone knows better please ping me!

Step 1: Get average colour cast

magick result.jpg -resize 1x1\! cast.png

enter image description here

Step 2: Invert the cast

magick cast.png -modulate 100,100,0 correction.png

enter image description here

Step 3: Blend the original with the correction and brighten maybe

magick result.jpg correction.png -define compose:args=50,50 -compose blend -composite -auto-level result.jpg

Here are the original and corrected versions:

enter image description here

Obviously you can change the percentages for different degrees of "correction".

  • the version utilizing ImageMagick however seems to work fine as expected!
    – stdcerr
    Feb 3, 2022 at 15:45
  • 1
    The ffmpeg one should actually work - despite giving an error message. Feb 3, 2022 at 15:46
  • True, it does work. My apologies, I added the loop into s script and that doesn't work, it gives me: No such pixel format: uvj440p. frame.raw: Invalid argument but the selected command by itself: ffmpeg -y -s:v 1280x960 -pix_fmt yuyv422 -i frame.raw result.jpg works fine! Thanks very much for your help!
    – stdcerr
    Feb 3, 2022 at 15:49
  • 1
    Cool - my pleasure. Good luck with your project! Feb 3, 2022 at 15:54
  • 1
    The "normal" way is to get the average colour of the image, invert the hue and blend that back with the original to offset the colour cast. I would suggest you ask a new question to see if any of the rather knowledgeable folk on here have a better idea. Be sure to frame it as a programming question not a Photoshop question else it will get closed. Your image is actually also rather under-exposed which probably isn't helping either. Tag a new question as image-processing. Feb 5, 2022 at 8:14

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