Difference between revisions of "AXIOM Beta/AXIOM Beta Software"

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This re-sampling method to scale up/down an image in real-time can be of rather low quality (nearest neighbor/bilinear/etc.) as it is only for preview purposes.
This re-sampling method to scale up/down an image in real-time can be of rather low quality (nearest neighbor/bilinear/etc.) as it is only for preview purposes.


=Tools=
==cmv_reg==
Get and Set CMV12000 image sensor registers (CMV12000 sports 128x16 Bit registers).


Details are in the sensor datasheet: https://github.com/apertus-open-source-cinema/beta-hardware/tree/master/Datasheets




'''Examples:'''


Read register 115 (which contains the analog gain settings):
cmv_reg 115


Return value:
0x00
Means we are currently operating at analog gain x1 = unity gain






Set register 115 to gain x2:
cmv_reg 115 1


==Setting Exposure Time==
To set the exposure time use the cmv_snap3 tool with -z parameter (this will tell the software to not save the image):
./cmv_snap3 -e 9.2ms -z
Note: The exposure time can be supplied in "s" (seconds), "ms" (milliseconds), "us" (microseconds) and "ns" (nanoseconds). Decimal values also work (eg. "15.5ms").
==mat4_conf.sh==
Read the details about the [[Matrix Color Conversion]] math/implementation.
To set the 4x4 color conversion matrix, you can use the mat4_conf.sh script:
The default configuration:
./mat4_conf.sh  1 0 0 0  0 1 0 0  0 0 1 0  0 0 0 1  0 0 0 0
'''
Please note that in current AXIOM Beta firmware the mat4 order is changed and the default matrix is:
./mat4_conf.sh 0.3 0.3 0.3 0.3  0 0 0 1  0 0.42 0.42 0  1 0 0 0
This will be changed to reflect the documentation again soon.'''
With the Black Magic Video Assist (BMVA), a nicer matrix (ie better skin color, less greenish):
./mat4_conf.sh 0.3 0.3 0.3 0.3  0 0 0 1  0 0.3 0.3 0  1 0 0 0
This 4x4 conversion matrix is a very powerful tool and allows to do things like mixing color channels, reassigning channels, applying effects or doing white balancing.
TODO: order is blue, green, red!
[[File:Mat4-conf-illustration-01.jpg | 700px]]
===4x4 Matrix Examples:===
./mat4_conf.sh  1 0 0 0  0 1 0 0  0 0 1 0  0 0 0 1    0 0 0 0  # unity matrix but not optimal as both green channels are processed separately
./mat4_conf.sh  1 0 0 0  0 0.5 0.5 0  0 0.5 0.5 0  0 0 0 1    0 0 0 0  # the two green channels inside each 2x2 pixel block are averaged and output on both green pixels
./mat4_conf.sh  0 0 0 1  0 1 0 0  0 0 1 0  1 0 0 0    0 0 0 0  # red and blue are swapped
./mat4_conf.sh  1 0 0 0  0 1 0 0  0 0 1 0  0 0 0 1    0.5 0 0 0    # red 50% brigther
./mat4_conf.sh  1 0 0 0  0 1 0 0  0 0 1 0  0 0 0 1.5    0 0 0 0    # blue multiplied with factor 1.5
./mat4_conf.sh  .25 .25 .25 .25  .25 .25 .25 .25  .25 .25 .25 .25  .25 .25 .25 .25    0 0 0 0    # black/white
./mat4_conf.sh  -1 0 0 0  0 -0.5 -0.5 0  0 -0.5 -0.5 0  0 0 0 -1    1 1 1 1    # negative


== Clipping ==
== Clipping ==

Revision as of 01:10, 6 November 2017


1 Misc Scripts

Display voltages and current flow:

./pac1720_info.sh

Output:

ZED_5V        	5.0781 V [2080] 	+29.0625 mV [2e8]   +968.75 mA
BETA_5V       	5.1172 V [20c0] 	+26.6016 mV [2a9]   +886.72 mA
HDN           	3.2422 V [14c0] 	 -0.0391 mV [fff]     -1.30 mA
PCIE_N_V      	3.2422 V [14c0] 	 -0.0391 mV [fff]     -1.30 mA
HDS           	3.2422 V [14c0] 	 +0.0000 mV [000]     +0.00 mA
PCIE_S_V      	3.2422 V [14c0] 	 -0.0391 mV [fff]     -1.30 mA
RFW_V         	3.2812 V [1500] 	 +0.2734 mV [007]     +9.11 mA
IOW_V         	3.2422 V [14c0] 	 +0.0000 mV [000]     +0.00 mA
RFE_V         	3.2812 V [1500] 	 +0.2344 mV [006]     +7.81 mA
IOE_V         	3.2812 V [1500] 	 +0.0781 mV [002]     +2.60 mA
VCCO_35       	2.5000 V [1000] 	 +0.6641 mV [011]    +22.14 mA
VCCO_13       	2.4609 V [ fc0] 	 +1.2500 mV [020]    +41.67 mA
PCIE_IO       	2.4609 V [ fc0] 	 -0.0391 mV [fff]     -1.30 mA
VCCO_34       	2.4609 V [ fc0] 	 +0.8203 mV [015]    +27.34 mA
W_VW          	1.9922 V [ cc0] 	 -0.0781 mV [ffe]     -2.60 mA
N_VW          	3.1641 V [1440] 	 +0.0000 mV [000]     +0.00 mA
N_VN          	1.8750 V [ c00] 	+15.4297 mV [18b]   +514.32 mA
N_VE          	3.1641 V [1440] 	 +0.0000 mV [000]     +0.00 mA
E_VE          	1.9922 V [ cc0] 	 -0.0391 mV [fff]     -1.30 mA
S_VE          	1.9531 V [ c80] 	 +0.0000 mV [000]     +0.00 mA
S_VS          	2.9297 V [12c0] 	 +0.3906 mV [00a]    +13.02 mA
S_VW          	1.9922 V [ cc0] 	 -0.1562 mV [ffc]     -5.21 mA

Read Temperature on Zynq:

./zynq_info.sh 

Output:

ZYNQ Temp     	49.9545 °C



2 Image Processing Nodes

2.1 Debayering

A planned feature is to generate this FPGA code block with "dynamic reconfiguration" meaning that the actual debayering algorithm can be replaced at any time by loading a new FPGA binary block at run-time. This tries to simplify creating custom debayering algorithms with a script like programming language that can be translated to FPGA code and loaded into the FPGA dynamically for testing.

2.2 Peaking Proposal

Peaking marks high image frequency areas with colored dot overlays. These marked areas are typically the ones "in-focus" currently so this is a handy tool to see where the focus lies with screens that have lower resolution than the camera is capturing.

Handy Custom Parameters:

  • color
  • frequency threshold

Potential Problems:

  • there are sharper and softer lenses so the threshold depends on the glass currently used. For a sharp lens the peaking could show areas as "in-focus" if they actually aren't and for softer lenses the peaking might never show up at all because the threshold is never reached

2.3 Image Blow Up / Zoom Proposal

Digital zoom into the center area of the image to check focus.

As extra feature this zoomed area could be moved around the full sensor area.

20140909152450-look-around.jpg


This feature is also related to the "Look Around" where the viewfinder sees a larger image area than is being output to the clean-feed.

This re-sampling method to scale up/down an image in real-time can be of rather low quality (nearest neighbor/bilinear/etc.) as it is only for preview purposes.






3 Clipping

scn_reg 28 0x00 # deactivate clipping
scn_reg 28 0x10 # activate low clipping
scn_reg 28 0x20 # activate high clipping
scn_reg 28 0x30 # activate high+low clipping


4 Operating System

At this moment we were able to reuse an Arch Linux image for the Zedboard on the Microzed. To do so, some software such as the FSBL and uboot were added. More information can be found here: http://stefan.konink.de/contrib/apertus/ I will commit myself on the production of a screencast of the entire bootstrap proces from the Xilinx software to booting the MicroZed.

I would suggest running Arch Linux on the AXIOM Beta for development purposes. If we need to shrink it down that will be quite trivial. Obviously we can take the embedded approach from there, as long as we don't fall in the trap of libc implementations with broken threading.




Pattern noise correction: --rnfilter=1  : FIR filter for row noise correction from black columns --rnfilter=2  : FIR filter for row noise correction from black columns

                     and per-row median differences in green channels

--fixrn  : Fix row noise by image filtering (slow, guesswork) --fixpn  : Fix row and column noise (SLOW, guesswork) --fixrnt  : Temporal row noise fix (use with static backgrounds; recommended) --fixpnt  : Temporal row/column noise fix (use with static backgrounds) --no-blackcol-rn  : Disable row noise correction from black columns

                     (they are still used to correct static offsets)

--no-blackcol-ff  : Disable fixed frequency correction in black columns

Flat field correction: --dchp  : Measure hot pixels to scale dark current frame --no-darkframe  : Disable dark frame (if darkframe-xN.pgm is present) --no-dcnuframe  : Disable dark current frame (if dcnuframe-xN.pgm is present) --no-gainframe  : Disable gain frame (if gainframe-xN.pgm is present) --no-clipframe  : Disable clip frame (if clipframe-xN.pgm is present) --no-blackcol  : Disable black reference column subtraction

                     - enabled by default if a dark frame is used
                     - reduces row noise and black level variations

--calc-darkframe  : Average a dark frame from all input files --calc-dcnuframe  : Fit a dark frame (constant offset) and a dark current frame

                     (exposure-dependent offset) from files with different exposures
                     (starting point: 256 frames with exposures from 1 to 50 ms)

--calc-gainframe  : Average a gain frame (aka flat field frame) --calc-clipframe  : Average a clip (overexposed) frame --check-darkframe  : Check image quality indicators on a dark frame

Debug options: --dump-regs  : Dump sensor registers from metadata block (no output DNG) --fixpn-dbg-denoised: Pattern noise: show denoised image --fixpn-dbg-noise  : Pattern noise: show noise image (original - denoised) --fixpn-dbg-mask  : Pattern noise: show masked areas (edges and highlights) --fixpn-dbg-col  : Pattern noise: debug columns (default: rows) --export-rownoise  : Export row noise data to octave (rownoise_data.m) --get-pixel:%d,%d  : Extract one pixel from all input files, at given coordinates,

                     and save it to pixel.csv, including metadata. Skips DNG output.

</nowiki>

Example:

./raw2dng --fixrnt --pgm --black=120 frame%05d.dng




5 Tutorials / Guides / Research / Topics

AXIOM Beta Firmware - Done

Installing a webserver on AXIOM Beta - Done

Wifi Access Point Setup - Done

AXIOM Beta as photography camera - Done

Factory Calibration - Done

Black Calibration

Pattern Noise

PLR

Sensor Cleaning - Done