Difference between revisions of "AXIOM Beta/Enclosures"

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The AXIOM Beta Developer Kit (ABDK) has a skeleton framework instead of an enclosure allowing easy access to the electronics but at the same time providing a strong and solid link between hardware, lens mount and tripod mount base. This is great for developers and in lab conditions so there are several sub-projects that focus on adding a protective enclosure (shell) around this skeleton.
There are several AXIOM Beta enclosure variants, some are finished and available and some are still in development. The AXIOM Beta Developer Kit (ABDK) has a skeleton framework instead of an enclosure allowing easy access to the electronics but at the same time providing a strong and solid link between hardware, lens mount and tripod mount base. This is great for developers and in lab conditions and there are several sub-projects that focus on adding a protective enclosure (shell) around this skeleton.


===Simple Enclosure===
=Skeleton Framework=
The Simple Enclosure is meant to wrap a "skin" around the camera's electronics and CNC milled metal skeleton parts. The Simple Enclosure is designed in a way that can be produced with any consumer 3d printer. The design is not finished yet, please help finish and test it.
The AXIOM Beta Developer kit uses the CNC milled aluminium skeleton frame and consists of the following components; Footplate, Skeleton, E-Mount lens mount and M3 threaded rods that hold the PCB Stack in place.  


https://cad.onshape.com/documents/15b58e5500d917fd327e95ef/w/7ed95a699b599a370a7f55ff/e/f97fa229ef96cd1e6d0c4a40
* See Parts: [[10-Enclosures_and_Associated_Mechanical_Parts]]... for detailed specifications.
* Skeleton and Skeleton Footplate stl and stp files: https://github.com/apertus-open-source-cinema/beta-hardware/tree/master/Enclosure/Skeleton_E-mount
* Onshape PCB Stack and Skeleton Assembly: [https://cad.onshape.com/documents/58bd498285673a104722aacd/w/466b8105bf6807b3f4f50b6c/e/b33cc7b3cc3cc5eebd5c2ae6 OnShape]


[[File:10-DKSF Stack- ABDK Skeleton Frame.png]]


==Mechanical Assembly==


===Transparent Enclosure===
Skeleton and Footplate are attached to each other with 2x tapered M3x12 - M3x16 screws.
A transparent enclosure is useful for showcasing the camera's printed circuit boards and for allowing to understand quickly what may or may not be going on simply by looking at the camera's status LEDs. The design is made so it can be laser cut with a 3mm thick acrylic glass. Acrylic glass comes is many variations and colors and could also be used to print logos or text labels on the exterior.


Nylon spacers, washers and nuts are used on the M3 threaded rods to hold the PCBs in the correct distances.


'''Simple transparent enclosure for the AXIOM Beta, version 0.2.'''
==Distance between Image Sensor and first PCB==


'''Note:''' There are two versions of the Image Sensor Frontend with differing image sensor to PCB distances.


[https://wiki.apertus.org/index.php/Beta_CMV12K_ZIF_Sensor_Board ZIF option] left, [https://wiki.apertus.org/index.php/Beta_CMV12K_THT_Sensor_Board THT option] right:


[[File:Beta-simple-transparent-enclosure v0.2.svg| 1150px]]
[[File:Axiom-beta-image-sensor-distances.png]]


[[File:ABTDSMt01 SpacerMeasurements THTSFE.png]]


Spacers for ZIF Version (front to back): washer, nut, 15mm spacer, washer, Main Board


M3 rod cut lengths:


* AXIOM Beta ZIF: 2x 69mm + 2x 47mm
* AXIOM Beta THT: 2x 66mm + 2x 44mm


''Key : Black => to be cut ; Red => to be engraved ; Green => comments (not to be cut or engraved)''
See [https://wiki.apertus.org/index.php/20-Screws,_Rods,_Spacers,_Rings_and_Nuts Parts]


Open and edit the above image with Inkscape or similar.
==Dimensions==


{| class="wikitable" style="width: 100%;background:#fcfcfc;"
|+ style="text-align: left;" |
|-
! scope="col" | !! scope="col" | Height !! scope="col" | Width !! scope="col" | Length !! scope="col" | Weight
|-
! scope=row style="text-align: left;" | AXIOM Beta Skeleton Frame
| 65.1mm || 111.76mm || 9mm || 47.9g
|-
! scope=row style="text-align: left;" | Skeleton Footplate
| 45mm || 30mm || 8mm || 27.9g
|-
! scope=row style="text-align: left;" | E-mount Lens Tube
| NA || 61mm diameter|| NA || 28g
|-
! scope="row" style="text-align: left;" | AXIOM Beta Developer Kit (board stack, footplate, lens tube & skeleton enclosure)
| 65.1mm || 111.76mm|| 74mm || 319g
|}


=Simple Enclosure=
The Simple Enclosure provides a basic "skin" around the camera's electronics and CNC milled metal skeleton framework parts. The Simple Enclosure is designed in a way that can be produced with any consumer 3d printer. The design is not finished yet, please help finish and test it.


CAD Onshape [https://cad.onshape.com/documents/15b58e5500d917fd327e95ef/w/7ed95a699b599a370a7f55ff/e/f97fa229ef96cd1e6d0c4a40 project].


=Transparent Enclosure=
A transparent enclosure is useful for demonstrating the camera's printed circuit boards and monitoring of the camera's status LEDs. The design is made so it can be laser-cut with 3mm thick acrylic glass. Acrylic glass comes in many variations and colors and could also be used to print label text on the exterior. The acrylic sheets are designed to be installed around the camera's electronics and CNC milled metal skeleton framework parts.


[[File:Lase Cut Clear 03 sm b.jpg| 1150px]]
'''Simple transparent enclosure for the AXIOM Beta, version 0.2.'''


'''Note:''' There may be scope for improvement by making the case slightly bigger (few mm wider for the front and back side), so that the HDMI cable can fit nicely in the enclosure (and you don't need to shave some plastic off the cable). If you make any alterations please update this page with modifications accordingly.
[[File:Beta-simple-transparent-enclosure v0.2.svg]]


''Key : Black => to be cut ; Red => to be engraved ; Green => comments (not to be cut or engraved)''


Open and edit the above image with Inkscape or similar.


[[File:Lase Cut Clear 03 sm b.jpg]]


====Distance between Image Sensor and first PCB====
'''Note:''' There may be scope for improvement by making the case slightly bigger (few mm wider for the front and back side), so that the HDMI cable can fit nicely in the enclosure (and you don't need to shave some plastic off the cable). If you make any alterations please update this page with modifications accordingly.
Note that there are two versions of the Image Sensor Frontend with different image sensor to PCB distances. The transparent enclosure has been designed for the ZIF (CPU Socket) variant of the Sensor Frontend.
 
[[File:Axiom-beta-image-sensor-distances.png | 800px]]


The transparent enclosure has been designed for the ZIF (CPU Socket) variant of the Sensor Frontend but should also work fine with the THT Sensor Frontend.


==Heat Dissipation==


====Heat Dissipation====
Tests have shown that this transparent enclosure makes the Zynq on the Microzed prone to overheating (due to a lack of air circulation) which creates general erratic camera behaviour. Other parts in the camera can get too hot as well of course. A newer design with a larger fan on top of the enclosure has shown significant improvements in keeping the Zynq at a constant temperature.
Tests have shown that this transparent enclosure makes the Zynq on the microzed prone to overheating (due to the lack of air circulation) which creates general erratic camera behavior. Other parts in the camera can get too hot as well of course. A newer design with a larger fan on top of the enclosure has shown significant improvements to keeping the Zynq on a constant temperature.


"Case" is the above laser cut transparent enclosure<br />
"Case" is the above laser cut transparent enclosure<br />
Line 55: Line 89:
"final" the final improved design with a big fan at the top of the PCB stack but no fan on the microzed heatsink (see below)<br />
"final" the final improved design with a big fan at the top of the PCB stack but no fan on the microzed heatsink (see below)<br />


[[File:Case_power.png | 400px]] [[File:Case_sensor.png |400px]] [[File:Case_ddr.png | 400px]] [[File:Case_zynq.png | 400px]]




In a closed case it's all about the air flow,  so you need to carefully consider where the air enters and leaves the case. Ventilating out through holes above the fan is recommended. It's best to make a sort of wind-tunnel effect if you like. If you simply put a few 'holes' at the back and have a gap between fan and case, the hot air will mostly circulate inside the case, which is not what you want.  
<gallery mode="packed" heights="150">
Image:Case_power.png|
Image:Case_sensor.png|
Image:Case_ddr.png|
Image:Case_zynq.png|
</gallery>


It's also recommended to measure various temperatures on the camera and monitor them during use with and without case.
In a closed case air flow is important and, in this case, ventilating out through holes above the fan is recommended. If you simply put a few 'holes' at the back and have a gap between a fan and the case then hot air will likely circulate inside the case, which is not what you want. Instead, it's good practice to make a 'wind-tunnel' effect, let's say.  


To get a reading of Zync temperature:
It's also recommended to measure various temperatures on the camera and monitor them during use cases with and without case. See [[AXIOM Beta/Temperatures|Temperature Sensors]] for more information.


$ ./zynq_info.sh will give you the zynq temp,
The Zynq will work relatively fine up to 85°C, although that is a little high for normal use. For the sensor, you want to keep temperature quite low, typically not more than a few degrees above room temperature, so adding holes or slits close to the sensor is a good idea.


Always keep in-take holes/slits at the bottom or at least bottom side, because it aids natural convection. As a rule of the thumb, for intake you want to have about 1.5-2x the area you have for the exhaust (in total, which is the inside area of the fan). If you have too little intake, the fan gets slowed down, if you have to much, cooling will be ineffective.


To get a reading of Power Board temperature:
=Transparent/3D Printed Enclosure=


$ cat /sys/class/hwmon/hwmon0/temp[0-9]_input
Improved version based on the transparent enclosure (above) whereby some of the enclosure sides are 3D printed instead of being laser cut. It adds a StarTech FAN6X1TX3 60x60x10mm at top of enclosure which solves the above mentioned heat dissipation issues.




To get a reading of the Sensor's temperature
<gallery mode="packed" heights="300">
Image:improved_transparent_enclosure_front.jpg| improved transparent enclosure front.
Image:improved_transparent_enclosure_back.jpg| improved transparent enclosure back.
</gallery>


$ cmv_reg 127


'''Build Instructions:'''


The zynq will work relatively fine up to 90°C, although that is a little high for normal use. For the sensor, you want to keep temperature quite low, typically not more than a few degrees above room temperature, so adding holes or slits close to the sensor is a good idea.  
# Laser cut acrylic sheets as defined in axiombetatransparentplot.top60x60fan.svg (all plates, except the "top" and the back side).
# 3D print the 2 STL files.
# Assemble.
# Affix StarTech FAN6X1TX3 60x60x10mm cooler fan to the top plate and connect to fan connector on the [[AES-Z7MB-7Z020-SOM-G | Microzed]] .
# Each of the enclosure'opposite plates are to be held together by one or more Φ 3 mm threaded rods together with corresponding nuts (locknuts can be considered for this application - https://en.wikipedia.org/wiki/Locknut - but have not been tested yet) mounted on the exterior on each side. For the back and the front plate the rods are the same four that hold together the PCBs and the skeleton mount, albeit longer ones will be required (min 7.7 cm). For the left and right plate there the current implementation requires only one Φ 3 mm threaded rod of aprox 15 mm in length. In the current version the holes for the threaded rod in the top and bottom plate require adjustments & are misaligned, but it will be fixed in the next version (however, tests show that the enclosure holds together just fine with just the left-right & front-back rods). No shock/vibration tests have been run on it, so consider this unexplored space.


Always keep in-take holes/slits at the bottom or at least bottom side, because it aids natural convection. As a rule of the thumb, for intake you want to have about 1.5-2x the area you have for the exhaust (in total, which is the inside area of the fan). If you have too little intake, the fan gets slowed down, if you have to much, cooling will be ineffective.


===Transparent/3D Printed Enclosure===


This is the improved version based on the transparent enclosure (above) and designates some of the enclosure sides to be 3D printed instead of laser cut. It adds a StarTech FAN6X1TX3 60x60x10mm at the top of the enclosure which solve the above mentioned heat dissipation problems.
Download: [[File: Transparent-3d-print-enclosure.zip]]


[[File:improved_transparent_enclosure_front.jpg|400px]] [[File:improved_transparent_enclosure_back.jpg|400px]]
=AXIOM Beta Compact Enclosure=


'''Instructions:'''
The AXIOM Beta Compact is an all metal enclosure for the AXIOM Beta and is CNC milled from aluminium and then anodized. Labels/logos are laser engraved.


# laser cut acrylic sheets as defined in axiombetatransparentplot.top60x60fan.svg (all plates, except the "top" and the back side)
# 3D print the 2 STL files
# assemble them all together
# strap a StarTech FAN6X1TX3 60x60x10mm cooler fan to the top plate and connect it to the FAN connector on the MicroZed
# each two opposite plates are to be held together by one or more Φ 3 mm threaded rods together with the corresponding nuts (locknuts can be considered for this application - https://en.wikipedia.org/wiki/Locknut - but have not been tested yet) mounted on the exterior on each side. For the back and the front plate the rods are the same four that hold together the PCBs and the skeleton mount, albeit longer ones will be required (min 7.7 cm). For the left and right plate there the current implementation requires only one Φ 3 mm threaded rod of aprox 15 mm in length. In the current version the holes for the threaded rod in the top and bottom plate require adjustments & are misaligned, but it will be fixed in the next version (however, tests show that the enclosure holds together just fine with just the left-right & front-back rods). No shock/vibration tests have been run on it, so consider this unexplored space.


Download: [[File:Transparent-3d-print-enclosure.zip]]
[[File:FINEPIX X100 4 L.JPG]]
''The design is inspired by analogue photo cameras "sandwich" design where silver elements on top and bottom sandwich a black mid section.''


===AXIOM Beta Compact Enclosure===


The AXIOM Beta Compact is designed to be CNC milled from aluminum and then ceramic coated or anodized
[[File:AXIOM-Beta-CP-w-Lens-on-e1e1e1.jpg]]
''Concept Rendering of the AXIOM Beta Compact Enclosure''


Design still in progress - not finished yet.


All dimensions are in millimeter.
[[File:Cp-asselby03.jpg]]
We manufactured two generations of prototypes in very small quantities and in 2023 had the first small batch manufactured for early adopters.


Labels/logos will be pad printed.


For detailed specifications and part numbers for individual components see [[10-Enclosures and Associated Mechanical Parts]]
Latest designs are in this Onshape 3D CAD [https://cad.onshape.com/documents/3535c21cf854f2c60256f1e1/w/8f5eb4d6ca1d6084ac623d92/e/e55676d6a8dc9d72015268c9?renderMode=0&uiState=651933db00f6501fda42dd16 project].


[[File:10-CEEM Stack- ABCP Enclosure E-Mount.jpg  | 1150px |]]
(Onshape is a CAD design software that's entirely browser based - good for collaboration in an open source project. You can view/inspect without an account but to export/download a free account is required - paid accounts only required for private designs).  


Latest designs are in this Onshape 3D CAD project: https://cad.onshape.com/documents/0e2510289c094498d83e1212/w/915b3a711de36102371778be/e/5505fab1dbb24db8b6f43eab
==Thermal Expansion of Lens Assembly==
According to https://goodcalculators.com/thermal-expansion-calculator/ and an aluminium lens mount assembly with a distance from sensor to bayonet of 19.4mm, the thermal expansion of 25°C temperature difference is 0.01mm, so can be considered negligible.


Onshape is a CAD design software that is entirely browser based which is great for collaboration in an open source project - also they made it free as long as you only need public designs - which is what we want anyways in an open source project.
==E-mount FFD verification==


The defined flange focal distance (FFD) between image sensor plane and lens bayonet for e-mount is 18mm. Though glass elements in the optical path affect that distance as they have a higher density as the air the light is envisioned to pass through in that 18mm (https://www.spektrum.de/lexikon/optik/planflaechenabbildung/2588).


====Open TODOs:====
'''AXIOM Beta Compact Enclosure Optical Path (cross section):'''
* design rod support base (optional, no priority at the moment)  


* Air Filter related decisions at top and bottom - separate evaluation/measurement device design finished
[[File:CP_enclosure_optical_Path_V2.jpg]]
* design plugin module enclosure concept that can be used/adapted for any length plugin modules (standing out of the back of the compact enclosure)
* shorten the lens mount assembly slightly so that shimming can be done
* add a second filter holder to the stack
* prototype side pates when image sensor to Sensor Board distance is set/measured
* rubber feet for cap bottom (this one? https://www.tme.eu/at/details/fix-sf-070620/beine/fix-fasten/ )?
* add marker to lens mount and front plate as the lens mount can be attached in 4 different positions currently -> evaluate pad printing process in-house
* switch m3 rods for long m3 screws, adjust back clamp and plugin holder accordingly to allow for the screwhead
* image sensor silicon rubber thermal pad connection to heatsink
* add rubber o rings to filter holders and lens mount


==== E mount FFD verification ====
[[File:ABTDLnsFFD01 AXIOM Beta E-Mount FFD Verification.png  | 1150px]]


'''Distance Notes:'''
'''Distance Notes:'''


* Spring ring under bayonet: 0.3mm thickness
* Spring ring under bayonet: 0.3mm thickness
* Sensor CMOS surface to outer front plate surface: 6.75mm
* Sensor CMOS surface to outer front plate surface: Version 1: 6.75mm / Version 2: 4.75mm + 0.244mm (delta from cover glass)
* every filter holder thickness should be 2mm + own filters delta (the assembly always requires two filter holders in place for the correct FFD)
* shimming should account for 0.15mm in the FFD


==== Cooling and Airflow ====
==Cooling and Airflow==
At the top of the AXIOM Beta Compact enclosure in the "Cap Top" part there is a 60x60x10mm fan. By using a larger fan we can spin it slower which makes it more silent in operation. Pulling air in and pushing it out (with the fan at the exit) is in general a more silent approach then pushing the air in at an entrance. The fan pushes hot air out at the top. The air enters the enclosure at the bottom ventilation holes and flows through the electronics. As heat rises this natural motion is supported by the fan.
At the top of the AXIOM Beta Compact enclosure in the "Cap Top" part and it integrates a 12V 60x60x10mm fan. By using a relatively large fan we can spin it slower meaning more silent operation. The fan pushes hot air out at the top. The air enters the enclosure at the bottom ventilation holes and flows through the electronics. As heat rises this natural motion is supported by the fan.


[[File:60x60fan-top-cap.jpg | 500px]]
[[File:60x60fan-top-cap.jpg | 1150px]]


The fan is held in place by 4x M3x5 socket head screws.  
There is a thin layer of PVC with fine hole grid pattern as filter.


There is a thin layer of PVC with fine hole grid as filter between the fan and the aluminum.
Image sensor cooling is done with a custom two part heat sink attached to the back of the image sensor with a silicon rubber thermal pad and pushed onto the image sensor back with 2 spring screws. The heat sink elements are anodized as according to https://www.gabrian.com/anodized-aluminum-heatsinks-what-you-need-to-know/ this increases the surface emissivity.


Image sensor cooling is envisioned with a custom two part heatsink attached to the back of the image sensor with a heat conductive tape (https://www.amazon.de/Tuloka-Thermisches-doppelseitig-integrierte-Schaltungen/dp/B06Y64H26X/ with 0.25mm thickness).
==Filter Holders==


====IR/UV Cut-off Filter====
The default stack contains two optical filter holders:
*1x UV/IR cut off filter
*1x empty (to provide space for adding a second filter later on)
 
Each filter holder features two orientation pins to prevent being inserted in a wrong orientation. These orientation pins also act as shim holder.
 
Each filter holders thickness is 2mm by default plus the FFD delta as a result of the optical filter holders own filter thickness/density. So in reality an optical filter holder will be something like 2.15 or 2.34mm thick depending on the glass element it holds.
 
The filter holder incorporates a rubber gasket ring with 1.5mm thickness and 58mm outer diameter, 55mm inner diameter corresponding to a ring length of 177.5mm. (eg. https://www.ebay.com/itm/10x-Metric-Nitrile-Rubber-NBR-O-Ring-Seals-Washers-Cross-Section-1-5mm-OD-5-80mm/173895045434) This gasket seals the holder towards the image sensor side.
 
===UV/IR cut off filter===


The visible spectrum that humans can see ranges from 380 - 750 nm.
The visible spectrum that humans can see ranges from 380 - 750 nm.
Line 161: Line 202:
UQG Optics offer 40x40x1.1mm UV/IR Cut off filters with 400 - 690nm bandpass
UQG Optics offer 40x40x1.1mm UV/IR Cut off filters with 400 - 690nm bandpass


 
==Thread Inserts==
 
====Thread Inserts====


We decided to use thread inserts for all external attachment points (1/4" and 3/8") instead of cutting threads into the aluminum directly. This is a bit more expensive but the threads are stronger, easier to replace in case any of them wear or get damaged over time so its better for repair-ability. We opted for steel helicoils as thread inserts.
We decided to use thread inserts for all external attachment points (1/4" and 3/8") instead of cutting threads into the aluminum directly. This is a bit more expensive but the threads are stronger, easier to replace in case any of them wear or get damaged over time so its better for repair-ability. We opted for steel helicoils as thread inserts.




====AXIOM Shell====
==AXIOM Shell==
features this cold shoe: https://camvate.en.alibaba.com/product/60759856560-806884690/2018_Aluminum_Alloy_hot_shoe_mount_adapter_with_1_4_20_Thread.html
features this [https://camvate.en.alibaba.com/product/60759856560-806884690/2018_Aluminum_Alloy_hot_shoe_mount_adapter_with_1_4_20_Thread.html cold shoe].
 
===Enclosures and Temperatures===
 
In a closed case it's all about the air flow,  so you need to carefully consider where the air enters and leaves the case. Ventilating out through holes above the fan is recommended. It's best to make a sort of wind-tunnel effect if you like. If you simply put a few 'holes' at the back and have a gap between fan and case, the hot air will mostly circulate inside the case, which is not what you want.
 
It's also recommended to measure various temperatures on the camera and monitor them during use with and without case. 
 
./zynq_info.sh
 
... will give you the zynq temp,
 
 
cat /sys/class/hwmon/hwmon0/temp[0-9]_input
 
... will give you power board temp
 
 
cmv_reg 127
 
... will give the temperature of the sensor.
 
 
The zynq will work relatively fine up to 90°C, although that is a little high for normal use. For the sensor you want to keep temperature quite low - typically not more than a few degrees above room temperature, so adding holes or slits close to the sensor is a good idea.
 
Always keep in-take holes/slits at the bottom or at least bottom side, because it aids natural convection. As a rule of the thumb, for intake you want to have about 1.5-2x the area you have for the exhaust (in total, which is the inside area of the fan). If you have too little intake, the fan gets slowed down, if you have to much, cooling will be ineffective.
 
 
 
===General Enclosure Design Topics===
 
From Labs:


[https://lab.apertus.org/T818 Weatherproof Enclosure]
==Extended Plugin Module Cartridge==
Plugin Modules can be any length, for this concept a flexible way to enclose the PCB is required. The following concept is a 2 part assembly:


[https://lab.apertus.org/M34 Axiom Beta new enclosure and labeling]
[[File:Plugin_module_cartridge_01.jpg]]


[https://lab.apertus.org/T816 Select Enclosure Feet]
To make space for the cartridge walls plugin module PCBs that shall fit into this extended cartridge need to be a bit less high (max: 26.575mm).


[https://lab.apertus.org/tag/axiom_beta_hardware/board/ AXIOM Beta Workboard]
[[File:Plugin_module_cartridge_02.jpg]]


Further requirements for the PCB so it will fit inside this cartridge enclosure:
* component height on bottom side is limited to 3mm
* component height on top side is limited to 7.5mm


----
Example of a 60mm long cartridge installed in CP enclosure top slot and HDMI (normal length) Plugin Module installed in bottom slot.:


[[File:Plugin_module_cartridge_03.jpg]]


===Legacy===
=Legacy=


[[Body Design Options]]
[[Body Design Options]]

Latest revision as of 14:58, 11 January 2024

There are several AXIOM Beta enclosure variants, some are finished and available and some are still in development. The AXIOM Beta Developer Kit (ABDK) has a skeleton framework instead of an enclosure allowing easy access to the electronics but at the same time providing a strong and solid link between hardware, lens mount and tripod mount base. This is great for developers and in lab conditions and there are several sub-projects that focus on adding a protective enclosure (shell) around this skeleton.

1 Skeleton Framework

The AXIOM Beta Developer kit uses the CNC milled aluminium skeleton frame and consists of the following components; Footplate, Skeleton, E-Mount lens mount and M3 threaded rods that hold the PCB Stack in place.

10-DKSF Stack- ABDK Skeleton Frame.png

1.1 Mechanical Assembly

Skeleton and Footplate are attached to each other with 2x tapered M3x12 - M3x16 screws.

Nylon spacers, washers and nuts are used on the M3 threaded rods to hold the PCBs in the correct distances.

1.2 Distance between Image Sensor and first PCB

Note: There are two versions of the Image Sensor Frontend with differing image sensor to PCB distances.

ZIF option left, THT option right:

Axiom-beta-image-sensor-distances.png

ABTDSMt01 SpacerMeasurements THTSFE.png

Spacers for ZIF Version (front to back): washer, nut, 15mm spacer, washer, Main Board

M3 rod cut lengths:

  • AXIOM Beta ZIF: 2x 69mm + 2x 47mm
  • AXIOM Beta THT: 2x 66mm + 2x 44mm

See Parts

1.3 Dimensions

Height Width Length Weight
AXIOM Beta Skeleton Frame 65.1mm 111.76mm 9mm 47.9g
Skeleton Footplate 45mm 30mm 8mm 27.9g
E-mount Lens Tube NA 61mm diameter NA 28g
AXIOM Beta Developer Kit (board stack, footplate, lens tube & skeleton enclosure) 65.1mm 111.76mm 74mm 319g

2 Simple Enclosure

The Simple Enclosure provides a basic "skin" around the camera's electronics and CNC milled metal skeleton framework parts. The Simple Enclosure is designed in a way that can be produced with any consumer 3d printer. The design is not finished yet, please help finish and test it.

CAD Onshape project.

3 Transparent Enclosure

A transparent enclosure is useful for demonstrating the camera's printed circuit boards and monitoring of the camera's status LEDs. The design is made so it can be laser-cut with 3mm thick acrylic glass. Acrylic glass comes in many variations and colors and could also be used to print label text on the exterior. The acrylic sheets are designed to be installed around the camera's electronics and CNC milled metal skeleton framework parts.

Simple transparent enclosure for the AXIOM Beta, version 0.2.

Beta-simple-transparent-enclosure v0.2.svg

Key : Black => to be cut ; Red => to be engraved ; Green => comments (not to be cut or engraved)

Open and edit the above image with Inkscape or similar.

Lase Cut Clear 03 sm b.jpg

Note: There may be scope for improvement by making the case slightly bigger (few mm wider for the front and back side), so that the HDMI cable can fit nicely in the enclosure (and you don't need to shave some plastic off the cable). If you make any alterations please update this page with modifications accordingly.

The transparent enclosure has been designed for the ZIF (CPU Socket) variant of the Sensor Frontend but should also work fine with the THT Sensor Frontend.

3.1 Heat Dissipation

Tests have shown that this transparent enclosure makes the Zynq on the Microzed prone to overheating (due to a lack of air circulation) which creates general erratic camera behaviour. Other parts in the camera can get too hot as well of course. A newer design with a larger fan on top of the enclosure has shown significant improvements in keeping the Zynq at a constant temperature.

"Case" is the above laser cut transparent enclosure
"Open" refers to the developer kit without enclosure
"Chimney" an intermediate design improvement attempt
"2xFan" a further improved design with a smaller fan on the microzed and a big fan at the top of the PCB stack
"final" the final improved design with a big fan at the top of the PCB stack but no fan on the microzed heatsink (see below)


In a closed case air flow is important and, in this case, ventilating out through holes above the fan is recommended. If you simply put a few 'holes' at the back and have a gap between a fan and the case then hot air will likely circulate inside the case, which is not what you want. Instead, it's good practice to make a 'wind-tunnel' effect, let's say.

It's also recommended to measure various temperatures on the camera and monitor them during use cases with and without case. See Temperature Sensors for more information.

The Zynq will work relatively fine up to 85°C, although that is a little high for normal use. For the sensor, you want to keep temperature quite low, typically not more than a few degrees above room temperature, so adding holes or slits close to the sensor is a good idea.

Always keep in-take holes/slits at the bottom or at least bottom side, because it aids natural convection. As a rule of the thumb, for intake you want to have about 1.5-2x the area you have for the exhaust (in total, which is the inside area of the fan). If you have too little intake, the fan gets slowed down, if you have to much, cooling will be ineffective.

4 Transparent/3D Printed Enclosure

Improved version based on the transparent enclosure (above) whereby some of the enclosure sides are 3D printed instead of being laser cut. It adds a StarTech FAN6X1TX3 60x60x10mm at top of enclosure which solves the above mentioned heat dissipation issues.



Build Instructions:

  1. Laser cut acrylic sheets as defined in axiombetatransparentplot.top60x60fan.svg (all plates, except the "top" and the back side).
  2. 3D print the 2 STL files.
  3. Assemble.
  4. Affix StarTech FAN6X1TX3 60x60x10mm cooler fan to the top plate and connect to fan connector on the Microzed .
  5. Each of the enclosure'opposite plates are to be held together by one or more Φ 3 mm threaded rods together with corresponding nuts (locknuts can be considered for this application - https://en.wikipedia.org/wiki/Locknut - but have not been tested yet) mounted on the exterior on each side. For the back and the front plate the rods are the same four that hold together the PCBs and the skeleton mount, albeit longer ones will be required (min 7.7 cm). For the left and right plate there the current implementation requires only one Φ 3 mm threaded rod of aprox 15 mm in length. In the current version the holes for the threaded rod in the top and bottom plate require adjustments & are misaligned, but it will be fixed in the next version (however, tests show that the enclosure holds together just fine with just the left-right & front-back rods). No shock/vibration tests have been run on it, so consider this unexplored space.


Download: File:Transparent-3d-print-enclosure.zip

5 AXIOM Beta Compact Enclosure

The AXIOM Beta Compact is an all metal enclosure for the AXIOM Beta and is CNC milled from aluminium and then anodized. Labels/logos are laser engraved.


FINEPIX X100 4 L.JPG The design is inspired by analogue photo cameras "sandwich" design where silver elements on top and bottom sandwich a black mid section.


AXIOM-Beta-CP-w-Lens-on-e1e1e1.jpg Concept Rendering of the AXIOM Beta Compact Enclosure


Cp-asselby03.jpg We manufactured two generations of prototypes in very small quantities and in 2023 had the first small batch manufactured for early adopters.


Latest designs are in this Onshape 3D CAD project.

(Onshape is a CAD design software that's entirely browser based - good for collaboration in an open source project. You can view/inspect without an account but to export/download a free account is required - paid accounts only required for private designs).

5.1 Thermal Expansion of Lens Assembly

According to https://goodcalculators.com/thermal-expansion-calculator/ and an aluminium lens mount assembly with a distance from sensor to bayonet of 19.4mm, the thermal expansion of 25°C temperature difference is 0.01mm, so can be considered negligible.

5.2 E-mount FFD verification

The defined flange focal distance (FFD) between image sensor plane and lens bayonet for e-mount is 18mm. Though glass elements in the optical path affect that distance as they have a higher density as the air the light is envisioned to pass through in that 18mm (https://www.spektrum.de/lexikon/optik/planflaechenabbildung/2588).

AXIOM Beta Compact Enclosure Optical Path (cross section):

CP enclosure optical Path V2.jpg


Distance Notes:

  • Spring ring under bayonet: 0.3mm thickness
  • Sensor CMOS surface to outer front plate surface: Version 1: 6.75mm / Version 2: 4.75mm + 0.244mm (delta from cover glass)
  • every filter holder thickness should be 2mm + own filters delta (the assembly always requires two filter holders in place for the correct FFD)
  • shimming should account for 0.15mm in the FFD

5.3 Cooling and Airflow

At the top of the AXIOM Beta Compact enclosure in the "Cap Top" part and it integrates a 12V 60x60x10mm fan. By using a relatively large fan we can spin it slower meaning more silent operation. The fan pushes hot air out at the top. The air enters the enclosure at the bottom ventilation holes and flows through the electronics. As heat rises this natural motion is supported by the fan.

60x60fan-top-cap.jpg

There is a thin layer of PVC with fine hole grid pattern as filter.

Image sensor cooling is done with a custom two part heat sink attached to the back of the image sensor with a silicon rubber thermal pad and pushed onto the image sensor back with 2 spring screws. The heat sink elements are anodized as according to https://www.gabrian.com/anodized-aluminum-heatsinks-what-you-need-to-know/ this increases the surface emissivity.

5.4 Filter Holders

The default stack contains two optical filter holders:

  • 1x UV/IR cut off filter
  • 1x empty (to provide space for adding a second filter later on)

Each filter holder features two orientation pins to prevent being inserted in a wrong orientation. These orientation pins also act as shim holder.

Each filter holders thickness is 2mm by default plus the FFD delta as a result of the optical filter holders own filter thickness/density. So in reality an optical filter holder will be something like 2.15 or 2.34mm thick depending on the glass element it holds.

The filter holder incorporates a rubber gasket ring with 1.5mm thickness and 58mm outer diameter, 55mm inner diameter corresponding to a ring length of 177.5mm. (eg. https://www.ebay.com/itm/10x-Metric-Nitrile-Rubber-NBR-O-Ring-Seals-Washers-Cross-Section-1-5mm-OD-5-80mm/173895045434) This gasket seals the holder towards the image sensor side.

5.4.1 UV/IR cut off filter

The visible spectrum that humans can see ranges from 380 - 750 nm.

Currently we are shipping Dev Kits with Haida Pro II MC Digital Slim UV / IR 390nm / 750nm filters.

Hoya filters offer a narrower band of 390 nm - 700 nm - will need to be tested how it impacts less red tones.

http://www.optics-online.com/IRC.asp?PN=IRC30-50x50 50x50mm for 39$ for sample (volume pricing likely lower and on request), 1.5mm thickness

UQG Optics offer 40x40x1.1mm UV/IR Cut off filters with 400 - 690nm bandpass

5.5 Thread Inserts

We decided to use thread inserts for all external attachment points (1/4" and 3/8") instead of cutting threads into the aluminum directly. This is a bit more expensive but the threads are stronger, easier to replace in case any of them wear or get damaged over time so its better for repair-ability. We opted for steel helicoils as thread inserts.


5.6 AXIOM Shell

features this cold shoe.

5.7 Extended Plugin Module Cartridge

Plugin Modules can be any length, for this concept a flexible way to enclose the PCB is required. The following concept is a 2 part assembly:

Plugin module cartridge 01.jpg

To make space for the cartridge walls plugin module PCBs that shall fit into this extended cartridge need to be a bit less high (max: 26.575mm).

Plugin module cartridge 02.jpg

Further requirements for the PCB so it will fit inside this cartridge enclosure:

  • component height on bottom side is limited to 3mm
  • component height on top side is limited to 7.5mm

Example of a 60mm long cartridge installed in CP enclosure top slot and HDMI (normal length) Plugin Module installed in bottom slot.:

Plugin module cartridge 03.jpg

6 Legacy

Body Design Options

Cooling

Switchable ND Filters not planned currently