Tag: Improvements

Making the world a better place, one piece at a time

Photography & Images, Recumbent Bicycling, Software

Copying Action Camera Video Files: Now With Arrays

Using Bash arrays is an exercise in masochism, but I got to recycle most of the oddities from the previous script, so it wasn’t a dead loss.

The cameras use individually unique / screwy / different filesystem layouts, so the script must have individual code to both copy the file and decapitalize the file extensions. This prevents using a single tidy function, although laying out the code in case statements keyed by the camera name helps identify what’s going on.

My previous approach identified the MicroSD cards by their UUIDs, which worked perfectly right up until the camera reformats the card while recovering from a filesystem crash and installs a randomly generated UUID. Because there’s no practical way to modify an existing UUID on a VFAT drive, I’m switching to the volume label as needed:

#-- action cameras and USB video storage
UUID=B40C6DD40C6D9262	/mnt/video	ntfs	user,noauto,uid=ed	0	0
UUID=B257-AE02		/mnt/Fly6	vfat	user,noauto,uid=ed	0	0
#UUID=0000-0001		/mnt/M20	vfat	user,noauto,uid=ed	0	0
UUID=3339-3338		/mnt/M20	vfat	user,noauto,uid=ed	0	0
LABEL=AS30V		/mnt/AS30V	exfat	user,noauto,uid=ed	0	0
LABEL=C100-0001		/mnt/C100_1	vfat	user,noauto,uid=ed	0	0
LABEL=C100-0002		/mnt/C100_2	vfat	user,noauto,uid=ed	0	0
UUID=0050-0001		/mnt/M50	vfat	user,noauto,uid=ed	0	0

In particular, note the two UUIDs for the M20 camera: there’s a crash and reformat in between those two lines. The two C100 cameras started out with labels because the M20 taught me the error of my ways.

The script simply iterates through a list array of the cameras and tries to mount the corresponding MicroSD card for each one: the mount points are cleverly chosen to match the camera names in the array. Should the mount succeeds, an asynchronous rsync then slurps the files onto the bulk video drive.

With all the rsync operations running, the script waits for all of them to complete before continuing. I don’t see much point in trying to identify which rsync just finished and fix up its files while the others continue to run, so the script simply stalls in a loop until everything is finished.

All in all, the script scratches my itch and, if naught else, can serve as a Bad Example™ of how to get the job done.

A picture to keep WordPress from reminding me that readers respond positively to illustrated posts:

A pleasant day for a ride - 2023-06-01
A pleasant day for a ride – 2023-06-01

Ride on!

The Bash script as a GitHub Gist:

#!/bin/bash
# This uses too many bashisms for dash
source /etc/os-release
echo 'Running on' $PRETTY_NAME
if [[ "$PRETTY_NAME" == *Manjaro* ]] ; then
ren='perl-rename'
dm='sudo dmesg'
elif [[ "$PRETTY_NAME" == *Ubuntu* ]] ; then
ren='rename'
dm='dmesg'
else
echo 'New distro to me:' $PRETTY_NAME
echo ' ... which rename command is valid?'
exit
fi
echo Check for good SD card spin-up
$dm | tail -50
echo ... Ctrl-C to bail out and fix / Enter to proceed
read junk
thisdate=$(date --rfc-3339=date)
echo Date: $thisdate
# MicroSD / readers / USB drive defined in fstab
# ... with UUID or PARTID as appropriate
echo Mounting bulk video drive
sudo mount /mnt/video
if [ $? -ne 0 ]; then
echo '** Cannot mount video storage drive'
exit
fi
# Show starting space available
df -h /mnt/video
# list the cameras
declare -a cams=( AS30V Fly6 M20 M50 C100_1 C100_2 )
declare -A targets=( \
[AS30V]=/mnt/video/AS30V/$thisdate \
[Fly6]=/mnt/video/Fly6/DCIM \
[M20]=/mnt/video/M20/$thisdate \
[M50]=/mnt/video/M50/$thisdate \
[C100_1]=/mnt/video/C100_1/$thisdate \
[C100_2]=/mnt/video/C100_2/$thisdate \
)
declare -A PIDs
declare -A Copied
echo Iterating through cameras: ${cams[*]}
Running=0
for cam in ${cams[*]} ; do
printf "\nProcessing: $cam\n"
mpt="/mnt/$cam"
target=${targets[$cam]}
sudo mount $mpt
if [ $? -eq 0 ]; then
echo " Start $cam transfer from $mpt"
echo " Make target directory: $target"
mkdir $target
case $cam in
( AS30V )
rsync -ahu --progress --exclude "*THM" $mpt/MP_ROOT/100ANV01/ $target &
;;
( Fly6 )
rsync -ahu --progress $mpt /mnt/video &
;;
( M20 )
n=$( ls $mpt/DCIM/Photo/* 2> /dev/null | wc -l )
if [ $n -gt 0 ] ; then
echo " copy M20 photos first"
rsync -ahu --progress $mpt/DCIM/Photo/ $target
fi
echo " cmd: rsync -ahu --progress $mpt/DCIM/Movie/ $target"
rsync -ahu --progress $mpt/DCIM/Movie/ $target &
;;
( M50 )
n=$( ls $mpt/DCIM/PHOTO/* 2> /dev/null | wc -l )
if [ $n -gt 0 ] ; then
echo " copy M50 photos first"
rsync -ahu --progress $mpt/DCIM/PHOTO/ $target
fi
rsync -ahu --progress $mpt/DCIM/MOVIE/ $target &
;;
( C100_1 | C100_2 )
n=$( ls $mpt/DCIM/Photo/* 2> /dev/null | wc -l )
if [ $n -gt 0 ] ; then
echo " copy $cam photos first"
rsync -ahu --progress $mpt/DCIM/Photo/ $target
fi
rsync -ahu --progress $mpt/DCIM/Movie/ $target &
;;
( * )
printf "\n**** Did not find $cam in list!\n"
;;
esac
PIDs[$cam]=$!
echo " PID for $cam: " "${PIDs[$cam]}"
Copied[$cam]=1
(( Running++ ))
else
echo " skipping $cam"
Copied[$cam]=0
fi
done
printf "\n----- Waiting for all rsync terminations\n"
echo PIDs: "${PIDs[*]}"
if [ $Running -eq 0 ] ; then
echo No rsyncs started, force error
rcsum=9999
else
rcsum=0
while [ $Running -gt 0 ] ; do
echo " waiting: $Running"
wait -n -p PID
rc=$?
rcsum=$(( rcsum+$rc ))
echo RC for $PID: $rc
(( Running-- ))
done
echo All rsyncs finished
fi
if [ $rcsum -eq 0 ] ; then
echo '----- Final cleanups'
for cam in ${cams[*]} ; do
if [ "${Copied[$cam]}" -eq 1 ] ; then
echo Cleanup for: $cam
mpt=/mnt/$cam
target=${targets[$cam]}
echo Target dir: $target
case $cam in
( Fly6 )
find $target -name \*AVI -print0 | xargs -0 $ren -v -f 's/AVI/avi/'
rm -rf $mpt/DCIM/*
;;
( AS30V )
find $target -name \*MP4 -print0 | xargs -0 $ren -v -f 's/MP4/mp4/'
rm $mpt/MP_ROOT/100ANV01/*
;;
( M50 )
find $target -name \*MP4 -print0 | xargs -0 $ren -v -f 's/MP4/mp4/'
rm $mpt/DCIM/MOVIE/*
n=$( ls $mpt/DCIM/PHOTO/* 2> /dev/null | wc -l )
if [ $n -gt 0 ] ; then
echo placeholder $cam
rm $mpt/DCIM/PHOTO/*
fi
;;
( * )
find $target -name \*MP4 -print0 | xargs -0 $ren -v -f 's/MP4/mp4/'
find $target -name \*JPG -print0 | xargs -0 $ren -v -f 's/JPG/jpg/'
rm $mpt/DCIM/Movie/*
n=$( ls $mpt/DCIM/Photo/* 2> /dev/null | wc -l )
if [ $n -gt 0 ] ; then
echo placeholder $cam
rm $mpt/DCIM/Photo/*
fi
;;
esac
sudo umount $mpt
else
echo No cleanup for: $cam
fi
done
echo '----- Space remaining on video drive'
df -h /mnt/video
sudo umount /mnt/video
date
echo Done!
else
echo Whoopsie! Total RC: $rcsum
fi
view raw savevideo-array.sh hosted with ❤ by GitHub
Photography & Images, Recumbent Bicycling, Software

Tour Easy: Another SJCAM C100+ Mount

Eight years of progress in the action camera world gets you from a rather expensive Cycliq Fly6:

Tour Easy - Fly6 image
Tour Easy – Fly6 image

To an SJCAM C100+ camera costing the better part of fifty bucks on closeout:

Tour Easy - C100 image
Tour Easy – C100 image

The camera is mounted on the side of the seat frame on Mary’s Tour Easy:

Tour Easy C100 mount - side rail
Tour Easy C100 mount – side rail

The slightly tilted picture comes from the frame rail’s incline. My C100+ camera mounts on the horizontal part of the rail:

Tour Easy C100 mount - rear rail
Tour Easy C100 mount – rear rail

As expected, the internal battery does not last for our usual hour-long rides, so the cameras now operate in “car mode”: recording starts when we plug in the USB battery pack and stops shortly after unplugging.

I started with the waterproof case on my bike:

Tour Easy - SJCAM C100 mount - installed
Tour Easy – SJCAM C100 mount – installed

Which (obviously) does not allow for an external battery, so they’re now in the “frame” mount. The hatch covering the MicroSD card and USB Micro-B connector (and a Reset button!) is on the bottom of the camera, but (fortunately) the whole affair mounts up-side-down and the settings include an image flip mode.

Putting the camera on the side required changing the mount angle from -20° to +35°:

SJCAM C100 Mount - 35 degree solid model
SJCAM C100 Mount – 35 degree solid model

The ergonomics / user interface of this whole setup is terrible:

  • The camera’s flexible hatch is recessed inside the frame far enough that it cannot be opened without using a small & sharp screwdriver
  • The USB jack is slightly off-center, so lining the plug up with the camera body doesn’t align it with the jack
  • The MicroSD card is in a push-to-release socket, but its raised ridge faces the hatch flap and cannot be reached by a fingernail. I added a small tab that helps, but it’s difficult to grasp.

Extracting the video files from the camera through the app is an exercise in frustration. Having already figured out how to do this for the other cameras in the fleet, it’s easier to fumble with the MicroSD card.

I devoutly hope we never really need any of the videos.

Electronics Workbench, Photography & Images, Science

HW Bucked Lithium AA Cells

The trail camera uses two parallel banks of four series AA cells to get enough oomph for its IR floodlight. I’m not convinced using bucked lithium AA cells in that configuration is a Good Idea, but it’s worth investigating.

These are labeled HW, rather than Fuvaly, because it seems one cannot swim twice in the same river:

HW bucked Li AA cells
HW bucked Li AA cells

In any event, they come close to their claimed 2.8 W·hr capacity:

HW bucked Li AA - 2023-05
HW bucked Li AA – 2023-05

The lower pair of traces (red & black) are single cells at 2.7-ish W·hr, the blue trace is a pair at 5.4 W·hr, and the green trace is a quartet at 9.8 W·hr. Surprisingly close, given some previous results in this field.

Recharging the cells after those tests shows they all take 3 hours ± a few minutes to soak up 730 mA·hr ± a few mA·hr, so they’re decently matched.

Measuring the terminal voltage with a 10 mA load after that charge lets me match a pair of quartets to 1 mV, which is obviously absurd:

HW bucked Li cells - initial charge 2023-05-05
HW bucked Li cells – initial charge 2023-05-05

The numbers in the upper left corner show the initial charge of four cells at a time required the same time within a minute and the same energy within 4%.

Sticking them in the trail camera must await using up the current set of alkaline AA cells.

Bonus: a lithium fire in a trail camera won’t burn down the house.

After all, pictures like this are definitely worth the hassle:

Young Buck in velvet - 2023-05-03
Young Buck in velvet – 2023-05-03

Looks like a pair of WiFi antennas …

Machine Shop, Recumbent Bicycling, Software

Bafang vs. Tour Easy: Chain Guide

After adding the Bafang motor to my Tour Easy, the chain has fallen off the chainring a few times, prompting the gap filler between the motor and the chainring spider. That this has never happened to Mary’s essentially identical Tour Easy suggests I have a different shift technique, but adding a chain catcher seemed easier than re-learning shifting:

Chain Catcher - top view
Chain Catcher – top view

It’s more properly called a “chain guide” and is basically a shifter cage minus the mechanism:

Chain Catcher - side view
Chain Catcher – side view

Because the Tour Easy frame has a 25 mm tube where the guide’s clamp expects a minimum 31.8 mm tube, a 3D printed adapter fills the gap:

Chain Catcher adapter ring - solid model
Chain Catcher adapter ring – solid model

The hole is off-center because it seemed like a good idea, although it’s not strictly necessary. The flange helps align the pieces while tightening the clamp screw.

The guide cage clears the chain on all sides while up on the work stand, but there’s nothing like getting out on the road to find out why something doesn’t work as you expect.

The OpenSCAD source code as a GitHub Gist:

// Chain catcher adapter ring
// Ed Nisley - KE4ZNU - 2023-05
/* [Hidden] */
ThreadThick = 0.25;
ThreadWidth = 0.40;
HoleWindage = 0.2;
Protrusion = 0.1; // make holes end cleanly
function IntegerMultiple(Size,Unit) = Unit * ceil(Size / Unit);
ID = 0;
OD = 1;
LENGTH = 2;
inch = 25.4;
//----------------------
// Dimensions
TubeOD = 26.0; // frame tube with silicone tape
Clamp = [35.0,39.0,12.0]; // Chain catcher clamp ring
Flange = [Clamp[ID],Clamp[OD],3*ThreadThick];
Kerf = 1.0;
Offset = (Clamp[ID] - TubeOD)/2 - 3*ThreadWidth;
NumSides = 2*3*4;
//-----------------------
$fn=NumSides;
difference() {
union() {
cylinder(d=Flange[OD],h=Flange[LENGTH]);
cylinder(d=Clamp[ID],h=Clamp[LENGTH]+Flange[LENGTH]);
}
cube([2*Flange[OD],Kerf,3*Clamp[LENGTH]],center=true);
translate([0,Offset,0])
cylinder(d=TubeOD,h=3*Clamp[LENGTH],center=true);
}
view raw Chain Catcher adapter ring.scad hosted with ❤ by GitHub
Machine Shop, Recumbent Bicycling, Software

Bafang Motor: Chain Gap Filler

When the chain falls off the top of the chainring toward the motor, the part remaining engaged with the chainring will inevitably drag the rest into the gap between the motor and the chainring spider, whereupon it will jam firmly in place and be almost impossible to extract. Preventing this means filling the gap, which required several iterations:

Bafang motor gap filler - prototypes
Bafang motor gap filler – prototypes

The Bafang motor has a cover held in place by seven M3 flat-head screws, shown here below a test filler using pan head screws:

Bafang motor gap filler - installed
Bafang motor gap filler – installed

Contrary to what you might think, the five screws that obviously sit on five points of a hexagon do not in fact sit 60° apart. How you find this out is by making the obvious layout, including the two screws bracketing the pinion gear in the lower right, then applying windage:

Bafang motor housing gap filler - hole adjustments
Bafang motor housing gap filler – hole adjustments

That’s one of the paper templates seen above, with laser-cut holes 60° apart and ugly holes punched at the actual screw locations. Then you scan and overlay that image with the LightBurn layout and twiddle the hole locations to make the answer come out right:

Bafang motor housing gap filler - hole adjustments - LB overlay
Bafang motor housing gap filler – hole adjustments – LB overlay

With that in hand, I cut a 1 mm acrylic shape to measure the clearance between the motor + filler and the chainring spider, with pan-head screws replacing the original flat-head screws:

Bafang motor gap filler - top view
Bafang motor gap filler – top view

That’s a single piece of 2.5 mm acrylic I used after discovering a pair of the 1 mm acrylic shapes fit with space to spare: hooray for rapid prototyping.

A test chain drop suggested it might suffice:

Bafang motor gap filler - test
Bafang motor gap filler – test

If I were so inclined, 3 mm acrylic with countersunk holes and slightly longer flat-head screws would probably work, but I’ll use this until it fails to prevent a chain snag.

The careful observer will have noted the stress crack extending radially inward from the upper-right screw, which I am carefully avoiding doing anything about, pending the aforementioned failure.

The LightBurn layout as a GitHub Gist:

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view raw Bafang motor housing gap filler.svg hosted with ❤ by GitHub
Machine Shop, Recumbent Bicycling

Tour Easy Running Light: Heatsink Machining

Having acquired some thick-wall (1 inch OD, ¾ inch ID) aluminum tube, making the LED heatsink and lens holder for a running light generates a lot less scrap. A new doodle gives the dimensions in a rather Picasso-ish layout:

Running Light - dimension doodles
Running Light – dimension doodles

The back end of the tube gets turned down to 23 mm OD and cleaned up to 19 mm ID, then scored to give the epoxy something to grip:

Front Running Light - Heatsink shell scoring
Front Running Light – Heatsink shell scoring

The front end gets bored to 22.5 mm for the lens holder and has its OD cleaned up to 25 mm:

Front Running Light - finished shell
Front Running Light – finished shell

Clean up the end of a ¾ inch rod to 19 mm OD, knurl it a little to increase the OD ever so slightly and improve its griptivity, slice off a bit more than 10 mm, butter it up with JB Weld epoxy, and shove it into the shell with its front end aligned and its back end sticking out:

Front Running Light - epoxied plug in shell - rear
Front Running Light – epoxied plug in shell – rear

Face off the back end and the front end looks fine as assembled:

Front Running Light - epoxied plug in shell - front
Front Running Light – epoxied plug in shell – front

Grab it in the Sherline mill’s three jaw chuck to:

  • Drill & tap the M3 central hole for the stud holding the circuit plate to the back end
  • Drill 1.6 mm blind holes for the circuit plate pins
  • Drill 2 mm through holes for the LED wires, 60° apart

Which looks like this from the front:

Front Running Light - drilled heatsink - front
Front Running Light – drilled heatsink – front

And like this with the circuit plate screwed & glued to the rear:

Front Running Light - circuit plate mounted
Front Running Light – circuit plate mounted

Clean up the OD of some ¾ inch PVC pipe to 25 mm, bore it out to 23 mm.

While the Sherline is set up, drill a pair of 2 mm holes in the lens holder for the wires, aligned so they’ll match the heatsink holes.

Because we live in the future, laser-cut the rear cap from some edge-lit acrylic with a black inner disk:

Front Running Light - PVC tube - end cap
Front Running Light – PVC tube – end cap

Cutting that cap with the notch included is now trivially easy, compared to the previous machining.

Now for some circuitry …

Electronics Workbench, Home Ec

Kitchen Scale: Button Shield

While I was thinking about something else, I added a back shield to our kitchen scale:

SmartHeart 19-106 Scale - button shield
SmartHeart 19-106 Scale – button shield

A pogo pin connected to the circuit common contacts the copper foil when the bottom cover is screwed down:

SmartHeart 19-106 Scale - shield pogo pin - detal
SmartHeart 19-106 Scale – shield pogo pin – detal

The shield prevents the buttons from responding to fingers on the bottom of the scale, so it no longer wakes up when I extract it from the under-cabinet shelf, and concentrates its attention on the buttons, so it no longer seems quite so willing to lock up due to mysterious influences.

With an absurd amount of rebuilding, this scale is becoming not a complete waste of free money.

The batteries soaked up 240 mA·hr of charge, which means the scale drew about 10 mA/day over the last three weeks. Given that the scale’s original 2032 lithium cells have a total capacity around 220 ma·hr for currents in the microamp range, expecting them to supply a current around 10 mA is was absurd.