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Mark van den Heuvel | Mark van den Heuvel <br> | ||
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Revision as of 12:22, 26 September 2019
Low Frequency Publication
Materialising the Blackbox
Introduction
In this special issue we will explore the physicality behind slick black boxes as for example found in everyone's pockets today. Be it hardware or software. The goal is to make the interactions, interfaces and connections explicit through hands-on research and play. Informed by the fact all modern day electronics still adhere to the paradigm of modularity, like the earliest computer designs we will collaboratively build one or more devices that explore notions of modularity, complexity/simplicity, interfaces, darkpatterns, input/output while explicitly giving insight into the black box, but this time including a manual.
To encourage affection with the materiality of the blackbox we will create our own. Starting of by constructing the building blocks of a synthesizer, allowing the creation of complex outputs by interfacing/combining relatively simple operations. As a clear framework we will start off by working with sound, your fastest sensor. Compatible with the possibly familiar 'Eurorack' format (as developed by Doepfer) we will be constructing several electronic modules that allow the output of one module to be the input for the next. Expanding upon the original discrete, or analog approach, each of our modules offer a programmable interface, eventually allowing for interfacing beyond the blackbox.
As single modules perform one job and one job well, you will have to anticipate and even require the output of someone elses module in order for yours to work. Coinciding with your research we will create one or several 'outputs' consisting of an interface, electronics and a manual.
Guests
Dennis de Bel Dennis de Bel (1984, NL) is an applied artistic researcher, educator, radio amateur (call sign PD0WNED). In his practice he positions himself as producer, consumer, observer and distributor of critical knowledge focussed on technology. His work has been exhibited at Siggraph Los Angeles, Transmediale Berlin and hosted workshops in various collaborations at, for example, ISEA Hong Kong, Radical Networks New York. He participated in the Relearn summer schools and Libre Graphics Meetings besides being a guest tutor at the Design Academy Eindhoven and the Willem de Kooning Academy Rotterdam University of Applied Science. In 2017 he co-founded Varia, a Rotterdam based space for developing collective approaches towards everyday technology. De Bel holds a MA from the Piet Zwart Institute (NL) and most recently (Jul-Dec 2018) participated in the artist in residency program of the Institute for Provocation in Beijing.
Olli Aarni
Olli Aarni (Oulu, Finland) makes experimental electronic music with vivid timbres and textures, static and slippery harmonies. He has released more than 20 records on four continents with labels like Aguirre, Flau and Lal Lal Lal. He has played in various European countries and Japan at events such as Flow Festival (Helsinki, Finland), Jauna Muzika (Vilnius, Lithuania) and The Gathering of Trans-Medial Publishers (Antwerpen, Belgium).
Aarni holds an MA in Finnish Language. Combining his passion for linguistics and music, he has created a sound poetry piece, consisting of the Finnish sound alphabet, and two sound poems created with this alphabet. He has created music with plants as part of the multimedia artist group Band of Weeds. Currently he is working on a site-specific music piece for electronic instruments and the Finnish traditional instrument kantele.
de Player Nor a white cube (read gallery) or black box (read: theater) but a 'grey dome' where production meets performance meets possibilities..and everything in between http://deplayer.nl
Martin Howse Not sure where to begin, techno-shaman would cut his practice short. Check his 'micro research' here: http://www.1010.co.uk/
Schedule
The program consists of three main sections, building, interfacing and coding and going public. Bring headphones to every class!
Building
Getting your hands dirty.
Week 1 - Sept 17
Today you will become modules of a modular synth! First we need to construct them though:
Construct: Meergranen (Optionally + LFO)
pad: https://pad.xpub.nl/p/lfp1 (Keep build notes, address points of improvements, happy accidents and tips)
git: https://git.xpub.nl/XPUB/special-issue-x
build manual: File:Manual-meergranen.pdf (20MB PDF)
BEFORE YOU POWER YOUR MODULE, LET ME TAKE A LOOK
arduino firmware: Arduino Firmware (ZIP file)
software: Arduino IDE + Driver
PLEASE BRING A MINI USB CABLE (with power + data lines) and Headphones (3.5mm jack)
homework:
-Play with the various Arduino Firmware (ZIP file) found in that zip file. Note some codes might need an external trigger (control voltage, 0-5v) in order to produce sound. Other codes might only produce triggers (no sound), used to sequence/trigger other modules. Make notes on the pad above what you find interesting, what functionality you would like to have, what sounds?
-Record your own sample, using the 'Memphis' example firmware and script below: http://pzwiki.wdka.nl/mediadesign/Category:Lfp#Adding_custom_audio_samples
Week 2 - Sept 23,24,25,28
Workshop with Olli Aarni
Notepad: https://pad.xpub.nl/p/olliworkshop
During the first part of the workshop the participants will learn about different interfaces of making sounds and music. We will explore such questions as: How do restrictions lead to creative solutions? How does technology affect the outcome of the creative process? How does the interface itself relate to its output?
We will listen to different sounds and develop our own concepts and categories for understanding, grouping and creating sounds. The process will combine language and sound in order to create a unique categorisation system, which will be used later as a basis for building a modular sound producing system.
Furthermore there will be a small introduction into modular synthesis and practical logic concerning your modules and demo of various in's and out's
Demo setup
28th September Excursion to Dutch Modular Festival
Please add your name if you are attending:
Dennis de Bel
Mika Motskobili
Mark van den Heuvel
Ioana Tomici
Week 3 - 1 Oct
PSU
Week 4 - 8 Oct
Building prototype frontpanels and 'test' case
Interfacing
Basics of arduino, interfacing with others, desiging interfaces (frontpanels) SOX
Laser cutter instructions (PDF)
Frontpanel source files (vector)
Week 5 - 15 Oct
Workshop with Olli Aarni (14, 15, 16) Arduino Basics
Week 6 - 5 Nov
DIWO - Interfacing with your neighbours
Week 7 - 12 Nov
Develop interactions
- DE PLAYER workshop Thursday 28.11
Publishing
Going public, manual
Week 8 - 19 Nov
Week 9 - 26 Nov
Week 10 - 3 Dec
Presentation at de Player
Resources
Software
Hardware
Modules - Mult
A simple module; just a front panel and jack sockets connected to each other (tip to tip (+), sleeve (gnd) to sleeve). Creating a passive (non-powered/buffered/unsafe) crude kind of mixer!
Notice the two sections of five jacks, distinguishing audio from CV. This is for safety, since our 'Meergranen' output (audio) is not protected from potential control voltages of -12v to 12v.
SO always try to mix audio with audio and CV with CV (if you have spare arduinos you can igonre this message, because modulating audio with CV can be interesting!).
Modules - Arduino Tool 'Meergranen'
Meergranen, front+back, no frontpanel
NOTE: there is a bug in the IDC connection, pin 7 and 8 need to be bridged if you want to power the module through usb (for testing)
NOTE: the optional button is wired incorrectly and is not usable. It needs a jumper from 5v (arduino) pin and a jumper to any of the free digital pins see.
WARNING: the output port is UNPROTECTED agains overcurrent/voltage/reversepolarity. Use it as OUPUT and dont connect it to another output for example.
What can the jack inputs do?
Adding custom audio samples
Download Arduino firmware examples here: Arduino Firmware (ZIP file) Indie the zip file you will find grains-sounds-master.zip, unzip and flash one of the arduino sketches found in the 'patches' folder. Grains-sounds is a basic sample player that allows you to manipulate pitch, start and end of a sample (using the potentiometers or control voltage). To add your own samples, just replace the 'sample.h' file with one of your own. To prepare an audio sample for this firmware:
-install sox (and Audacity ) (mac: install homebrew and then install brew install sox)
-make 3 second (loop) of a sound in Audacity for example
-convert stereo sound to mono
-export as wav file (16bit)
-in Terminal, navigate yo your exported soundfile and convert it to 8bit, 8000hz: (alternatively use the script below to convert your 16bit wav file exported from Audacity directly to sample.h!)
sox your_sound_file.wav -t u8 -c 1 -r 8000 output.wav xxd -i output.wav > sample.h
you end up with a hexadecimal encoded soundfile now in an array.
C code needs to know the length of the array before hand:
at the bottom of sample.h it says the length of the file,
for example 27278.
in sample.h search and replace the first line:
unsigned char out2_wav[] = {
with, note you have to change the sound_lenght into that of your sample:
#define SAMPLE_RATE 8000 const int sound_length=27278; const unsigned char sound_data[] PROGMEM= {
Script
You can use this bash script to automatize the creation of sample.h (instructions below):
#!/bin/sh # Prepares a sample.h file # sed not used, should just werk (TM) everywhere # Usage: ./samplify.sh my_sample.wav # Or you can install samplify.sh in your ~/bin and call it # from anywhere you like # Convert original soundfile and create sample.h # A temp file is needed oftherwise xxd is unable to generate # sample length information? sox "${1}" -t u8 -c 1 -r 8000 /tmp/sample.wav xxd -i /tmp/sample.wav > sample.h rm /tmp/sample.wav # Extract sample length SAMPLE_LEN=$(tail -1 sample.h | cut -d ' ' -f 5 | tr -d ';') # Inject SAMPLE_LEN in new file header NEW_HEADER="#define SAMPLE_RATE 8000 const int sound_length=${SAMPLE_LEN}; const unsigned char sound_data[] PROGMEM= {" # Remove first line of sample.h echo "$(tail -n +2 sample.h)" > sample.h # Prepend new header to sample.h echo "$(echo "${NEW_HEADER}"; cat sample.h)" > sample.h
The latest version will be updated on the trimester's git repos! https://git.xpub.nl/XPUB/special-issue-x/src/branch/master/utils/samplify.sh
How to use the script: Copy paste the text above in a texteditor (raw text, not Textedit) and save as 'samplify.sh'. Open a terminal and make the file executable:
chmod +x samplify.sh
Put your wave file in the same directory as samplify.sh and in terminal run:
./samplify.sh yourfile.wav
This will generate the sample.h file needed for the sample player arduino firmware as in the 'memphis' example. Just replace the sample.h in that folder with your newly generated one. Flash the arduino with the memphis code again and it should now play our own custom sample!
Pro tip: 27278 bytes is about the maximum lenght of sample storage on arduino nano (+ the script that plays the sample). If sound sample is a bit too long/big you can simply speed it up in Audacity, the script allows for pitch bending, so you can make up for the increase in speed. Possiblt there is some head room in the sample rate (8000hz) in the above example. Reducing this will result in smaller file, but lower quality (resolution). Possibly the playback speed will increase as well (since the script anticipates the sample rate of 8000hz, ofcourse this is adjustable by yourself).
Bill of Materials
Label | Part Type | Properties |
---|---|---|
for arduino | Male Headers | 1x16 |
for arduino | Female Headers | 1x16 |
C1 104 | Capacitor | 104, 100nF package cap-pth-small2; variant pth2 |
J1 - A2 | 3.5mm Switch Jack | size 3.5mm; variant 1; part # PJ301M-12 |
J2 - A1 | 3.5mm Switch Jack | size 3.5mm; variant 1; part # PJ301M-12 |
J3TRIG - A3 | 3.5mm Switch Jack | size 3.5mm; variant 1; part # PJ301M-12 |
J4 - A0 | 3.5mm Switch Jack | size 3.5mm; variant 1; part # PJ301M-12 |
J4 OUT | 3.5mm Switch Jack | size 3.5mm; variant 1; part # PJ301M-12 |
JP | Header 5x2 | package 2x5-ra; variant ra |
LDR1 | Photocell (LDR) | resistance@ dark 300 kOhms@ 10 seconds; package THT; resistance@ luminance 16 kOhms@ 10 lux |
LDR2 | Photocell (LDR) | resistance@ dark 300 kOhms@ 10 seconds; package THT; resistance@ luminance 16 kOhms@ 10 lux |
LDR3 | Photocell (LDR) | resistance@ dark 300 kOhms@ 10 seconds; package THT; resistance@ luminance 16 kOhms@ 10 lux |
LDR4 | Photocell (LDR) | resistance@ dark 300 kOhms@ 10 seconds; package THT; resistance@ luminance 16 kOhms@ 10 lux |
LED1 | Red (633nm) LED | package 3 mm [THT]; color Red (633nm); leg yes |
LED2 | Red (633nm) LED | package 3 mm [THT]; color Red (633nm); leg yes |
LED3 | Red (633nm) LED | package 3 mm [THT]; color Red (633nm); leg yes |
LED4 | Red (633nm) LED | package 3 mm [THT]; color Red (633nm); leg yes |
NANO | Arduino Nano (Rev3.0) | type Arduino Nano (3.0) |
P1 = A2 | Rotary Potentiometer (Small) | package THT; size Rotary - 9mm; track Linear; maximum resistance 10kΩ; type Rotary Shaft Potentiometer |
P2 = A1 | Rotary Potentiometer (Small) | package THT; size Rotary - 9mm; track Linear; maximum resistance 10kΩ; type Rotary Shaft Potentiometer |
P3 = A0 | Rotary Potentiometer (Small) | package THT; size Rotary - 9mm; track Linear; maximum resistance 10kΩ; type Rotary Shaft Potentiometer |
R1 | 0Ω Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 0Ω |
R2 | 0Ω Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 0Ω |
R3 | 1kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 1kΩ |
R4 | 1kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 1kΩ |
R5 | 1kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 1kΩ |
R6 | 10kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 10kΩ |
R7 | 1kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 1kΩ |
R8 | 10kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 10kΩ |
R9 | 150Ω Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 150Ω |
S1 | SWITCH-MOMENTARY-2 | package tactile-pth; variant pth |
Shopping List
Amount | Part Type | Properties |
---|---|---|
2 | Male Headers | 1x16 |
2 | Female Headers | 1x16 |
1 | Capacitor | 104, 100nF package cap-pth-small2; variant pth2 |
5 | 3.5mm Switch Jack | size 3.5mm; variant 1; part # PJ301M-12 |
1 | Header 5x2 | package 2x5-ra; variant ra |
4 | Photocell (LDR) | resistance@ dark 300 kOhms@ 10 seconds; package THT; resistance@ luminance 16 kOhms@ 10 lux |
4 | Red (633nm) LED | package 3 mm [THT]; color Red (633nm); leg yes |
1 | Arduino Nano (Rev3.0) | type Arduino Nano (3.0) |
3 | Rotary Potentiometer (Small) | package THT; size Rotary - 9mm; track Linear; maximum resistance 10kΩ; type Rotary Shaft Potentiometer |
2 | 0Ω Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 0Ω |
4 | 1kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 1kΩ |
2 | 10kΩ Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 10kΩ |
1 | 150Ω Resistor | bands 5; package THT; tolerance ±5%; pin spacing 400 mil; resistance 150Ω |
1 | SWITCH-MOMENTARY-2 | package tactile-pth; variant pth |
Modules - Low frequency oscillator
Analog lfo frequency oscillator, delivers waves below the speed of sound. Usefull for triggering other things (beats, filters, etc). Based on quad-opamp, can deliver up to 2x square wave + 2x triangle wave. In this configuration/pcb only 1x square + 1x triangle. Speed of oscillation depening on potentiometer.
Build Instructions
Building this module is a soft introduction into the world of electronics where humans cannot handle, build, or see the components they are using. Introducing: Surface Mount Devices > SDM (or surface mount technology > SMT). In contrast to 'through hole type' components, these smd parts don't need drilling at all, efficient! Not designed to be handled by humans, but for space saving and efficiency, you can still try!
Use the BOM (Bill Of Materials) to see what components you need. This time we introduce IC's, Transistors and IDC connectors. They all have a specific orientation. The white silkscreen on the PCB hints at this, but sometimes its hard to see (LED +, long leg goes into square hole) or drawn incorrectly:
BUG: The white silkscreen of the IDC connector (marked 'JP2') is wrong, Refer to the example how it should be (hint, 180deg turn).
Soldering SMD
-put a little bit of solder on 1 pad of the pcb
-check the orientation of the IC (Integrated Circuit, the SMD component)
-CHECK AGAIN WHERE PIN 1 SHOULD GO!
-place smd ic correctly on the pads, keep in place with finger
-touch the leg that corresponds with the pad containing some solder
-let the solder melt, and remove the soldering iron
-now the ic is fixed in place!
-check the orientation again, now is the time to make corrections (when all pins are soldered its very very hard to remove the IC withouth damaging the board and ic.)
solder the rest of the pins:
-clean your soldering tip (do this for every pin)
-touch the pin+pad with soldering tip, add some solder, remove soldering tip
-repeat.
-the pin spacing is small, dont add too much solder, clean tip after soldering each pin (clean bridges with solder wick).
Modules - Power Supply
Use a usb wall wart adaptor or powerbank (laptop WILL die!)
Credits: https://github.com/TomWhitwell/StupidUSBPower
Modules - ESP8266wifi
Coming soon...
Frontpanels
Temporary place for the front panel vector files: http://dennisdebel.nl/downloads/xpub/frontpanels/ (soon on GIT).
Cables
Flat cables with IDC connectors ('eurorack power cables') (Lint- or Bandkabel in Dutch)
Patch cable (mono TS (Tip-Sleeve)3.5mm Male Jacks)
,
Glossary
Patch Cables - mono 3.5 mm male jack-jack cables used to interconnect eurorack modules.
Control Voltage - or CV, a signal used to control synths. typically within the -15 to +15v range (DC or AC).
Breadboard - or solderless-breadboard is a plastic board with interconnected holes for prototyping electronic circuits using jumper cables instead of (semi) permanent solder.
Soldering tin - combination of low melting point metals and resin flux. Sticks to copper, various metals and itself (not to aluminium, stainless steel, plastic, wood etc.)
PCB - Printed Circuit Board - Fiberglass (FR4) coated with copper. Etching away the copper allows for creating traces for electrical circuits. Professionally made boards are silskreened with soldermask (only exposing the places where solder is allowed and protecting the fragile copper traces + lettering for component placement.
Resistor - Slows down electrons, reducing current and thus voltage (Ohms Law, U=IxR) by converting it to heat. Units in Ohms > 1k = 1 kilo Ohm = 1000 Ohm, 0r = 0 Ohm (can be used to bride traces on a PCB)
LED - Light emitting diode, Has polarity: a positive (anode) and negative (cathode) leg. The longest leg is the positive one, keep this in mind when placing the component!
LDR - Light Dependant Resistor, a variable resitor based on light. The more light the lower the resistance and vice versa. Also called light sensor. Units in Ohms
Potentiometer - Rotary or sliding (like on audio mixers) variable resistor. Resistance is changed by turning the knob. Units in Ohms
Ceramic Capacitor - No polarity. Stores enegry until full and then releases it (like a bucket). Can be used for filtering signals (high frequencies will chose to go over a capacitor, low frequencies rather choose to go through a resistor). Units in Farad (pico, nano)
Electrolytic Capacitor - Has polarity. Stores enegry until full and then releases it (like a bucket). (high frequencies will chose to go over a capacitor, low frequencies rather choose to go through a resistor)Units in Farad (mirco, milli)
IC - Integrated Circuit, a single component housing various circuits. Examples: 555 timer, CMOS logic, Opamps,
IDC Connector - Special 'solderless' connectors for ribbon cable, press fit. Use vice, not hammer, be gentle on the brittle material.
Heatshrink - Tube that shrinks when heat is applied (use: lighter, paintstripper, soldering iron), handy for isolating wires, contacts and blocking external light when using LDRS
SMD/SMT - Surface Mount Device/Surface Mount Technology; components that are not soldered through holes, but directly to the PCB
THT - Through Hole Type: components that have long legs that go ...through holes before soldering
Trigger - a control voltage that gives a quick peak, used to trigger drums for example. Typically a harsh square wave.
Gate - a control voltage that follows a (ADSR) slope over time, useful for filters, pitch, notes. Typically a complex wave.
Transistor - Using a plumbing analogy: this is a tap: turn it open with a little effort (current) , allows many electrons to flow. Usable as switch (on off) and thus also to create oscillations (rapid on-off switches).
Ribbon cable - Also called flat cable, multiple parallel conducting wires. (Dutch: lint- or bandkabel)
Vactrols - Vactrols turn voltage into resistance. The 'hotter' the signal, the lower the resistance. Consist of one LED and one LDR, applying voltage to the LED creates light, influencing the resistance of the LDR.
Wire Wrap - before through hole and smd, there was wire wrap, wrap the components legs around a header pin for a airtight solderless, reverseable connection.
Inputs Outputs
Outputs
https://www.facebook.com/HARRYPL0TTER/ Harry Plotter (aka dennis verschoor akak mono-poly, maintainer of worm synth lab), using modular synths to control xy- pen plotters
Shops
Up until a few years ago it was not strange to bike a few minutes to a nearby electronics shop to buy a headphone jack input socket or battery holder. In 2015 the last electronics (component) shop of Rotterdam closed (DIL). Many preceded (2014 Van Der Bend) and many followed, leaving us with just a handful of physical shops to get (unwanted) advice and goods at a premium price without waiting for yellow envelopes from China. Besides not being able to physically examine the goods for sale (will it fit?) more important issues arise. Beyond supporting your local entrepreneur, the decline of DIY shops like the above signify a certain level of consumerism, painfully acknowledging planned obsolesce over DIY repair culture.
Local Shops
Rotterdams Electronica Depot a sporadic electronics shop near you...inquire dennis for more info
https://www.radiotwenthe.nl/ The Hague
https://www.hf-electronics.nl/ Haarlem
https://www.baco-army-goods.nl/ Ijmuiden
http://www.radiopiet.nl/ Arnhem
https://www.tinytronics.nl/ Eindhoven, semi public shop, sells Chinese knock-offs at a premium..
https://www.hobbyelectronica.nl/ Online only, quick delivery, expensive-ish
https://www.kiwi-electronics.nl/ Online only, quick delivery, expensive, recently burned down, sells adafruit stuff etc (expensive-ish)
European Shops
https://www.tme.eu/nl/en/ Member of the Shenzhen (China) Chamber of Commerce. That says everything, please forget box pushers like conrad, farnell, digikey who will rip you off
China
(Almost) EVERYTHING mentioned above comes from Shenzhen, China...so aliexpress.com (or taobao....good luck!). It even pays of to fly to HK, get a SZ port visa and buy what you need in case you want bulk items.
Pads
Reading/Watching/Listening List
http://www.gieskes.nl/ databending circuitboard designs, owns his own pick and place machine, music on tape, vinyl, concrete and what not.
https://www.ciat-lonbarde.net/ taking modular synths in some direction
http://www.gjp.info/ originally radio amateur drummer, applying knowledge of electronics to make incredible noise
http://www.electronicpeasant.com/ discovered by accident, but most 'personal homepages' of early synth enthusiast will publish in this manner
https://www.mengqimusic.com/ friend from Beijing offers some nice interfaces
https://www.errorinstruments.com/ your local eurorack pusher, love bbq in Shenzhen, has infinite energy to make some seriously interesting devices
https://www.muffwiggler.com/forum/index.php the forum where all the action takes (took?) place. Terrible name, terrible place, all the goods you need, though scattered over 90+ forum pages, enjoy!
https://www.facebook.com/HARRYPL0TTER/ Harry Plotter (aka dennis verschoor akak mono-poly, maintainer of worm synth lab), using modular synths to control xy- pen plotters
Pages in category "LFP"
The following 22 pages are in this category, out of 22 total.
E
Media in category "LFP"
The following 170 files are in this category, out of 170 total.
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- LFP 18.jpg 5,184 × 3,456; 447 KB
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- LFP all 04.jpg 3,059 × 3,030; 956 KB
- LFP bird 12.jpg 3,411 × 5,116; 782 KB
- LFP bird 13.jpg 3,411 × 5,116; 725 KB
- LFP deplayer 02.jpg 1,000 × 667; 310 KB
- LFP deplayer 03 small.jpg 1,000 × 667; 485 KB
- LFP deplayer 06.jpg 1,000 × 667; 295 KB
- LFP deplayer 09.jpg 667 × 1,000; 345 KB
- LFP deplayer 11.jpg 1,000 × 667; 353 KB
- LFP deplayer 12.jpg 886 × 1,329; 969 KB
- LFP deplayer 21.jpg 1,000 × 667; 261 KB
- LFP deplayer 29.jpg 1,000 × 667; 378 KB
- LFP deplayer 30.jpg 1,000 × 1,500; 404 KB
- LFP detail 01.jpg 5,184 × 3,456; 851 KB
- LFP detail 02.jpg 5,184 × 3,456; 652 KB
- LFP detail 03.jpg 5,184 × 3,456; 973 KB
- LFP detail 27 small.jpg 1,800 × 1,200; 640 KB
- LFP detail 28.jpg 5,101 × 3,401; 307 KB
- LFP detail 29.jpg 5,162 × 3,441; 320 KB
- LFP detail 34.jpg 5,184 × 3,456; 904 KB
- LFP detail 35.jpg 5,184 × 3,456; 1,001 KB
- LFPoster1.jpg 1,836 × 3,264; 1,009 KB
- LFPoster2.jpg 3,264 × 1,836; 898 KB
- LFPoster3.jpg 3,264 × 1,836; 846 KB
- LFPoster4.jpg 1,836 × 3,264; 802 KB
- LFPoster5.jpg 1,836 × 3,264; 954 KB
- LFPoster6.jpg 3,264 × 1,836; 756 KB
- Lfpsesh2-code.png 2,110 × 688; 172 KB
- Love-tape.jpg 720 × 540; 695 KB
- Mark - Back.png 1,789 × 1,743; 1.78 MB
- Mark - Front.png 1,789 × 1,753; 1.33 MB
- Max DMF1.jpg 1,836 × 3,264; 1.62 MB
- Max DMF2.jpg 3,264 × 1,836; 2.52 MB
- Max DMF3.jpg 1,836 × 3,264; 2.49 MB
- Max DMF4.jpg 1,836 × 3,264; 2.59 MB
- Max DMF5.gif 480 × 640; 4.01 MB
- Max DMF6.jpg 3,264 × 1,836; 2.29 MB
- Max DMF7.gif 480 × 640; 2.45 MB
- Max DMF8.jpg 3,264 × 1,836; 2.09 MB
- Maxbreadboard1.jpg 2,268 × 1,276; 601 KB
- Maxconceptsketch1.jpg 1,134 × 2,016; 414 KB
- Maxconceptsketch2.jpg 1,134 × 2,016; 396 KB
- Meergranen s.gif 453 × 958; 351 KB
- Meergranen-db.jpg 4,000 × 3,000; 4.07 MB
- Meergranen-samples.png 1,548 × 878; 527 KB
- Meergranen1.jpg 3,264 × 2,448; 1.95 MB
- Meergranen2.jpg 2,448 × 3,264; 2.55 MB
- Meergranen3.jpg 2,448 × 3,264; 2.15 MB
- Mf1.jpeg 480 × 640; 116 KB
- Mf2.jpeg 480 × 640; 134 KB
- Mf3.jpeg 480 × 640; 111 KB
- Modular synth interface.jpg 2,268 × 1,515; 2.37 MB
- Motheremin.jpg 720 × 540; 836 KB
- Multiplexer1.jpg 2,268 × 2,520; 1,010 KB
- Multiplexer2.jpg 2,268 × 1,276; 801 KB
- Musicboxmodule.jpg 2,268 × 1,276; 2.03 MB
- MVDH speech-to-midi-counting.mp3 ; 351 KB
- Mystify understand.jpg 3,264 × 1,836; 2.73 MB
- Olli workshop.jpg 1,280 × 960; 112 KB
- OSC.gif 600 × 338; 1.49 MB
- PCBSchematic.png 1,951 × 923; 89 KB
- Pencil.jpg 720 × 540; 698 KB
- PosterSmallFinal.jpg 1,742 × 2,498; 585 KB
- Publication.gif 200 × 112; 419 KB
- Publication01.jpg 1,000 × 667; 286 KB
- Raspberry-p-3-bird.jpg 726 × 498; 249 KB
- S-Water.mp3 ; 843 KB
- S-Wood.mp3 ; 1.1 MB
- Screen Shot 2019-12-02 at 22.20.11.png 170 × 390; 14 KB
- Sensor plug.jpg 1,390 × 2,472; 675 KB
- Sensor synth.jpg 1,836 × 3,264; 856 KB
- Sensor.png 265 × 893; 10 KB
- SensorProto.jpg 1,836 × 3,264; 836 KB
- SensorTV.jpg 1,836 × 3,264; 669 KB
- Serial plotter.mp4 ; 2.47 MB
- Sess3 2.gif 480 × 640; 1.39 MB
- Sess3 5.jpg 1,836 × 3,264; 1.51 MB
- Sine.mp3 ; 48 KB
- Sine2.mp3 ; 119 KB
- Speech-instrument.jpg 1,417 × 823; 592 KB
- Stapletrigger2.jpg 3,264 × 1,836; 1.56 MB
- Stapletrigger3.jpg 1,836 × 3,264; 1.7 MB
- Stapletrigger4.jpg 3,264 × 1,836; 1.15 MB
- Subtractive-synthesis.png 830 × 299; 21 KB
- Super-in-low.jpg 720 × 540; 727 KB
- Svarog3.jpg 720 × 540; 698 KB
- Take time.jpg 960 × 1,280; 266 KB
- Teensy1.jpg 1,827 × 1,218; 877 KB
- Teensy2.jpg 1,224 × 700; 506 KB
- Testkeyboard1.jpg 2,268 × 1,276; 500 KB
- Tisa take time.mp3 ; 6 MB
- WorkshopOlli1.jpg 2,448 × 3,264; 2.17 MB
- WorkshopOlli2.jpg 3,264 × 2,448; 2.27 MB
- WorkshopOlli4.jpg 3,264 × 2,448; 2.19 MB
- WorkshopOlli5.jpg 3,264 × 2,448; 2.24 MB
- WorkshopOlli7.jpg 1,366 × 1,024; 325 KB
- XPUB - DE PLAYER - INPUT-OUTPUT176-12 december 2019.jpg 1,800 × 1,200; 559 KB
- XPUB - DE PLAYER - INPUT-OUTPUT292-12 december 2019.jpg 1,800 × 1,200; 563 KB
- XPUB - DE PLAYER - INPUT-OUTPUT300-12 december 2019.jpg 1,800 × 1,200; 614 KB
- XPUB - DE PLAYER - INPUT-OUTPUT43-12 december 2019.jpg 1,800 × 1,200; 610 KB
- XPUB workshop.jpg 4,128 × 2,322; 2.75 MB