Difference between revisions of "Sphere lab technical info"
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− | [[Sphere lab]] | + | [[Sphere lab|back to Sphere lab]] |
+ | ==Introduction== | ||
+ | The Sphere setup is a sound boot with about 126 speakers arranged in a sphere. In the middle of the sphere is a chair where a person (the subject) can sit, so that his/her head is exactly in the centre of the sphere. The subject can be presented with stimuli in the form of sounds or led flashes. The headmovements of the subject can be tracked. The subject can also respond to stimuli by pressing a button. The experiments are controlled by a computer and electronics from outside the boot. | ||
+ | |||
+ | History: | ||
+ | *2014: build of the original system | ||
+ | *2018: all original Visaton speakers where replaced by Minx12 speakers | ||
+ | *2018: Remmel head tracking system replaced by Femto | ||
+ | |||
==Sound booth== | ==Sound booth== | ||
− | + | [[File:image005.png|thumb|Sound Booth]] | |
+ | *Dimensions: LxWxH = 420x300x300cm | ||
+ | ===Description=== | ||
+ | The sound booth is an acoustically isolated room with sound absorbing materials on all walls and the floor to reduce reverberation. A 2.75m diameter sphere build of metal tubes holds about 112 small passive speakers and 14 large active speakers. The small speakers also contain 5mm two color LEDs. In the centre of the sphere there is a chair for a subject. The chair is placed in a way that the head of the subject is right in centre of the sphere. The positions of the speakers and LEDs are specified in [[Coordinate systems|Spherical coordinates]]. | ||
+ | Large coils are embedded in the walls of the sound booth. The coils make a cube of about 3mx3mx3m. These coils are used for head movement detection. | ||
+ | A metal cabinet contains PLC equipment for controlling the LEDs as well as a patch panel for the small speakers. The large speakers are connected with XLR cables to a large reel. | ||
+ | An infrared camera is installed in the booth. The experimenter has a monitor from which he/she can see the inside of the booth. The camera looks down on the back of the subject. | ||
+ | |||
+ | ===Acoustics=== | ||
+ | The walls and floor of the booth as well as the PLC cabinet and the leg rest are covered with sound dampening materials. The speaker frame sphere is of 1 cm thick steel tubes. | ||
+ | *Walls: egg box type soundproofing foam | ||
+ | *Floor: anti-fatigue rubber floor mat with holes | ||
+ | see [[Acoustic Materials]] | ||
+ | |||
+ | ===Coordinates=== | ||
+ | The orientation of the coordinates is determined by the position of the head of the subject looking to the center speaker. The raw acquisition data of the head coil results in tuples of voltages (Frontal, Vertical, Horizontal) which correspond to (X, Y, Z). | ||
+ | |||
+ | * Frontal (F) : Front is X+, Back is X- | ||
+ | * Vertical (V) : Top is Y+, Bottom is Y- | ||
+ | * Horizontal (H): Right is Z+, Left is Z- | ||
+ | |||
+ | For Double Polar coordinates see [[Coordinate systems]] | ||
+ | |||
==Computer== | ==Computer== | ||
− | < | + | [[File:image009.png|thumb|zBus Monitor]] |
+ | A windows computer with MATLAB, RPvdsEx and zBUSmon. The computer has an optical interface card (PO5e) for communication with the Tucker Davis equipment via the Optibit optical bus (FO5) at the back of the rack. The working of the optical bus can be monitored by the program zBUSmon program from TDT. This program has also some control functions for the optical bus. It shows all the connected zBus chassis and the TDT devices that are installed in each chassis. It also shows the version number of the installed firmware on the devices. | ||
+ | ==Software== | ||
+ | The software consist of several parts: | ||
+ | *GenExp: Matlab software for generating experiment files. | ||
+ | *SpherePrime: Matlab software that runs the experiments. | ||
+ | *RPvdsX software for the RP2.1 soundprocessors | ||
+ | *RPvdsX software for the RA16 medusa base station. | ||
+ | |||
+ | ===GenExp=== | ||
+ | The software that generates a experiment file is called 'genexp_xxxxx'. In the '''\biofysica\experiment\exp''' directory there are five examples: | ||
+ | *genexp_defaultcal.m | ||
+ | *genexp_defaultloc.m | ||
+ | *genexp_fartloc.m | ||
+ | *genexp_glausndloc.m | ||
+ | *genexp_student.m | ||
+ | |||
+ | ===NewSpherePrime=== | ||
+ | The current program (since 2024) is 'newSpherePrime' developed by Ruurd Lof. It can be found in the '''\biofysica\experiment\newSpherePrime''' directory. This program has a GUI build in the app designer of Matlab. The program is mostly written in the Object Oriented Programming (OOP) paradigm. The core of the program is a state machine. Due to its structure the GUI stays always responsive. | ||
+ | |||
+ | The 'newSpherePrime' program uses a vector based method for locating the stimuli, which is more precise than the 'interpolant' method. | ||
+ | |||
+ | ===Older SpherePrime=== | ||
+ | The software mostly used up to 2023 is called 'SpherePrime'. It is written in the procedural programming paradigm. Nearly all functions have a parameter 'handles' as input parameter and as output parameter. 'handles' is a struct that contains nearly all information that is moved around in the program. Every function has the ability to change 'handles'. This way it acts as a global data structure. | ||
+ | |||
+ | The 'SpherePrime' program uses the 'interpolant' method for locating the stimuli. This can sometimes lead to different speaker choices for locations in the backward hemisphere. | ||
+ | |||
+ | <pre> | ||
+ | N.B. SpherePrime uses the outdated GUIDE environment for the GUI. The GUIDE environment will be removed in a future releases of MATLAB. | ||
+ | </pre> | ||
+ | |||
+ | ===RPvdsEx software=== | ||
+ | In the '''\biofysica\experiment''' directory there are several versions of .rcx programs. | ||
+ | For the RP2.1 soundprocessors | ||
+ | *sphere_RP2_GWN.rcx | ||
+ | *sphere_RP2_WAV.rcx | ||
+ | |||
+ | For the RA16 | ||
+ | *sphere_RA16.rcx | ||
+ | *sphere_RA16_equaltowaitevent.rcx | ||
+ | *sphere_RA16_testled.rcx | ||
+ | |||
+ | When a RZ6 is used instead of a RA16 there is: | ||
+ | *sphere_RZ6.rcx | ||
==Electronics rack== | ==Electronics rack== | ||
[[File:image010.png|thumb|upper half of electronics rack]] | [[File:image010.png|thumb|upper half of electronics rack]] | ||
− | |||
− | |||
The upper half of the electronics rack contains 10 TDT Zbus devices chassis, each containing two TDT series 3 devices. The lower half contains the Field coil amplifier and the Femto LockinAmplifier as part of the head tracking electronics. | The upper half of the electronics rack contains 10 TDT Zbus devices chassis, each containing two TDT series 3 devices. The lower half contains the Field coil amplifier and the Femto LockinAmplifier as part of the head tracking electronics. | ||
− | |||
− | |||
− | |||
The following table shows all the zBus chassis from top to bottom, with the installed devices. | The following table shows all the zBus chassis from top to bottom, with the installed devices. | ||
− | {| class="wikitable" | + | {| class="wikitable mw-collapsible mw-collapsed" style="text-align: left;margin:0px;" |
!Chassis | !Chassis | ||
!Front left | !Front left | ||
Line 68: | Line 136: | ||
|- | |- | ||
|Zbus | |Zbus | ||
+ | |RA8GA2 multi DAC | ||
|RA16ba base station | |RA16ba base station | ||
− | |||
|F05 optibit bus #4 | |F05 optibit bus #4 | ||
|} | |} | ||
Line 83: | Line 151: | ||
*Rack main power switch | *Rack main power switch | ||
*Patch panel for XLR output to Tannoy speakers | *Patch panel for XLR output to Tannoy speakers | ||
+ | |||
+ | ===Optical Interface=== | ||
+ | [[File:image007.png|thumb|Optical interface card]] | ||
+ | Four of the Zbus chassis in the rack have an optical interface (F05) at the back. These optical interfaces are connected in a loop with the P05e interface at the back of the computer. | ||
+ | PO5e optibit bus | ||
+ | F05 optibit bus (4x) | ||
+ | Transfer rate: read 1.5 Mbit/s, write 1.0 Mbit/s | ||
+ | N.B. The optical bus is not 100% stable. Once in a while it hangs up the program. Issue #196 on GitLab. | ||
==Sound system== | ==Sound system== | ||
Line 88: | Line 164: | ||
[[File:image018.png|thumb|Speaker locations on the sphere]] | [[File:image018.png|thumb|Speaker locations on the sphere]] | ||
The sound system consists of two programmable DSP’s (TDT RP2.1’s) with each two DAC’s. An RP2.1 generates a sound signal that travels via a programmable attenuator (TDT PA5), a stereo amplifier (TDT SA1) and a multiplexer (TDT PM2R) to a patch panel inside the PLC cabinet in the boot and from there to a speaker. | The sound system consists of two programmable DSP’s (TDT RP2.1’s) with each two DAC’s. An RP2.1 generates a sound signal that travels via a programmable attenuator (TDT PA5), a stereo amplifier (TDT SA1) and a multiplexer (TDT PM2R) to a patch panel inside the PLC cabinet in the boot and from there to a speaker. | ||
− | The multiplexing system consists of two sets of four multiplexers (TDT PM2relay). Each multiplexer has 16 channels. Only one channels per multiplexer can be opened at a time. The total number of channels is 128. Each RP2.1 controls four multiplexers. Since each RP2.1 has 2 DAC outputs, each output is connected to two multiplexers. It is therefore possible to play up to 4 different sounds at once over different speaker. | + | The multiplexing system consists of two sets of four multiplexers (TDT PM2relay). Each multiplexer has 16 channels. Only one channels per multiplexer can be opened at a time. The total number of channels is 128, but the numbering of the channels (and speaker IDs) is 0-127. Each RP2.1 controls four multiplexers. Since each RP2.1 has 2 DAC outputs, each output is connected to two multiplexers. It is therefore possible to play up to 4 different sounds at once over different speaker. |
Parts | Parts | ||
*TDT RP2.1 (2x) | *TDT RP2.1 (2x) | ||
Line 100: | Line 176: | ||
*Speakers (116x) | *Speakers (116x) | ||
− | ==== | + | ====Minx Min12 speaker system==== |
[[File:image016.png|thumb|Speaker (and LED) connection scheme]] | [[File:image016.png|thumb|Speaker (and LED) connection scheme]] | ||
− | The | + | On the sphere frame Cambridge Audio Minx Min12 speakers are used. |
+ | |||
+ | Speaker specifications: | ||
+ | |||
+ | *Sensitivity: 86 dB SPL (@2.83 Vrms input) | ||
+ | *Frequency response: 150 Hz-20 kHz | ||
+ | *Impedance: 8 Ohms | ||
+ | *H x W x D: 78 x 78 x 85 mm | ||
+ | *Weight: 0.43 kg | ||
+ | |||
+ | The speakers are connected via 5 lead wires with a 5 pole binder connector at each end. Two leads are used for the speakers, three leads are used for the LED’s. | ||
+ | |||
+ | *RP2.1_1 Left : 26 speakers #000..#025 | ||
+ | *RP2.1_1 Right: 28 speakers #032..#057 | ||
+ | *RP2.1_2 Left : 32 speakers #064..#095 | ||
+ | *RP2.1_2 Right: 26 speakers #096..#123 | ||
+ | |||
+ | A total of 112 speakers. | ||
+ | |||
+ | The channels numbers (or speakers IDs) that are not used are: [26 27 28 29 30 31 58 59 60 61 62 63 124 125 126 127] | ||
+ | |||
+ | Azimuths and elevations were measured by Sebastian Ausili in June 2015 and are tabulated in 'Sphere Measurement.xlsx'. The newSpherePrime program uses the same data in the file 'sphere_sound_locations.xlsx'. | ||
====Tannoy speaker system==== | ====Tannoy speaker system==== | ||
[[File:image020.png|thumb|XLR patch panel connection scheme]] | [[File:image020.png|thumb|XLR patch panel connection scheme]] | ||
+ | There are 14 Tannoy Reveal 402 speakers in the horizontal plane, positioned on small plateaus. These are active speakers with their own amplifier. The speakers are used when lower frequencies (50Hz-150Hz) are important. Due to hiss problems, the original block transformers have been replaced by toroidal transformers. | ||
+ | The Tannoy speakers are connected with XLR cables to a special patch panel at the bottom of the electronics rack, and inside the boot to a panel on a XLR cable reel. Since the output of the TDT soundsystem does not have a balanced output, the shield of the XLR cables are connected to the minus leads. | ||
+ | The Tannoy speakers can be connected to a multiplexer using a special flat cable that connects to the back of the XLR patch panel. | ||
+ | |||
+ | A flat cable with DSub25 connector from the back of the XLR patch panel you can connect the Tannoy speakers to a multiplexer. In the following table you see the mapping from the mux channels to the XLR channels. The collumn "Pin MUX" shows the corresponding DSub25 pin numbers. | ||
+ | |||
+ | {| class="wikitable mw-collapsible mw-collapsed" style="text-align: left;margin:0px;" | ||
+ | |- | ||
+ | !style="width:8em;" |Channel | ||
+ | !style="width:8em;" |Pin MUX | ||
+ | !style="width:8em;" |XLR | ||
+ | |- | ||
+ | |X | ||
+ | |1 | ||
+ | |GND | ||
+ | |- | ||
+ | |A0 | ||
+ | |15 | ||
+ | |1 | ||
+ | |- | ||
+ | |A1 | ||
+ | |3 | ||
+ | |2 | ||
+ | |- | ||
+ | |A2 | ||
+ | |16 | ||
+ | |3 | ||
+ | |- | ||
+ | |A3 | ||
+ | |4 | ||
+ | |4 | ||
+ | |- | ||
+ | |A4 | ||
+ | |17 | ||
+ | |5 | ||
+ | |- | ||
+ | |A5 | ||
+ | |5 | ||
+ | |6 | ||
+ | |- | ||
+ | |A6 | ||
+ | |18 | ||
+ | |7 | ||
+ | |- | ||
+ | |A7 | ||
+ | |6 | ||
+ | |8 | ||
+ | |- | ||
+ | |A8 | ||
+ | |19 | ||
+ | |9 | ||
+ | |- | ||
+ | |A9 | ||
+ | |7 | ||
+ | |10 | ||
+ | |- | ||
+ | |A10 | ||
+ | |20 | ||
+ | |11 | ||
+ | |- | ||
+ | |A11 | ||
+ | |8 | ||
+ | |12 | ||
+ | |- | ||
+ | |A12 | ||
+ | |21 | ||
+ | |13 | ||
+ | |- | ||
+ | |A13 | ||
+ | |9 | ||
+ | |14 | ||
+ | |- | ||
+ | |X | ||
+ | |X | ||
+ | |15 | ||
+ | |- | ||
+ | |X | ||
+ | |X | ||
+ | |16 | ||
+ | |} | ||
+ | |||
+ | The wiring of the XLR sockets on the patch panel is as follows: | ||
+ | *XLR-1: Shield = zwart | ||
+ | *XLR-2: Hot = rood | ||
+ | *XLR-3: Cold = connected to XLR-1 | ||
+ | |||
+ | Speaker specifications: | ||
+ | |||
+ | *Active speaker: Bi-Amp (25W + 25W) | ||
+ | *4" Woofer; 3/4" Tweeter | ||
+ | *Frequency range: 56 Hz tot 43 kHz | ||
+ | *Cross over freq.: 2.8 kHz | ||
+ | *Distortion: <0.9% | ||
+ | *Maximum sound pressure 101 dB | ||
+ | *Bass reflex system | ||
+ | *H x W x D: 240 x 147 x 212 mm | ||
+ | *Weight: 5.2 kg | ||
==LED system== | ==LED system== | ||
Line 114: | Line 308: | ||
====Parts==== | ====Parts==== | ||
*Trigger from Medusa base station | *Trigger from Medusa base station | ||
− | *PLC | + | *[[PLC LED controller specifications|PLC LED controller]] |
− | + | *Break-out panel with 5 pole Binder connectors (128x) | |
− | |||
*Binder cables (120x) | *Binder cables (120x) | ||
*LED mounting frames (120x) | *LED mounting frames (120x) | ||
− | *Red/Green LED’s (120x) | + | *[[LED specifications|Bivar 5BC-3-CA-F]] Red/Green LED’s (120x) |
− | *Trigger | + | *Trigger converter (5V → 24V) for input trigger |
+ | *Trigger converter (24V → 5V) for trigger echo | ||
+ | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
====Specifications Red/Green LEDs==== | ====Specifications Red/Green LEDs==== | ||
− | * | + | See [[LED specifications]] |
− | * | + | |
− | * | + | ==Trigger/Timing system== |
− | * | + | [[File:Trigger system Sphere 2.png|thumb|Scheme of trigger system]] |
− | + | [[File:image032.png|thumb|LED stimulus in standard modus (X=0)]] | |
− | * | + | [[File:image034.png|thumb|LED stimulus in short pulse modus (X=1)]] |
− | + | ===Description=== | |
− | + | The task of the trigger/timing system is to distribute trigger signals and record the timing of the triggers. In the standard situation when an experiment starts, the subject has to push a button to start a trial. The button push is registered by an arduino trigger bridge that outputs a trigger to the Medusa Base Station. The Medusa sends triggers to the RP2.1’s, the LED PLC and to the Event Recorder. The Event Recorder timestamps all the triggers and can be read out via ethernet. The arduino trigger bridge has a green LED that indicates that a trigger signal is generated and it has a test button that generates a trigger signal when pushed. | |
+ | |||
+ | ===Parts=== | ||
+ | *[[Active handheld push button (5V output)|Active Pushbutton]] (with 9V battery for 5V output) | ||
+ | *Arduino [[Trigger distributor]] (5V inputs (3x), 5V outputs (6x), 3V outputs (2x), testbutton) | ||
+ | *PP16 patch panel for analogue inputs | ||
+ | *PP16 patch panel for digital outputs | ||
+ | *Medusa Base Station (TDT RA16) | ||
+ | *[[8 channel digital event recorder|Digital event recorder (LSLDER05)]] | ||
+ | |||
+ | ===Specification=== | ||
+ | The LED PLC in the LED controller cabinet can be programmed by Matlab. The PLC stores a list of LED configurations. One configuration tells the PLC which LEDs should be on or off. In the standard mode (X = 0) the current configuration is changed to the next configuration by an electrical trigger signal from the Medusa Base Station. A stimulus of a single LED consists of two configurations, one with only that LED on, followed by one with all the LEDs off. The timing and the length of the stimulus are controlled by trigger signals sent from the Medusa Base Station. | ||
+ | The PLC cycle of 1.35 ms is the limiting factor for the shortness of a LED stimulus. In practice the pulselength can be as short as two or three PLC cycles (2.7 ms or 4.0 ms) in the standard modus (X=0). The number of cycles the stimulus lasts can vary by one cycle. | ||
+ | In practice there is always 1.35 ms jitter on top of a 1.35 ms delay for the start (and end) of a LED stimulus (see figure). When more precise knowledge is needed over the timing or length of the stimulus, a timing signal (trigger echo) sent from the PLC can be recorded. The trigger echo signal is lined up with the rising or falling flanks of the LED and can measure the real stimulus with an accuracy down to 40 µs. | ||
+ | |||
+ | When using short stimuli the X parameter can be used to control the exact number of cycles. When X = n the length of the LED stimulus is exactly n PLC cycles. | ||
+ | |||
+ | ==Head Tracking System== | ||
+ | [[File:SphereLab_Lockin_settings.JPEG|300px|thumb|right|Lock-in amplifier settings]] | ||
+ | *See [[EM Field Head Tracking System specifications]] | ||
+ | |||
+ | ===Lock-in amplifiers settings=== | ||
+ | |||
+ | |||
+ | {| class="wikitable" | ||
+ | ! Setting | ||
+ | ! Frontal (Red) | ||
+ | ! Vertical (Blue) | ||
+ | ! Horizontal (Yellow) | ||
+ | |- | ||
+ | | Frequency | ||
+ | | 50 kHz | ||
+ | | 60 kHz | ||
+ | | 70 kHz | ||
+ | |- | ||
+ | | Time constant | ||
+ | | B | ||
+ | | B | ||
+ | | B | ||
+ | |- | ||
+ | | Sensitivity | ||
+ | | 4 | ||
+ | | 5 | ||
+ | | 5 | ||
+ | |- | ||
+ | | Phase Course | ||
+ | | 0 | ||
+ | | F | ||
+ | | 4 | ||
+ | |- | ||
+ | | Phase Fine | ||
+ | | 4 | ||
+ | | D | ||
+ | | 6 | ||
+ | |- | ||
+ | | Dynamic Reserve | ||
+ | | L | ||
+ | | L | ||
+ | | L | ||
+ | |- | ||
+ | | Mode | ||
+ | | 1f | ||
+ | | 1f | ||
+ | | 1f | ||
+ | |- | ||
+ | | PLL | ||
+ | | S | ||
+ | | S | ||
+ | | S | ||
+ | |- | ||
+ | | Reference Threshold | ||
+ | | 0V | ||
+ | | 0V | ||
+ | | 0V | ||
+ | |} |
Latest revision as of 09:05, 24 September 2024
Introduction
The Sphere setup is a sound boot with about 126 speakers arranged in a sphere. In the middle of the sphere is a chair where a person (the subject) can sit, so that his/her head is exactly in the centre of the sphere. The subject can be presented with stimuli in the form of sounds or led flashes. The headmovements of the subject can be tracked. The subject can also respond to stimuli by pressing a button. The experiments are controlled by a computer and electronics from outside the boot.
History:
- 2014: build of the original system
- 2018: all original Visaton speakers where replaced by Minx12 speakers
- 2018: Remmel head tracking system replaced by Femto
Sound booth
- Dimensions: LxWxH = 420x300x300cm
Description
The sound booth is an acoustically isolated room with sound absorbing materials on all walls and the floor to reduce reverberation. A 2.75m diameter sphere build of metal tubes holds about 112 small passive speakers and 14 large active speakers. The small speakers also contain 5mm two color LEDs. In the centre of the sphere there is a chair for a subject. The chair is placed in a way that the head of the subject is right in centre of the sphere. The positions of the speakers and LEDs are specified in Spherical coordinates. Large coils are embedded in the walls of the sound booth. The coils make a cube of about 3mx3mx3m. These coils are used for head movement detection. A metal cabinet contains PLC equipment for controlling the LEDs as well as a patch panel for the small speakers. The large speakers are connected with XLR cables to a large reel. An infrared camera is installed in the booth. The experimenter has a monitor from which he/she can see the inside of the booth. The camera looks down on the back of the subject.
Acoustics
The walls and floor of the booth as well as the PLC cabinet and the leg rest are covered with sound dampening materials. The speaker frame sphere is of 1 cm thick steel tubes.
- Walls: egg box type soundproofing foam
- Floor: anti-fatigue rubber floor mat with holes
Coordinates
The orientation of the coordinates is determined by the position of the head of the subject looking to the center speaker. The raw acquisition data of the head coil results in tuples of voltages (Frontal, Vertical, Horizontal) which correspond to (X, Y, Z).
- Frontal (F) : Front is X+, Back is X-
- Vertical (V) : Top is Y+, Bottom is Y-
- Horizontal (H): Right is Z+, Left is Z-
For Double Polar coordinates see Coordinate systems
Computer
A windows computer with MATLAB, RPvdsEx and zBUSmon. The computer has an optical interface card (PO5e) for communication with the Tucker Davis equipment via the Optibit optical bus (FO5) at the back of the rack. The working of the optical bus can be monitored by the program zBUSmon program from TDT. This program has also some control functions for the optical bus. It shows all the connected zBus chassis and the TDT devices that are installed in each chassis. It also shows the version number of the installed firmware on the devices.
Software
The software consist of several parts:
- GenExp: Matlab software for generating experiment files.
- SpherePrime: Matlab software that runs the experiments.
- RPvdsX software for the RP2.1 soundprocessors
- RPvdsX software for the RA16 medusa base station.
GenExp
The software that generates a experiment file is called 'genexp_xxxxx'. In the \biofysica\experiment\exp directory there are five examples:
- genexp_defaultcal.m
- genexp_defaultloc.m
- genexp_fartloc.m
- genexp_glausndloc.m
- genexp_student.m
NewSpherePrime
The current program (since 2024) is 'newSpherePrime' developed by Ruurd Lof. It can be found in the \biofysica\experiment\newSpherePrime directory. This program has a GUI build in the app designer of Matlab. The program is mostly written in the Object Oriented Programming (OOP) paradigm. The core of the program is a state machine. Due to its structure the GUI stays always responsive.
The 'newSpherePrime' program uses a vector based method for locating the stimuli, which is more precise than the 'interpolant' method.
Older SpherePrime
The software mostly used up to 2023 is called 'SpherePrime'. It is written in the procedural programming paradigm. Nearly all functions have a parameter 'handles' as input parameter and as output parameter. 'handles' is a struct that contains nearly all information that is moved around in the program. Every function has the ability to change 'handles'. This way it acts as a global data structure.
The 'SpherePrime' program uses the 'interpolant' method for locating the stimuli. This can sometimes lead to different speaker choices for locations in the backward hemisphere.
N.B. SpherePrime uses the outdated GUIDE environment for the GUI. The GUIDE environment will be removed in a future releases of MATLAB.
RPvdsEx software
In the \biofysica\experiment directory there are several versions of .rcx programs. For the RP2.1 soundprocessors
- sphere_RP2_GWN.rcx
- sphere_RP2_WAV.rcx
For the RA16
- sphere_RA16.rcx
- sphere_RA16_equaltowaitevent.rcx
- sphere_RA16_testled.rcx
When a RZ6 is used instead of a RA16 there is:
- sphere_RZ6.rcx
Electronics rack
The upper half of the electronics rack contains 10 TDT Zbus devices chassis, each containing two TDT series 3 devices. The lower half contains the Field coil amplifier and the Femto LockinAmplifier as part of the head tracking electronics.
The following table shows all the zBus chassis from top to bottom, with the installed devices.
Chassis | Front left | Front right | Back |
---|---|---|---|
Zbus | MS2 Monitor speaker | <empty> | |
Zbus | PA5 Attenuator | PA5 Attenuator | F05 optibit bus #1 |
Zbus | PA5 Attenuator | PA5 Attenuator | F05 optibit bus #2 |
Zbus | SA1 Speaker amplifier | SA1 Speaker amplifier | |
Zbus | RP2.1 Sound processor | RP2.1 Sound processor | F05 optibit bus #3 |
Zbus | PM2R Multiplexer | PM2R Multiplexer | |
Zbus | PM2R Multiplexer | PM2R Multiplexer | |
Zbus | PM2R Multiplexer | PM2R Multiplexer | |
Zbus | PM2R Multiplexer | PM2R Multiplexer | |
Zbus | RA8GA2 multi DAC | RA16ba base station | F05 optibit bus #4 |
The next list shows all other electronics in the lower half of the rack from top to bottom.
- PP16 Patch panel for Medusa Base Station (2x)
- Digital event recorder
- Junction box panel (connects to junction box in sound boot)
- Trigger distribution panel
- Femto Lockin amplifiers
- Tektronics Oscilloscope
- Field coil amplifier
- Rack main power switch
- Patch panel for XLR output to Tannoy speakers
Optical Interface
Four of the Zbus chassis in the rack have an optical interface (F05) at the back. These optical interfaces are connected in a loop with the P05e interface at the back of the computer. PO5e optibit bus F05 optibit bus (4x) Transfer rate: read 1.5 Mbit/s, write 1.0 Mbit/s N.B. The optical bus is not 100% stable. Once in a while it hangs up the program. Issue #196 on GitLab.
Sound system
The sound system consists of two programmable DSP’s (TDT RP2.1’s) with each two DAC’s. An RP2.1 generates a sound signal that travels via a programmable attenuator (TDT PA5), a stereo amplifier (TDT SA1) and a multiplexer (TDT PM2R) to a patch panel inside the PLC cabinet in the boot and from there to a speaker. The multiplexing system consists of two sets of four multiplexers (TDT PM2relay). Each multiplexer has 16 channels. Only one channels per multiplexer can be opened at a time. The total number of channels is 128, but the numbering of the channels (and speaker IDs) is 0-127. Each RP2.1 controls four multiplexers. Since each RP2.1 has 2 DAC outputs, each output is connected to two multiplexers. It is therefore possible to play up to 4 different sounds at once over different speaker. Parts
- TDT RP2.1 (2x)
- TDT PA5 (4x)
- TDT SA1 (2x)
- TDT PM2relay Multiplexers (8x)
- Flat cables from RP2.1 to PM2relays (2x)
- Dsub25 cables from PM2relays to PLC cabinet in the boot (8x)
- Patch panel inside the PLC cabinet
- Speakers (116x)
Minx Min12 speaker system
On the sphere frame Cambridge Audio Minx Min12 speakers are used.
Speaker specifications:
- Sensitivity: 86 dB SPL (@2.83 Vrms input)
- Frequency response: 150 Hz-20 kHz
- Impedance: 8 Ohms
- H x W x D: 78 x 78 x 85 mm
- Weight: 0.43 kg
The speakers are connected via 5 lead wires with a 5 pole binder connector at each end. Two leads are used for the speakers, three leads are used for the LED’s.
- RP2.1_1 Left : 26 speakers #000..#025
- RP2.1_1 Right: 28 speakers #032..#057
- RP2.1_2 Left : 32 speakers #064..#095
- RP2.1_2 Right: 26 speakers #096..#123
A total of 112 speakers.
The channels numbers (or speakers IDs) that are not used are: [26 27 28 29 30 31 58 59 60 61 62 63 124 125 126 127]
Azimuths and elevations were measured by Sebastian Ausili in June 2015 and are tabulated in 'Sphere Measurement.xlsx'. The newSpherePrime program uses the same data in the file 'sphere_sound_locations.xlsx'.
Tannoy speaker system
There are 14 Tannoy Reveal 402 speakers in the horizontal plane, positioned on small plateaus. These are active speakers with their own amplifier. The speakers are used when lower frequencies (50Hz-150Hz) are important. Due to hiss problems, the original block transformers have been replaced by toroidal transformers. The Tannoy speakers are connected with XLR cables to a special patch panel at the bottom of the electronics rack, and inside the boot to a panel on a XLR cable reel. Since the output of the TDT soundsystem does not have a balanced output, the shield of the XLR cables are connected to the minus leads. The Tannoy speakers can be connected to a multiplexer using a special flat cable that connects to the back of the XLR patch panel.
A flat cable with DSub25 connector from the back of the XLR patch panel you can connect the Tannoy speakers to a multiplexer. In the following table you see the mapping from the mux channels to the XLR channels. The collumn "Pin MUX" shows the corresponding DSub25 pin numbers.
Channel | Pin MUX | XLR |
---|---|---|
X | 1 | GND |
A0 | 15 | 1 |
A1 | 3 | 2 |
A2 | 16 | 3 |
A3 | 4 | 4 |
A4 | 17 | 5 |
A5 | 5 | 6 |
A6 | 18 | 7 |
A7 | 6 | 8 |
A8 | 19 | 9 |
A9 | 7 | 10 |
A10 | 20 | 11 |
A11 | 8 | 12 |
A12 | 21 | 13 |
A13 | 9 | 14 |
X | X | 15 |
X | X | 16 |
The wiring of the XLR sockets on the patch panel is as follows:
- XLR-1: Shield = zwart
- XLR-2: Hot = rood
- XLR-3: Cold = connected to XLR-1
Speaker specifications:
- Active speaker: Bi-Amp (25W + 25W)
- 4" Woofer; 3/4" Tweeter
- Frequency range: 56 Hz tot 43 kHz
- Cross over freq.: 2.8 kHz
- Distortion: <0.9%
- Maximum sound pressure 101 dB
- Bass reflex system
- H x W x D: 240 x 147 x 212 mm
- Weight: 5.2 kg
LED system
The LED system consists of a cabinet inside the sound boot with a Panasonic FP2 series PLC system (programmable logic controller). The PLC can independently switch 256 channels. The channels connect to a two color LEDs (red and green) that are mounted on the speaker. The PLC cabinet has two test buttons that can light all LEDs at once. The PLC system consists of a PLC with several IO units and is can be programmed by via a special USB cable.
Parts
- Trigger from Medusa base station
- PLC LED controller
- Break-out panel with 5 pole Binder connectors (128x)
- Binder cables (120x)
- LED mounting frames (120x)
- Bivar 5BC-3-CA-F Red/Green LED’s (120x)
- Trigger converter (5V → 24V) for input trigger
- Trigger converter (24V → 5V) for trigger echo
Specifications Red/Green LEDs
Trigger/Timing system
Description
The task of the trigger/timing system is to distribute trigger signals and record the timing of the triggers. In the standard situation when an experiment starts, the subject has to push a button to start a trial. The button push is registered by an arduino trigger bridge that outputs a trigger to the Medusa Base Station. The Medusa sends triggers to the RP2.1’s, the LED PLC and to the Event Recorder. The Event Recorder timestamps all the triggers and can be read out via ethernet. The arduino trigger bridge has a green LED that indicates that a trigger signal is generated and it has a test button that generates a trigger signal when pushed.
Parts
- Active Pushbutton (with 9V battery for 5V output)
- Arduino Trigger distributor (5V inputs (3x), 5V outputs (6x), 3V outputs (2x), testbutton)
- PP16 patch panel for analogue inputs
- PP16 patch panel for digital outputs
- Medusa Base Station (TDT RA16)
- Digital event recorder (LSLDER05)
Specification
The LED PLC in the LED controller cabinet can be programmed by Matlab. The PLC stores a list of LED configurations. One configuration tells the PLC which LEDs should be on or off. In the standard mode (X = 0) the current configuration is changed to the next configuration by an electrical trigger signal from the Medusa Base Station. A stimulus of a single LED consists of two configurations, one with only that LED on, followed by one with all the LEDs off. The timing and the length of the stimulus are controlled by trigger signals sent from the Medusa Base Station. The PLC cycle of 1.35 ms is the limiting factor for the shortness of a LED stimulus. In practice the pulselength can be as short as two or three PLC cycles (2.7 ms or 4.0 ms) in the standard modus (X=0). The number of cycles the stimulus lasts can vary by one cycle. In practice there is always 1.35 ms jitter on top of a 1.35 ms delay for the start (and end) of a LED stimulus (see figure). When more precise knowledge is needed over the timing or length of the stimulus, a timing signal (trigger echo) sent from the PLC can be recorded. The trigger echo signal is lined up with the rising or falling flanks of the LED and can measure the real stimulus with an accuracy down to 40 µs.
When using short stimuli the X parameter can be used to control the exact number of cycles. When X = n the length of the LED stimulus is exactly n PLC cycles.
Head Tracking System
Lock-in amplifiers settings
Setting | Frontal (Red) | Vertical (Blue) | Horizontal (Yellow) |
---|---|---|---|
Frequency | 50 kHz | 60 kHz | 70 kHz |
Time constant | B | B | B |
Sensitivity | 4 | 5 | 5 |
Phase Course | 0 | F | 4 |
Phase Fine | 4 | D | 6 |
Dynamic Reserve | L | L | L |
Mode | 1f | 1f | 1f |
PLL | S | S | S |
Reference Threshold | 0V | 0V | 0V |