Difference between revisions of "Auditory Perception Lab technical info"

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*A RZ6 multi I/O processor that records the acquired data.
 
*A RZ6 multi I/O processor that records the acquired data.
 
*Software that converts the recorded data to head orientations using calibration data.
 
*Software that converts the recorded data to head orientations using calibration data.
 +
 +
The convention for the directions:
 +
*channel 1; 45 kHz; Frontal    ;color = red  ; Front = + Back = -
 +
*channel 2; 55 kHz; Vertical  ;color = blue  ; Right = + Left = -
 +
*channel 3; 65 kHz; Horizontal ;color = yellow; Up    = + Down = -

Revision as of 14:31, 15 November 2023

back to Auditory Perception Lab

Introduction

The Auditory Perception setup is a sound boot with 43 speakers arranged in a quarter 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 center of the sphere. The subject can be presented with stimuli in the form of sounds or led flashes. The head movements 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.

Booth

Sound Booth

%todo

  • Dimensions: LxWxH = 250x230x280cm

Description

The sound booth is an acoustically isolated room with sound absorbing materials on all walls and the floor to reduce reverberation. A 2.4 m diameter quarter sphere build of a metal structure holds 43 small passive speakers. The speakers also contain two color LED's. In the center of the booth there is a chair for a subject. The chair is placed in a way that the head of the subject is right in center of the sphere. Large coils are embedded in the walls of the sound booth. The coils make a box of about 2.5 m x 2.3 m x 2.8 m. These coils are used for head movement detection.

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 Booth is acoustically isolated from its environment. The walls and corners are covered by acoustic panels. A double steel door isolates the booth from the operating room.

  • Walls: Cinema Round Acoustic Panels
  • Corners: Super Bass 90 Acoustic Panels.
  • Floor: anti-fatigue rubber floor mat with holes

see Acoustic Materials

Computer

File:Xxxxxxx.png
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:

  • Matlab software for generating experiment files.
    • Sphere Minor
    • BIOX Prime (under construction)
  • Matlab software that runs the experiments.
  • BIOX (RPvdsX) software for the RZ6 soundprocessor.

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

Sphere Minor

The software mostly used is called 'SphereMinor'. It is a reworked copy of the 'SpherePrime' program of the Sphere Setup. It can be found in the \biofysica\experiment\sphereMinor directory. It has a graphical user interface (GUI) and is, except for the GUI, written in the procedural programming paradigm. Several 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.

Biox Prime

A program 'Biox Prime' is under construction. 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 programming of the RZ6 is based on the BIOX toolbox.

RPvdsX software

The BIOX sofware can be found in the \biofysica\experiment\biox_rz6 directory.

Electronics rack

electronics rack

From top to bottom:

  • Rack main power switches
  • Computer
  • Quad channel amplifier
  • Digital event recorder
  • RZ6 Multi I/O Processor
  • PP RZ6 Digital I/O (Patch panel)
  • Left: PP Amp (Patch panel) ; Right: Multiplexer
  • Left: <none> ;Right: Multiplexer
  • Left: PP Audion (Patch panel; Right: Multiplexer
  • 8 channel ADC acquisition device
  • Oscilloscope
  • Femto oscilator/Lock-in amplifier module
  • Field coil generator (amplifier)

Sound system

File:Xxxxxxx.png
Connection schematics of the sound system
File:Xxxxxxx.png
Speaker locations on the sphere

The sound system consists of a programmable sound processor (RZ6) with each two DAC’s. The RZ6 generates a sound signal that travels via a multiplexer (TDT PM2R) to a patch panel inside the the booth and from there to a speaker. The multiplexing system consists of two TDT PM2relay multiplexers. Each multiplexer has 16 channels. Only one channels per multiplexer can be opened at a time. The total number of channels is 32. The RZ6 controls the multiplexers.

Parts

  • RZ6
  • TDT PM2relay Multiplexers (2x)
  • Flat cables from RZ6 to PM2relays.
  • Dsub25 cables from PM2relays to patch panels in the booth (2x)
  • Patch panel inside the booth
  • Speakers (30x)

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 2 lead wires for the sound and 3 lead wires with mini stereo jacks for the LED's.

Azimuths and elevations were measured by %todo and are tabulated in %todo.

LED system

File:Xxxxxxx.png
LED wiring scheme

%todo

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 RZ6
  • Custom LED controllers (2x)
  • LED mounting frames (32x)
  • Red/Green LED’s (32x)

Specifications Red/Green LEDs

  • Bivar 5BC-3-CA-F (Common Anode)
  • Red 625nm (FWHM = 25 nm)
  • Green 568 nm (FWHM = 30 nm)
  • Nominal current 20 mA
  • Voltage drop 2.1V
  • 45 degree viewing angle
  • Series resistor 1kOhm
  • Actual current 10 mA @100% PWM

Trigger/Timing system

File:Xxxxxxxxx.png
Scheme of trigger system

Parts

%todo

Specification

%todo

Head Tracking System

The Head Tracking System is used for recording head movements of the subject during a trial. The system consists of the following parts:

Schematic of the Sphere Head Tracking System
  • Three oscillators at roughly 50, 60 and 70 kHz for X, Y and Z direction.
  • Three signal amplifiers that amplify the oscillator signals.
  • six field coils that make a cube of roughly 3x3x3 meters.
  • A small pick-up coil mounted on a glasses frame that is worn by the subject during the experiment.
  • Three lock-in amplifiers that split the signal from the pick-up coil in the 3 frequency components and measures their envelope.
  • An acquisition device that converts the output signals from the lock-in amplifiers.
  • A RZ6 multi I/O processor that records the acquired data.
  • Software that converts the recorded data to head orientations using calibration data.

The convention for the directions:

  • channel 1; 45 kHz; Frontal ;color = red ; Front = + Back = -
  • channel 2; 55 kHz; Vertical ;color = blue ; Right = + Left = -
  • channel 3; 65 kHz; Horizontal ;color = yellow; Up = + Down = -