Difference between revisions of "ButtonBoxes"
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Download this site-package to use the buttonbox: [https://pypi.python.org/pypi/RuSocSci rusocsci] | Download this site-package to use the buttonbox: [https://pypi.python.org/pypi/RuSocSci rusocsci] | ||
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or use in windows command 'pip install --upgrade rusocsci' | or use in windows command 'pip install --upgrade rusocsci' | ||
Revision as of 12:50, 7 August 2019
2018 Buttonbox | |
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2013 Buttonbox | |
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The buttonbox is used for time accurate(1ms) button press registration. We use it to register buttonpresses, soundkey, voicekey signals and to send tone onset, analog output, triggers with the BITSI protocol. It is suitable for Behavioral, EEG, MEG, and fMRI experiments. The buttonbox is connected to a computer with a usb connection.
The output connector has two binary eight bit ports: input and output. The two ports can be used for responses (input) and stimulus triggers (output). Two 12 bits analog outputs and three 12 bits analog inputs. The output connector has a sound and voicekey which triggers when a amplitude reaches a threshold. By using the serial port, the BITSI can be used platform independently: it works on Windows, Linux and Mac OSX. Most programming environments and stimulus packages support serial communication.
There is currently a Microsoft Windows driver issue.
BITSI Protocol
BITSI stands for Bits to Serial Interface. Because the BITSI is designed to interface both in- and output signals, the 'protocol' is asymmetric: the input and output protocols differ.
Input
The input port can be used to interface eight buttons maximally. Button presses are translated to serial output characters/bytes according to the following table:
BITSI Simple | ||
---|---|---|
Signal/Button | ASCII (rise/fall) | Code (rise/fall) |
1 | A / a | 65 / 97 |
2 | B / b | 66 / 98 |
3 | C / c | 67 / 99 |
4 | D / d | 68 / 100 |
5 | E / e | 69 / 101 |
6 | F / f | 70 / 102 |
7 | G / g | 71 / 103 |
8 | H / h | 72 / 104 |
This means that when signal 1 gets active(button press), a capital A will be sent to the serial port. A lowercase 'a' will be sent when the signal is deactivated(button release). Mechanical buttons can be connected directly.
Output
Output knows two protocols: BITSI simple or BITSI extended. To enter a certain protocol two buttons have to be pressed when the BITSIbox is powered or com port opens. [2015]Press button H and A for simple mode and H and B for extended mode. [2018]Press button E and A for simple mode and E and B for extended mode.
If no button is pressed when powered it boots the last known protocol. In the simple protocol every byte sent to the BITSI over the serial port, is represented at the 8 bit output.
The extended protocol uses two bytes(or two characters), this combination can access two analog outputs and a tone generator. The first byte selects the output. The second byte determines the value written to this output.
BITSI Extended | ||
---|---|---|
Function | Byte 1 (ASCII/code) | Byte 2 |
Marker Out | M / 77 | Marker Value |
Pulse Out | P / 80 | Marker Value |
Pulse Time | X / 88 | ms before pulse reset |
Analog Out 1 | Y / 89 | Analog Output Value |
Analog Out 2 | Z / 90 | Analog Output Value |
Tone | T / 84 | Start Tone |
Detect Sound | D / | S / 83 |
Detect Voice | D / | V / 83 |
Calibrate Sound | C / | S |
Calibrate Voice | C / | V |
Analog In 1 | A / | 1 |
Analog In 2 | A / | 2 |
Analog In 3 | A / | 3 |
Analog In 4 | A / | 4 |
LEDs Off | L / | X |
LEDs Input | L / | I |
LEDs Output | L / | O |
Port Settings
Trigger port
The 25 pins female connector has 8 inputs and 8 outputs, respectively 1-8 are inputs and 9-16 are outputs. Three analog input with an analog to digital convertor of 12 bit, pins 17,18,20 and 21. Two analog outputs with an digital to analog convertor of 12 bits on pins 22 and 23.
The inputs 1-8 will be pulled down from 5V to GND when the buttons are pressed. The outputs 9-16 will be pulled up from GND to 5V when the output is activated.
Serial port
Our hardware design allows to be connected to the computers USB and emulates a serial communication Port.
Baudrate | 115200 |
Parity | None |
Data bits | 8 |
Stop bits | 1 |
Flow control | None |
USB-Com port
1.Connect the BITSIbox to your computer using the USB cable.
2.When you connect the BITSIbox, Windows should initiate the driver installation process (if you haven't used the computer with an BITSIbox board before).
3.On Windows Vista/7, the driver should be automatically downloaded and installed.
4.On Windows XP, the Add New Hardware wizard will open:
- When asked Can Windows connect to Windows Update to search for software? select No, not this time. Click next.
- Select Install from a list or specified location (Advanced) and click next.
- Make sure that Search for the best driver in these locations is checked; uncheck Search removable media; check Include this location in the search and browse to the c:/beheer/arduino/drivers directory.
- The wizard will search for the driver and then tell you that a "USB Serial Converter" was found. Click finish.
- The new hardware wizard will appear again. Go through the same steps and select the same options and location to search. This time, a "USB Serial Port" will be found.
How to Check the Com Port settings(important!)
- From the Start menu, open the Control Panel.
- From the control panel, open the System window.
- From the system properties window, go to the Hardware tab and click the Device Manager button.
- From the Device Manager window, click Ports (Com&LPT). You should now be able to see which Com Port the USB adapter is assigned to.
- If the Com Port is 10 or higher, you will have to change it to a lower port.
- From the Device Manager window, click on USB Serial Port (Com#). Click the Port Settings tab of the USB Serial Port Properties window, and then click the Advanced button.
- In the Advanced Settings window, use the scroll input to select a Com Port (select 10 or lower). Change Receive (bytes) and Transmit (bytes) to 64. Change the Latency Timer to 1.
- Click the OK button.
Always connect the usb device to the same port and your settings will be remembered.
Software Settings
Neurobs Presentation
The experiment files needs a few settings for the device to work:
- In the settings tab: port -> input port -> 1 must be the device that identifies itself as "Arduino Uno" in the device manager. Note that the port must have a number not higher than 10 (COM1-COM10). Use re-enumerate if it is higher.
- Rate must be set 115200, Parity to None, Data Bits to 8 and Stop Bits to 1, Uncheck FIFO Interrupt.
Testing Buttonbox
When pressing on the A button within the input channel tester. You will see the following ASCII code.
Adding Marker
Testing Markers (output)
Send code 1 for Button A
Button A will light up.
Send code 0 for clearing.
Example PCL code you can program a handle to send a marker:
#handle: output_port OutputPort = output_port_manager.get_port( 1 );
Example to send a marker:
OutputPort.send_code(100); #create a marker
for more information see chapter 8 in the presentation course by clicking here
Python/PsychoPy
Download this site-package to use the buttonbox: rusocsci
or use in windows command 'pip install --upgrade rusocsci'
Example using buttons from the buttonbox in Python:
1#!/usr/bin/env python
2
3# import the rusocsci.buttonbox module
4from rusocsci import buttonbox
5
6# make a buttonbox
7bb = buttonbox.Buttonbox()
8
9# wait for a single button press
10b = bb.waitButtons()
11
12# print the button pressed
13print("b: {}".format(b))
Example using markers with the buttonbox in Python:
1#!/usr/bin/env python
2
3# import the rusocsci.buttonbox module
4from rusocsci import buttonbox
5
6# make a buttonbox
7bb = buttonbox.Buttonbox()
8
9# send a marker
10bb.sendMarker(val=100) #This is your marker code, range code 1-255
Example using BITSI extended in Python:
1#!/usr/bin/env python
2
3# import the rusocsci.buttonbox module
4from rusocsci import buttonbox
5
6# make a buttonbox
7bb = buttonbox.Buttonbox()
8
9# select a function
10bb.sendMarker(val=(ord(X))) #select pulse time
11bb.sendMarker(val=2) #set time of dureation pulse to 2ms
12
13bb.sendMarker(val=(ord(M))) #select marker out
14bb.sendMarker(val=115) #set marker value 115
Example using BITSI extended analog read in Python:
1#!/usr/bin/env python
2
3# import the rusocsci.buttonbox module
4import serial
5
6# make a buttonbox
7ser = serial.Serial("COM2", 115200, timeout = 0.10 )
8ser = serial.Serial("/dev/ttyUSB0", 115200, timeout = 0.10 )
9
10while True:
11 ser.write('A1')
12 ser.flush()
13 x = ser.readline()
14 visual.TextStim(win, text=x).draw()
15
16 # black screen for 1000 ms
17 win.flip()
18
19 key = event.getKeys()
20 try:
21 if key[0]=='escape':
22 break
23 except:
24 continue
Example using the Buttonbox in PsychoPy:
1#!/usr/bin/env python
2
3# import psychopy and rusocsci
4from psychopy import core, visual
5from rusocsci import buttonbox
6
7## Setup Section
8win = visual.Window(monitor="testMonitor")
9bb = buttonbox.Buttonbox()
10text = visual.TextStim(win, "Press a button on the buttonbox")
11
12## Experiment Section
13# show text
14text.draw()
15win.flip()
16# wait for response
17b = bb.waitButtons()
18# show response
19text.setText("you pressed: {}".format(b))
20text.draw()
21win.flip()
22core.wait(5)
23
24## Cleanup Section
25core.quit()
For more documentation click here: http://pythonhosted.org//RuSocSci/index.html
Matlab
1function ret = buttonbox(cmd,varargin)
2% to initialize connection: (omit 2nd argument if defaults apply)
3% define settings as structure with fields:
4% bb.Device = 'COM2';
5% bb.BaudRate = 115200;
6% bb.DataBits = 8;
7% bb.StopBits = 1;
8% bb.Parity = 'none';
9% handle = buttonbox('open',bb)
10%
11% to run: (receiving incoming data, check code for own purposes)
12% buttonbox('run');
13%
14% or
15%
16% to send a marker: (marker: a numeric value; Fs: sampling frequency device)
17% buttonbox(marker,Fs)
18%
19% or
20%
21% to wait for a buttonpress:
22% buttonbox('clear'); (make sure buttonbox buffer is emptied)
23% key = buttonbox('wait_keypress')
24%
25% to close the connection:
26% buttonbox('close');
27
28persistent old_hdl % keep handle to COM object persistent
29% set defaults
30bb.Device = 'COM2';
31bb.BaudRate = 115200;
32bb.DataBits = 8;
33bb.StopBits = 1;
34bb.Parity = 'none';
35
36if nargin < 1
37 cmd = 'open';
38end
39if nargin > 1 && isstruct(varargin{1})
40 % user overwrites default settings
41 flds = fields(varargin{1});
42 for n = 1 : numel(flds)
43 bb.(flds{n}) = varargin{1}.(flds{n});
44 end
45end
46if nargin==1 && isnumeric(cmd)
47 error('Please also specify acquisition sampling frequency of device that receives the marker');
48end
49if nargin > 1 && isnumeric(cmd)
50 marker = cmd;
51 cmd = 'marker';
52 Fs = varargin{1};
53end
54
55if ~any(strcmp(cmd,{'open','close'}))
56 if isempty(old_hdl)
57 help serial_buttonbox_common
58 error('Buttonbox not yet initialized');
59 end
60 handle = old_hdl;
61end
62
63switch cmd
64 case 'marker'
65 fwrite(handle, uint8(marker));%IOPort('Write', handle, uint8(marker), 1); % last argument: blocking
66 WaitSecs(2/Fs);
67 fwrite(handle, uint8(0));%IOPort('Write', handle, uint8(0), 0); % last argument: blocking
68 return
69 case 'clear'
70 while(handle.BytesAvailable)
71 fread(handle, 1);
72 end
73 ret = []; % meaningless
74 return
75 case 'open'
76 % get handle to serial device
77 handle = open_buttonbox(bb);
78 ret = handle;
79 return
80 case 'close'
81 if nargin > 1
82 handle = varargin{1};
83 else
84 handle = old_hdl;
85 end
86 fclose(handle);
87 delete(handle);
88 ret = [];
89 return
90 case 'run'
91 % read incoming data
92 % code proceeds below ....
93 case 'wait_keypress'
94 % start polling for characters (indicating start of scan)
95 while(1)
96 data = [];
97 while handle.BytesAvailable
98 navailable = handle.BytesAvailable;
99 % read incoming data
100 [newdata, cnt] = fread(handle, navailable);
101 % concatenate possible new data
102 if cnt
103 data = [data newdata(:)];
104 end
105 end
106 if ~isempty(data)
107 ret = data;
108 return
109 end
110 end
111 otherwise
112 fprintf('Unknown option %s\n',cmd);
113 ret = [];
114 return
115end
116
117%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
118% only gets here when cmd = 'run' %
119%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
120% Initialize output figure
121win = list_output(' ',[]);
122while 1
123 % Exit if user closed output figure
124 if ~ishandle(win)
125 return
126 end
127 % start polling for characters (indicating start of scan)
128 navailable = handle.BytesAvailable;
129 if navailable
130 data = [];
131 while navailable
132 % read incoming data
133 [newdata, cnt] = fread(handle, navailable);
134 % concatenate possible new data
135 if cnt
136 data = [data newdata(:)];
137 end
138 % check if any more data left
139 navailable = handle.BytesAvailable;
140 end
141 % output info about which button was pressed
142 for n = 1 : numel(data)
143 line = sprintf('incoming: %03d %s',data(n),char(data(n)));
144 list_output(line,win);
145 end
146 end
147 pause(0.01);
148end %while 1
149
150
151
152 function hdl = open_buttonbox(device)
153 % open handle to serial device (mini buttonbox) WaitSecs(0.002); % just to load mex-file into memory
154 try
155 hdl = serial(device.Device, 'Baudrate', device.BaudRate, 'DataBits', device.DataBits, 'StopBits', device.StopBits, 'Parity', device.Parity);
156 fopen(hdl);
157 catch
158 if ~isempty(old_hdl)
159 fclose(old_hdl);
160 delete(old_hdl);
161 end
162 hdl = serial(device.Device, 'Baudrate', device.BaudRate, 'DataBits', device.DataBits, 'StopBits', device.StopBits, 'Parity', device.Parity);
163 fopen(hdl);
164 end
165 old_hdl = hdl;
166 fprintf('Wait for device buttonbox....\n');
167 tic
168 while hdl.BytesAvailable && toc<10
169 navailable = bbox.BytesAvailable;
170 % wait for welcome message device
171 fread(hdl, navailable);
172 end
173 pause(0.5);
174 end
175
176 function win = list_output(line,win)
177 persistent ptr
178 persistent lines
179 persistent edt
180 Maxlines = 40;
181 if isempty(win)
182 % initialize listbox output figure
183 lines = cell(1,Maxlines);
184 [lines(1:end)]=deal({''});
185 ptr=Maxlines;
186 lines(ptr) = {'Buttonbox output:'};
187 idxs = mod(ptr:ptr+Maxlines-1,Maxlines)+1;
188 win = figure();
189 % initialize figure to hold output text
190 edt = uicontrol('Parent',win,'Style','ListBox','HorizontalAlignment','left', ...
191 'Max',Maxlines,'BackgroundColor',[1 1 1],'Visible','on','String',lines(idxs), ...
192 'FontSize',12,'Value',Maxlines);
193 pos = get(win,'Position');
194 set(edt,'Position',[1 1 pos(3) pos(4)]);
195 end
196 ptr = mod(ptr,Maxlines)+1; % start
197 lines{ptr} = line;
198 idxs = mod(ptr:ptr+Maxlines-1,Maxlines)+1;
199 set(edt,'String',lines(idxs),'Value',Maxlines);
200 drawnow;
201 end
202end
203 end