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readLeCroyWaveJetWfm.m
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readLeCroyWaveJetWfm.m
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function [ varargout ] = readLeCroyWaveJetWfm( varargin )
%readLeCroyWaveJetWfm - Read binary waveform (.wfm) files as saved by
% LeCroy WaveJet oscilloscopes.
%
% readLeCroyWaveJetWfm( filename )
%
% Loads the specified file, shows some information about the file,
% and displays the waveform(s).
%
% [ data ] = readLeCroyWaveJetWfm( filename )
% [ data nfo ] = readLeCroyWaveJetWfm( filename )
%
% Load the specified file and returns its data.
% data - Array with loaded waveform(s). If only one channel was recorded
% this is a single column with the waveform. If more than one
% channel was recorded this is a 2D array where each column
% corresponds with a channel. If a lower number channel is not
% recorded it will contain a column with NaN's. If a higher number
% channel is not recorded, it's column is removed from the data
% array. E.g. ch1: x, ch2: 0, ch3: x, ch4: 0 will result in a 2D
% array with 3 column, where the second column contains NaN's.
% nfo - structure with time axis information and text header
% nfo.x0 - time of first sample (trigger will be at t = 0)
% nfo.dx - sampling time, i.e. time between two consecutive samples
% nfo.notes - text field with complete oscilloscope setup.
%
% Copyright (c) 2008-2010, Paul Wagenaars
% All rights reserved.
%
% Redistribution and use in source and binary forms, with or without
% modification, are permitted provided that the following conditions are
% met:
%
% * Redistributions of source code must retain the above copyright
% notice, this list of conditions and the following disclaimer.
% * Redistributions in binary form must reproduce the above copyright
% notice, this list of conditions and the following disclaimer in
% the documentation and/or other materials provided with the distribution
%
% THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
% AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
% IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
% ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
% LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
% CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
% SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
% INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
% CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
% ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
% POSSIBILITY OF SUCH DAMAGE.
%
% Changelog:
% v0.1 (2008-06-29)
% - initial release
%
% v0.2 (2008-08-??)
% - in averaging mode the binary WFM waveform seems to have a half a
% sample offset compared to the ASCII CSV file. The binary waveform is
% now shifted half sample downwards.
% - if averaging mode is turned on the data of inactive channels was
% skipped incorrectly. This has been fixed.
%
% v0.3 (2010-03-02)
% - made function compatible with GNU Octave.
% - fixed waveforms with multiple waveform modes, e.g. when averaging and
% equivalent sampling are specified at the same time.
%
% Define some constants
global RLWJW_XWAV_DEF_INF_NOACQ RLWJW_XWAV_DEF_INF_NORM RLWJW_XWAV_DEF_INF_PEAK
global RLWJW_XWAV_DEF_INF_EQU RLWJW_XWAV_DEF_INF_AVG RLWJW_XWAV_DEF_INF_ROLL
global RLWJW_XWAV_DEF_INF_ILV
RLWJW_XWAV_DEF_INF_NOACQ = uint16(0); % 0x0000 /* Not acquired */
RLWJW_XWAV_DEF_INF_NORM = uint16(1); % 0x0001 /* Normal wave */
RLWJW_XWAV_DEF_INF_PEAK = uint16(2); % 0x0002 /* Peak wave */
RLWJW_XWAV_DEF_INF_EQU = uint16(4); % 0x0004 /* Equ wave */
RLWJW_XWAV_DEF_INF_AVG = uint16(8); % 0x0008 /* Average wave */
RLWJW_XWAV_DEF_INF_ROLL = uint16(16); % 0x0010 /* Roll wave */
RLWJW_XWAV_DEF_INF_ILV = uint16(32); % 0x0020 /* Interleave wave */
% Maximum memory enum
global MAX_MEM_ENUM
MAX_MEM_ENUM = 1024 * [0 0.5 ; 1 1 ; 2 10 ; 3 100 ; 4 500];
% V/div enum
global RLWJW_VDIV_ENUM
RLWJW_VDIV_ENUM = [10 5 2 1 500e-3 200e-3 100e-3 50e-3 20e-3 10e-3 5e-3 2e-3];
% time/div enum
global RLWJW_TDIV_ENUM
RLWJW_TDIV_ENUM = [50 20 10 5 2 1 500e-3 200e-3 100e-3 ...
50e-3 20e-3 10e-3 5e-3 2e-3 1e-3 500e-6 200e-6 100e-6 ...
50e-6 20e-6 10e-6 5e-6 2e-6 1e-6 500e-9 200e-9 100e-9 ...
50e-9 20e-9 10e-9 5e-9 2e-9 1e-9 500e-12 200e-12 100e-12 ...
50e-12 20e-12 10e-12 5e-12 2e-12 1e-12 500e-15 200e-15 100e-15];
% Display informatie about waveform(s)
infomode = (nargout == 0);
if nargin < 1
error('No filename specified.');
else
filename = varargin{1};
end
if infomode
fprintf('Loading %s\n', filename);
end
% Open file
[fid, msg] = fopen(filename, 'r', 'b');
if fid == -1
error('Unable to open %s: %s', filename, msg);
end
% Skip text header
fullheader = '';
while true
line = fgetl(fid);
fullheader = sprintf('%s%s\n', fullheader, line);
if ~ischar(line)
fclose(fid);
error('Unable to find end of setup information. Is this a correct LeCroy WaveJet .wfm file?');
elseif strcmp(line, '[END OF SETUP]');
% The 'fgetl' function seems to consume one byte too much.
% So, here we check the byte and rewind in necessary.
fseek(fid, -1, 'cof');
data = fread(fid, 1, 'uint8');
if (data ~= 10) && (data ~= 13)
fseek(fid, -1, 'cof');
end
break;
end
end
% Read the XWAV_TDE_WAVEINF structure
wavinf = load_XWAV_TDE_WAVEINF(fid);
% Read waveform data
data = nan(wavinf.timebase.memoryLength + 1, 4);
dataStart = wavinf.timebase.validWfmStart;
memLen = wavinf.timebase.memoryLength;
bankSize = wavinf.timebase.bankSize;
validChannels = nan(1,4);
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_AVG)
bytesPerSample = 2;
else
bytesPerSample = 1;
end
sampleType = sprintf('int%d', 8 * bytesPerSample);
maxValue = 2^(8 * bytesPerSample);
for j = 1:4
if wavinf.channels(j).isValid
validChannels(j) = 1;
singleChannel = fread(fid, bankSize, sampleType);
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_AVG)
% In average mode there is a half a sample offset compared to
% the csv file. Here we correct that.
singleChannel = singleChannel - 127;
end
singleChannel = singleChannel * 8 * wavinf.channels(j).vdiv / maxValue;
singleChannel = singleChannel - wavinf.channels(j).offset;
data(:, j) = singleChannel((5 + dataStart):(memLen + dataStart + 5));
else
validChannels(j) = 0;
fseek(fid, bankSize * bytesPerSample, 'cof');
end
end
fclose(fid);
clear singleChannel;
% Select only the "good" channels
if sum(validChannels) == 1
data = data(:, validChannels == 1);
elseif sum(validChannels) < 4
maxIndex = find(validChannels == 1, 1, 'last');
data = data(:, 1:maxIndex);
end
% Create nfo structure
totalTime = 10.0 * wavinf.timebase.tdiv;
nfo.dx = totalTime / (wavinf.timebase.memoryLength);
nfo.x0 = -0.5 * totalTime - wavinf.timebase.delay + nfo.dx;
nfo.notes = fullheader;
if infomode
showInfo(wavinf, nfo, data);
end
% Set the output arguments
if nargout >= 1
varargout{1} = data;
end
if nargout >= 2
varargout{2} = nfo;
end
end % End of main function
%%
%% SUBFUNCTIONS
%%
%% load_XWAV_TDE_WAVEINF
% Loads a wave information structure from file.
% The structure (C code):
% typedef struct
% {
% XWAV_TDE_WAVEINF_TBASE TbaseInfo; /* Time Base Info. */
% XWAV_TDE_WAVEINF_CH ChInfo[4]; /* Ch Info. */
% } XWAV_TDE_WAVEINF;
function [waveinfo] = load_XWAV_TDE_WAVEINF(fid)
waveinfo.timebase = load_XWAV_TDE_WAVEINF_TBASE(fid);
waveinfo.channels = load_XWAV_TDE_WAVEINF_CH(fid);
end
%% load_XWAV_TDE_WAVEINF_TBASE
% Loads a time base information structure from file.
% The structure (C code):
% typedef struct
% {
% SVMNG_TDE_TRGDLY delay; /* Trigger delay time?i-500s..750s?j*/
% XWAV_TDE_TSTAMP Tstamp; /* Time stamp */
% IWDP_TDE_BANKS bankNr; /* Current bank size setting in enum */
% Uint mleng; /* Memory length */
% Uint BankSize; /* Actual bank size (512..512*1024) */
% Uint TrgSkew; /* Trigger skew(TDC): WDP internal value */
% Uint WavValidAdr; /* Start address for valid waveform data */
% Ushort wvinf; /* Bitfielf of waveform mode */
% Ushort AvgTimes; /* Number of average (0,1?`256) */
% char tim; /* time/div in enum */
% char spclk; /* sampling clock in enum */
% Uchar RdmInitVal; /* Random seed: WDP internal value */
% Uchar WavSkew; /* Fraction of delay and trigger skew in a
% sampling clock. 0..99 for normalwaveform,
% 0..49 for interleaved waveform,
% (0..100)/(equivalent sampling) for EQU. */
% Uchar maxmem; /* MAX MEMORY LENGTH 0:0.5k, 1:1k, 2:10k,
% 3:100k, 4:500k */
% Ushort MaskBank; /* Mask for bank number */
% } XWAV_TDE_WAVEINF_TBASE;
%
% Sizes of the differnet bank numbers (bankNr):
% IWDP_ENM_BANKS = [8 16 32 64 128 256 512 1024 2*1024 4*1024 8*1024 ...
% 16*1024 32*1024 64*1024 128*1024 256*1024 512*1024 1048576 ...
% 2*1048576 4*1048576 Inf];
function [tbase] = load_XWAV_TDE_WAVEINF_TBASE(fid)
global MAX_MEM_ENUM RLWJW_TDIV_ENUM
tbase.delay = load_SVMNG_TDE_TRGDLY(fid);
tbase.timeStamp = load_XWAV_TDE_TSTAMP(fid);
tbase.bankNr = fread(fid, 1, 'uint32');
tbase.memoryLength = fread(fid, 1, 'uint32');
tbase.bankSize = fread(fid, 1, 'uint32');
tbase.triggerSkew = fread(fid, 1, 'uint32');
tbase.validWfmStart = fread(fid, 1, 'uint32');
tbase.wfmMode = fread(fid, 1, 'uint16');
tbase.nrAvgs = fread(fid, 1, 'uint16');
tbase.tdivEnum = fread(fid, 1, 'uint8');
tbase.tdiv = RLWJW_TDIV_ENUM(1 + tbase.tdivEnum);
tbase.samplingClockEnum = fread(fid, 1, 'uint8');
tbase.rndInit = fread(fid, 1, 'uint8');
tbase.wavSkew = fread(fid, 1, 'uint8');
tbase.maxMemory = MAX_MEM_ENUM(1 + fread(fid, 1, 'uint8'), :);
tbase.bankMask = fread(fid, 1, 'uint16');
fread(fid, 1, 'uint8');
end
%% load_SVMNG_TDE_TRGDLY
% // Trigger delay structure
% typedef struct {
% Uint sgn; // -1:-/0:+
% Uint sec; // 0?`750s (1s?`750s)
% Uint us; // 0?`999999us (1us?`999ms)
% Uint ps; // 0?`999999ps (1ps?`999ns)
% } SVMNG_TDE_TRGDLY;
function [delay] = load_SVMNG_TDE_TRGDLY(fid)
sgn = fread(fid, 1, 'uint32');
sec = fread(fid, 1, 'uint32');
us = fread(fid, 1, 'uint32');
ps = fread(fid, 1, 'uint32');
if sgn == 0
delay = 1.0;
else
delay = -1.0;
end
delay = delay * (sec + 1e-6 * us + 1e-12 * ps);
end
%% load_XWAV_TDE_TSTAMP
% Load time stamp information.
%
% // Date structure
% typedef struct {
% Ushort year;
% Uchar month;
% Uchar day;
% } SVMNG_TDE_DATE;
%
% // Time structure
% typedef struct {
% Uchar hour;
% Uchar min;
% Uchar sec;
% } SVMNG_TDE_TIME;
%
% typedef struct {
% SVMNG_TDE_DATE date; // DATE year:2000..2099, month:1..12, day:1..31
% SVMNG_TDE_TIME time; // TIME hour:0..23, min:0..59, sec:0..59
% Uchar msec; // 100ms
% } XWAV_TDE_TSTAMP;
function [tstamp] = load_XWAV_TDE_TSTAMP(fid)
year = fread(fid, 1, 'uint16');
month = fread(fid, 1, 'uint8');
day = fread(fid, 1, 'uint8');
hour = fread(fid, 1, 'uint8');
min = fread(fid, 1, 'uint8');
sec = fread(fid, 1, 'uint8');
msec = 100 * fread(fid, 1, 'uint8');
tstamp = [year month day hour min sec msec];
end
%% load_XWAV_TDE_WAVEINF_CH
% Load channel information for a single channel.
function [chs] = load_XWAV_TDE_WAVEINF_CH(fid)
global RLWJW_VDIV_ENUM
chs = struct('offset', {NaN NaN NaN NaN}, ...
'vdivEnum', {NaN NaN NaN NaN}, ...
'isValid', {false false false false});
for i = 1:4
chs(i).offset = fread(fid, 1, 'int32');
chs(i).vdivEnum = fread(fid, 1, 'uint8');
chs(i).vdiv = RLWJW_VDIV_ENUM(1 + chs(i).vdivEnum);
chs(i).offset = chs(i).offset / 3200 * chs(i).vdiv;
chs(i).isValid = (fread(fid, 1, 'uint8') > 0);
chs(i).unknown = fread(fid, 1, 'uint16');
end
end
%% Show information about the waveform(s)
function showInfo(wavinf, nfo, data)
global RLWJW_XWAV_DEF_INF_NOACQ RLWJW_XWAV_DEF_INF_NORM
global RLWJW_XWAV_DEF_INF_PEAK RLWJW_XWAV_DEF_INF_EQU
global RLWJW_XWAV_DEF_INF_AVG RLWJW_XWAV_DEF_INF_ROLL
global RLWJW_XWAV_DEF_INF_ILV
fprintf('Time stamp: %04d-%02d-%02d %02d:%02d:%02d.%03d\n', ...
wavinf.timebase.timeStamp);
fprintf('Memory length: %d (max.mem %dk)\n', wavinf.timebase.memoryLength, ...
wavinf.timebase.maxMemory(2)/1024);
fprintf('Bank size: %d\n', wavinf.timebase.bankSize);
fprintf('Waveform mode:');
if wavinf.timebase.wfmMode == RLWJW_XWAV_DEF_INF_NOACQ
fprintf(' not_acquired');
else
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_NORM)
fprintf(' normal');
end
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_PEAK)
fprintf(' peak');
end
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_EQU)
fprintf(' equivalent_sampling');
end
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_AVG)
fprintf(' averaged(%dx)', wavinf.timebase.nrAvgs);
end
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_ROLL)
fprintf(' roll');
end
if bitand(wavinf.timebase.wfmMode, RLWJW_XWAV_DEF_INF_ILV)
fprintf(' interleaved');
end
end
fprintf('\n');
fprintf('Hor. resolution: %g s/div (%d)\n', wavinf.timebase.tdiv, ...
wavinf.timebase.tdivEnum);
fprintf('Trigger delay: %g s\n', wavinf.timebase.delay);
fprintf('Valid wfm start: %d\n', wavinf.timebase.validWfmStart);
fprintf(' Channel 1 Channel 2 Channel 3 Channel 4 \n');
fprintf('offset (V) %9g %9g %9g %9g\n', wavinf.channels.offset);
fprintf('resolution (V/div) %9g %9g %9g %9g\n', wavinf.channels.vdiv);
fprintf('channel on or off? %9g %9g %9g %9g\n', wavinf.channels.isValid);
fprintf('unknown %9d %9d %9d %9d\n', wavinf.channels.unknown);
xf = (wavinf.timebase.memoryLength) * nfo.dx + nfo.x0;
t = linspace(nfo.x0, xf, wavinf.timebase.memoryLength + 1);
figure;
plot(t, data);
grid on;
xlabel('Time (s)');
end % end of showInfo function