header - WFDB header file format
For each database record,
a header file specifies the names of the associated signal files and their
attributes. Programs compiled with the WFDB library (-lwfdb) can read header
files created by newheader (see wfdb(3)
). Header files contain line- and
field-oriented ASCII text. ASCII linefeed characters separate lines (which
may not contain more than 255 characters each, including the linefeed),
and spaces or tabs separate fields (except as noted below). Beginning with
WFDB library version 6.1, an ASCII carriage return character may precede
each linefeed. Fields not specifically designated below as optional must
be present.
Header files contain at a minimum a record line, which specifies
the record name, the number of segments, and the number of signals. Header
files for ordinary records (those that contain one segment) also contain
a signal specification line for each signal. Header files for multi-segment
records (supported by WFDB library version 9.1 and later versions) contain
a segment specification line for each segment; see the section on multi-segment
records below for details.
Comment lines may appear anywhere in a header
file. The first printing character in a comment line must be ‘#’. Comment
lines that follow the last signal specification line are treated specially
(see Info strings, below). All other comment lines are ignored by WFDB
library functions that read header files.
The first non-empty,
non-comment line is the record line. It contains information applicable
to all signals in the record. Its fields are, from left to right:
- record
name
- A string of characters that identify the record. The record name may
include letters, digits and underscores (‘_’) only.
- number of segments [optional]
- This field, if present, is not separated by whitespace from the record
name field; rather, it follows a ‘/’, which serves as a field separator.
If the field is present, it indicates that the record is a multi-segment
record containing the specified number of segments, and that the header
file contains segment specification lines rather than signal specification
lines. The number of segments must be greater than zero. A value of 1 in
this field is legal, though unlikely to be useful.
- number of signals
- Note
that this is not necessarily equal to the number of signal files, since
two or more signals can share a signal file. This number must not be negative;
a value of zero is legal, however.
- sampling frequency (in samples per second
per signal) [optional]
- This number can be expressed in any format legal
for scanf(3)
input of floating point numbers (thus ‘360’, ‘360.’, ‘360.0’, and
‘3.6e2’ are all legal and equivalent). The sampling frequency must be greater
than zero; if it is missing, a value of 250 (DEFREQ, defined in <wfdb/wfdb.h>)
is assumed.
- counter frequency (in ticks per second) [optional]
- This field
(a floating-point number, in the same format as the sampling frequency)
can be present only if the sampling frequency is also present. It is not
separated by whitespace from the sampling frequency field; rather, it follows
a ‘/’, which serves as a field separator. The sampling and counter frequencies
are used by strtim to convert strings beginning with ‘c’ into sample intervals.
Typically, the counter frequency may be derived from an analog tape counter,
or from page numbers in a chart recording. If the counter frequency is absent
or not positive, it is assumed to be equal to the sampling frequency. WFDB
library versions 5.1 and earlier ignore the counter frequency field.
- base
counter value [optional]
- This field can be present only if the counter
frequency is also present. It is not separated by whitespace from the counter
frequency field; rather, it is surrounded by parentheses, which delimit
it. The base counter value is a floating-point number that specifies the
counter value corresponding to sample 0. If absent, the base counter value
is taken to be zero. WFDB library versions 5.1 and earlier ignore the base
counter value field.
- number of samples per signal [optional]
- This field
can be present only if the sampling frequency is also present. If it is
zero or missing, the number of samples is unspecified and checksum verification
of the signals is disabled.
- base time [optional]
- This field can be present
only if the number of samples is also present. It gives the time of day
that corresponds to the beginning of the record, in HH:MM:SS format (using
a 24-hour clock; thus 13:05:00, or 13:5:0, represent 1:05 pm). If this field
is absent, the time-conversion functions assume a value of 0:0:0, corresponding
to midnight.
- base date [optional]
- This field can be present only if the
base time is also present. It contains the date that corresponds to the
beginning of the record, in DD/MM/YYYY format (e.g., 25/4/1989 is 25 April
1989).
Each non-empty, non-comment line following
the record line in a single-segment record contains specifications for one
signal, beginning with signal 0. Header files must contain valid signal
specification lines for at least as many signals as were indicated in the
record line (the first non-empty, non-comment line in the file). Any extra
signal specification lines are not read by WFDB library functions. From
left to right in each line, the fields are:
- file name
- The name of the file
in which samples of the signal are kept. The environment variable WFDB (the
database path) lists the directories in which signal files (as well as
WFDB header and annotation files) are found; normally WFDB should include
an initial empty component, so that signal files can be kept in any directory
if they are designated by absolute path names in the header file. If the
file name specifies that the signal file is to be found in a directory
that is not already in WFDB, that directory is appended to the end of WFDB
(by functions that read header files in WFDB library version 6.2 and later
versions). Although the record name is usually part of the signal file name,
this convention is not a requirement (see, e.g., examples 3, 4, and 5 below).
Note that several signals can share the same file (i.e., they can belong
to the same signal group); all entries for signals that share a given file
must be consecutive, however. The file name ‘-’ refers to the standard input
or output. The sum of the lengths of the file name and description fields
(see below) is limited to 80 characters.
- format
- This field is an integer
that specifies the storage format of the signal. All signals in a given
group are stored in the same format. The most common formats are format
8 (eight-bit first differences) and format 16 (sixteen-bit amplitudes);
see signal(5)
(or <wfdb/wfdb.h>) for a list of other supported formats. The
following three optional fields, if present, are bound to the format field
(i.e., not separated from it by whitespace); they may be considered as format
modifiers, since they further describe the encoding of samples within the
signal file.
- samples per frame [optional]
- If present, this field follows
an ‘x’ that serves as a field separator. Normally, all signals in a given
record are sampled at the (base) sampling frequency as specified in the
record line; in this case, the number of samples per frame is 1 for all
signals, and this field is conventionally omitted. If the signal was sampled
at some integer multiple, n, of the base sampling frequency, however, each
frame (set of samples returned by getframe) contains n samples of the signal,
and the value specified in this field is also n. (Note that non-integer
multiples of the base sampling frequency are not supported.) WFDB library
versions 8.3 and earlier ignore this field if it is present, and cannot
properly read signal files that contain more than one sample per signal
per frame.
- skew [optional]
- If present, this field follows a ‘:’ that serves
as a field separator. Ideally, within a given record, samples of different
signals with the same sample number are simultaneous (within one sampling
interval). If this is not the case (as, for example, when a multitrack
analog tape recording is digitized and the azimuth of the playback head
does not match that of the recording head), the skew between signals can
sometimes determined (for example, by locating recorded waveform features
with known time relationships, such as calibration signals). If this has
been done, the skew field may be inserted into the header file to indicate
the (positive) number of samples of the signal that are considered to precede
sample 0. These samples, if any, are included in the checksum, but cannot
be returned by getvec or getframe (thus the checksum need not be changed
if the skew field is inserted or modified). WFDB library versions 9.1 and
earlier ignore this field if it is present; later versions correctly deskew
signals in accordance with the contents of this field.
- byte offset [optional]
- If present, this field follows a ‘+’ that serves as a field separator. Normally,
signal files include only sample data. If a signal file includes a preamble,
however, this field specifies the offset in bytes from the beginning of
the signal file to sample 0 (i.e., the length of the preamble). Data within
the preamble is not included in the signal checksum. Note that the byte
offset must be the same for all signals within a given group (use the skew
field to correct for intersignal skew). This feature is provided only to
simplify the task of reading signal files not generated using the WFDB
library; the WFDB library does not support any means of writing such files,
and byte offsets must be inserted into header files manually. WFDB library
versions 4.4 and earlier ignore byte offsets; these versions return any
preamble data as samples.
- ADC gain (ADC units per physical unit) [optional]
- This field is a floating-point number that specifies the difference in sample
values that would be observed if a step of one physical unit occurred in
the original analog signal. For ECGs, the gain is usually roughly equal
to the R-wave amplitude in a lead that is roughly parallel to the mean cardiac
electrical axis. If the gain is zero or missing, this indicates that the
signal amplitude is uncalibrated; in such cases, a value of 200 (DEFGAIN,
defined in <wfdb/wfdb.h>) ADC units per physical unit may be assumed.
- baseline
(ADC units) [optional]
- This field can be present only if the ADC gain is
also present. It is not separated by whitespace from the ADC gain field;
rather, it is surrounded by parentheses, which delimit it. The baseline
is an integer that specifies the sample value corresponding to 0 physical
units. If absent, the baseline is taken to be equal to the ADC zero. Note
that the baseline need not be a value within the ADC range; for example,
if the ADC input range corresponds to 200-300 degrees Kelvin, the baseline
is the (extended precision) value that would map to 0 degrees Kelvin. WFDB
library versions 5.0 and earlier ignore baseline fields.
- units [optional]
- This field can be present only if the ADC gain is also present. It follows
the baseline field if that field is present, or the gain field if the baseline
field is absent. It is not separated by whitespace from the previous field;
rather, it follows a ‘/’, which serves as a field separator. The units field
is a character string without embedded whitespace that specifies the type
of physical unit. If the units field is absent, the physical unit may be
assumed to be one millivolt. WFDB library versions 4.7 and earlier ignore
units fields.
- ADC resolution (bits) [optional]
- This field can be present
only if the ADC gain is also present. It specifies the resolution of the
analog-to-digital converter used to digitize the signal. Typical ADCs have
resolutions between 8 and 16 bits. If this field is missing or zero, the
default value is 12 bits for amplitude-format signals, or 10 bits for difference-format
signals (unless a lower value is specified by the format field).
- ADC zero
[optional]
- This field can be present only if the ADC resolution is also
present. It is an integer that represents the amplitude (sample value)
that would be observed if the analog signal present at the ADC inputs had
a level that fell exactly in the middle of the input range of the ADC.
For a bipolar ADC, this value is usually zero, but a unipolar (offset binary)
ADC usually produces a non-zero value in the middle of its range. Together
with the ADC resolution, the contents of this field can be used to determine
the range of possible sample values. If this field is missing, a value of
zero is assumed.
- initial value [optional]
- This field can be present only
if the ADC zero is also present. It specifies the value of sample 0 in
the signal, but is used only if the signal is stored in difference format.
If this field is missing, a value equal to the ADC zero is assumed.
- checksum
[optional]
- This field can be present only if the initial value is also
present. It is a 16-bit signed checksum of all samples in the signal. (Thus
the checksum is independent of the storage format.) If the entire record
is read without skipping samples, and the header’s record line specifies
the correct number of samples per signal, this field is compared against
a computed checksum to verify that the signal file has not been corrupted.
A value of zero may be used as a field placeholder if the number of samples
is unspecified.
- block size [optional]
- This field can be present only if
the checksum is present. This field is an integer and is usually zero. If
the signal is stored in a file that must be read in blocks of a specific
size, however, this field specifies the block size in bytes. (On UNIX systems,
this is the case only for character special files, corresponding to certain
tape and raw disk files. If necessary, the block size may be given as a
negative number to indicate that the associated file lacks I/O driver support
for fseek(3)
operations.) All signals belonging to the same signal group
have the same block size.
- description [optional]
- This field can be present
only if the block size is present. Any text between the block size field
and the end of the line is taken to be a description of the signal. When
creating new records, follow the style used to document the signals in
existing header files. Unlike the other fields in the header file, the
description may include embedded spaces; note that whitespace between the
block size and description fields is not considered to be part of the description,
however. If the description is missing, the WFDB library functions that
read header files supply a description of the form ’record rec, signal n’
(shortened to ’signal n’ by many WFDB applications).
Comment lines
that follow the last signal specification line in a header file can be
read and written by the WFDB library functions getinfo and putinfo; the
contents of these lines (excluding the initial ‘#’ comment character) are
referred to as ‘info strings’. There must be no whitespace preceding the initial
‘#’ in any line that is to be recognized by getinfo.
Each
non-empty, non-comment line following the record line in the top-level header
file of a multi-segment record contains specifications for one segment,
beginning with segment 0. (Info strings cannot be used in the top-level header
file of a multi-segment record.) Top-level header files must contain valid
segment specification lines for at least as many segments as were indicated
in the record line. Any extra segment specification lines are not read
by WFDB library functions.
A segment is simply an ordinary (single-segment)
record, with its own header and signal files. By including segments in
a multi-segment record, the signals within them can be read by WFDB applications
as if they were continuous signals, beginning with those in segment 0 and
continuing with those in segment 1, with no need for the applications to
do anything special to move from one segment to another. The only restrictions
are that segments cannot themselves contain other segments (they must be
single-segment records), the sampling frequencies must not change from segment
to segment, and the number of samples per signal must be defined for each
segment in the record line of the segment’s own header file.
Two types of
multi-segment records are defined. In a fixed-layout record, the arrangement
of signals is constant across all segments, and the signal gain, baseline,
units, ADC resolution and zero, and description match for corresponding
signals in all segments (these recommendations are not enforced by the
WFDB library, but existing applications are likely to behave unpredictably
if they are not followed). Note, however, that it is not necessary to use
the same signal storage format in all segments, and significant space savings
may be possible in some cases by selecting an optimal format for each segment.
Each segment of a fixed-layout record is an ordinary record containing
one or more samples.
In a variable-layout record, the arrangement of signals
may vary, signals may be absent in some segments, and the gains and baselines
may change between segments. A variable-layout record can be identified
by the presence of a layout segment, which must be segment 0 and must have
a length of 0 samples. The layout segment has no associated signal files;
its header file specifies the desired arrangement of signals and their
gains and baselines. Signal file names in a layout segment header are recorded
as ‘~’. When read using WFDB library version 10.3.17 or later, the signals
of a variable layout record are rearranged, shifted, and rescaled as needed
in order to present the signals in the arrangement and with the gains and
baselines specified in the layout segment header.
Each segment specification line contains the following fields, separated
by whitespace:
- record name
- A string of characters identifying the single-segment
record that comprises the segment. As in the record line, the record name
may include letters, digits, and underscores (‘_’) only.
- number of samples
per signal
- This number must match the number specified in the header file
for the single-segment record that comprises the segment.
Variable-layout
records may contain null segments, which can be identified if the record
name given in the segment specification line is ‘~’. The number of samples
per signal indicates the length of the null segment; when read, these
samples have the value WFDB_INVALID_DATA (defined in <wfdb/wfdb.h>). Null
segments do not have associated header or signal files.
- Example
1 (MIT DB record 100):
- 100 2 360 650000 0:0:0 0/0/0
100.dat 212 200 11 1024 995 -22131 0 MLII
100.dat 212 200 11 1024 1011 20052 0 V5
# 69 M 1085 1629 x1
# Aldomet, Inderal
This header specifies 2 signals each sampled at 360
Hz, each 650000 samples (slightly over 30 minutes) long. The starting time
and date were not recorded; in the example, the defaults are shown, but
they might be omitted without changing the meaning of the header file. Each
signal is stored in 12-bit bit-packed format (2 samples per 3 bytes; see
signal(5)
for details), and one file contains both signals. Since the filename
given (100.dat) does not include path information, WFDB library-based programs
will find the signal file only if it is located in one of the directories
specified by the WFDB environment variable. The gain for each signal was
the (default) 200 ADC units per millivolt (the default physical unit),
and the ADC had 11-bit resolution and an offset such that its output was
1024 ADC units given an input exactly in the middle of its range. The baseline
is not given explicitly, but may be assumed to be equal to the ADC zero
value of 1024. The first samples acquired had values of 995 and 1011 (i.e.,
both signals began slightly below 0 VDC). The checksums of the 650000 samples
are -22131 and 20052, and I/O may be performed in blocks of any desired
size (since the block size fields are zero). The signal descriptions specify
which leads were used (MLII: modified lead II). Finally, the last two lines
contain ‘info strings’. (In this example, the first info string specifies
the sex and age of the subject and data about the recording, and the second
lists the subject’s medications. The contents and format of info strings
vary between databases; it is not wise to rely on the presence of specific
data in info strings, since their use in header files is optional.)
- Example
2 (AHA DB record 7001):
- 7001 2 250 525000
/db1/data0/d0.7001 8 100 10 0 -53 -1279 0 ECG signal 0
/db1/data1/d1.7001 8 100 10 0 -69 15626 0 ECG signal 1
This header illustrates
how on-line AHA DB records were formerly kept at MIT. Note that the sampling
frequency and ADC specifications differ from the previous example. In this
example, each signal is kept in its own signal file, specified by its absolute
pathname. As shown here, AHA DB records may be kept in 8-bit first difference
format, but the sampling rate requires that the signals be scaled down
(from 12-bit to 10-bit ADC resolution) to stay within the slew rate limits
imposed by the format. Note that signal checksums (-1279 and 15626 in this
example) are derived from the reconstructed sample values, and not from
the first differences; thus they should not change if the signals are
reformatted.
- Example 3 (Local record 8l):
- 8l 16
data0 8
data1 8
...
data15 8
This example illustrates how relative pathnames can be used for
user-created records. If data* files in the proper format are created in
any of the directories named by the WFDB environment variable, they become
the signal files for record 8l.
- Example 4 (Piped record 16x4):
- # Piped record
16x4. Use this record to read or write 4 signals
# using the standard I/O.
16x4 4
- 16
- 16
- 16
- 16
This example illustrates several features not seen in the earlier examples.
The special file name ‘-’ means that samples will be read from the standard
input or written to the standard output when using this record. All four
signals are associated with the same file. The signals are kept in 16-bit
amplitude format. The example includes two comment lines, which are ignored
by the WFDB library functions that read header files.
- Example 5 ("ahatape"
header file):
- # Use this record on a UNIX system to read directly
# from a 9-track AHA DB distribution tape with
# 4096-byte blocks. The tape must be positioned
# to the beginning of the ECG data file before
# using this record.
ahatape 2 250
/dev/nrmt0 16 0 12 0 0 0 4096
/dev/nrmt0 16 0 12 0 0 0 4096
As in the previous example, both signals
are associated with the same file; in this case, the file is /dev/nrmt0,
the non-rewinding raw 9-track tape drive (on some systems, the name of this
device may differ). The block size must be specified in this case, since
I/O to or from a raw device (character special file) is not buffered by
the operating system and must be performed in the units appropriate to
the device (in this case, the tape block size). AHA DB tapes written at
1600 bpi contain 4096 bytes per block (i.e., 1024 two-byte samples from each
of the two signals).
- Example 6 ("multi" header file):
- multi/3 2 360 45000
100s 21600
null 1800
100s 21600
This header file is a sample of a multi-segment record. The first
line contains the record name ("multi"), the number of segments (there
are 3), the number of signals (2; this must be the same in each segment),
the sampling frequency (360), and the total length of the record in sample
intervals (45000; this must be the sum of the segment lengths).
The second
line contains the record name ("100s") of the first segment of the record,
and its length in sample intervals (21600). The third and fourth lines
contain the record names and lengths of the remaining segments. The remaining
lines are comments.
Note that a segment may appear more than once in a multi-segment
record, as in this sample, and that storage formats may vary between segments
(the second segment is a "null" record, containing format 0 "signals",
and the others are written in format 8).
This record may be read by any
WFDB application built using WFDB library version 9.1 or later; the application
need not be aware that this is a multi-segment record. Earlier versions
of the WFDB library do not support multi-segment records (or format 0 signals).
Versions 2.3 through 4.6 of the WFDB library included support for
reading header files written in an obsolete format. This support has been
removed from WFDB library version 5.0. Obsolete-format header files can be
brought up-to-date using revise (in the convert directory of the WFDB software
distribution).
annot(5)
, signal(5)
, wfdbcal(5)
WFDB Programmer’s Guide
George B. Moody (george@mit.edu)
Table of Contents
Up: WFDB Applications Guide
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