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Claims  |
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What is claimed is:
1. In combination, defibrillator for generating a polarization voltage
signal and an electrocardiographic monitor, said monitor comprising:
a first preamplifier for amplifying electrocardiographic signals received
at the first preamplifier, the first preamplifier having a dynamic range
corresponding to the amplitude of the polarization voltage signal that is
generated by the defibrillator;
a first high-pass filter to which the electrocardiographic signals
amplified by the preamplifier are supplied, the first high pass filter
having a predetermined cut-off frequency;
a second high-pass filter to which the electrocardiographic signals
amplified by the first preamplifier are supplied, the second high-pass
filter having a cut-off frequency that is higher than the cut-off
frequency of the first high-pass filter so that any portion of the
polarization voltage signal present within the electrocardiographic signal
is attenuated without erasing the electrocardiographic signals;
filter switching means for actuating the second high-pass filter for a time
period corresponding to the time period in which the polarization voltage
signal is generated by the defibrillator;
an electrocardiographic signal processing circuit for processing
electrocardiographic signals transmitted through one of the first high
pass filter and the first and second high-pass filters; and
output means for monitoring the electrocardiographic signals processed by
the electrocardiographic signal processing circuit.
2. A combination according to claim 1, wherein the second high-pass filter
is a high-pass filter having a third-order cut-off frequency of
approximately 0.6 Hz, the second high-pass filter further including at
least two RC circuits and a second preamplifier, the at least two RC
circuits being cascade-connected in two steps through the second
preamplifier to the first high-pass filter.
3. A combination according to claim 1, wherein the first and the second
high-pass filters include at least one digital filter, the at least one
digital filter including an A/D converter for converting an amplified
output signal from the first preamplifier into a digital form, and the A/D
converter is positioned at an anterior position relative to the digital
filter.
4. A combination according to claim 3, wherein the digital filter includes
an A/D converter and a differential amplifier, the A/D converter having a
dynamic range that is smaller than a dynamic range of the first
preamplifier and the differential amplifier including a first and a second
input terminal, the first input terminal of the differential amplifier
being electrically connected to the first preamplifier, and wherein the
differential amplifier is positioned at an anterior position relative to
the A/D converter, further comprising:
instantaneous processing means, the instantaneous processing means for
supplying a first subtraction signal corresponding to an output-signal
level of the A/D converter to the second input terminal of the
differential amplifier through a D/A converter during a time period in
which the polarization voltage signal is present to change the input
signal level of the A/D converter to within the dynamic range of the first
preamplifier;
window processing means, the window processing means for supplying a second
subtraction signal of an amplitude corresponding to a window width of the
D/A converter if the window processing means determines that the
input-signal level is outside of the window, wherein the second
subtraction signal is added to move the input-signal level of the A/D
converter to within the dynamic range of the first preamplifier after the
instantaneous processing means has supplied the first subtraction signal;
OR gate means, the OR gate means for inputting at least one of the first
and second subtraction signals from the window processing means and the
instantaneous processing means, respectively, and generating a subtraction
output signal; and
adding means, the adding means for adding the subtraction output signal
from the OR gate means to an output signal from the A/D converter to
generate an addition signal and outputting the addition signal to the at
least one digital filter. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a defibrillator with an
electrocardiographic monitor which displays and records
electrocardiographic signals, or performs data processing by amplifying
electrocardiographic signals induced at electrodes by means of a
preamplifier and then supplying the signals to an electrocardiographic
signal processing circuit through high-pass filters.
In such a defibrillator with an electrocardiogram monitor, when the
defibrillator is operated, a polarization voltage greater than an ordinary
signal level is generated between electrodes as a result of the
application of a high voltage. Therefore, an electrocardiograph is
provided with an instantaneous switch for grounding an output end of a
coupling capacitor which forms a high-pass filter when a high level
signal, as well as such polarization voltage, is instantaneously input at
the time of electrode switching or the like. This instantaneous switch
prevents the scale-over of an abnormally high level signal in an output
unit.
However, there are some cases in which the amplitude of the above-mentioned
polarization voltage at high voltage application time reaches
approximately .+-.300 mV and then gradually decreases in 10 seconds or
thereabouts. If the instantaneous switch is operated to prevent the
scale-over or the like, electrocardiographic signals are completely
vanished.
SUMMARY OF THE INVENTION
Accordingly, an object of the present invention is to provide a
defibrillator with an electrocardiographic monitor capable of detecting
electrocardiographic signals at near a base-line level immediately after
the defibrillator is operated.
To this end, according to the present invention, the dynamic range of a
preamplifier is made wider in accordance with the amplitude of a
polarization voltage which is generated when a defibrillator is operated.
A high-pass filter is formed of a first high-pass filter which operates in
a normal state and a second high-pass filter whose cut-off frequency is
higher than that of the first high-pass filter so that the polarization
voltage is attenuated without vanishing the electrocardiographic signals.
Filter switching means is provided for operating the second high-pass
filter in synchronization with the operation of the defibrillator during
the time period corresponding to the time period in which the polarization
voltage is generated.
According to the present invention, since the cut-off frequency of the
high-pass filter becomes temporarily higher when the defibrillator is
operated, it is possible to suppress an input of a polarization voltage
and very quickly control the vanishing time of the electrocardiographic
signals.
If two types of high-pass filters are formed of digital filters, it is
possible to switch filter characteristics at high speed and suppress
transient signal changes.
The above and further objects and novel features of the invention will more
fully appear from the following detailed description when the same is read
in connection with the accompanying drawings. It is to be expressly
understood, however, that the drawings are for the purpose of illustration
only and are not intended as a definition of the limits of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a view illustrating the circuitry of the main portion of a
defibrillator with an electrocardiographic monitor according to an
embodiment of the present invention;
FIGS. 2A-2D are a waveform chart illustrating the operation of the circuit
shown in FIG. 1;
FIG. 3 is a view illustrating the circuitry of the main portion of a
defibrillator with an electrocardiographic monitor according to another
embodiment of the present invention;
FIG. 4 is a view illustrating the circuitry of the main portion of a
defibrillator with an electrocardiographic monitor according to still
another embodiment of the present invention;
FIG. 5 is a flowchart showing the operation of the circuit according to the
embodiment shown in FIG. 4;
FIG. 6 is a view illustrating the operation of the circuit according to the
embodiment shown in FIG. 4; and
FIGS. 7A-7D are a view illustrating the operating waveforms of the circuit
according to the embodiment shown in FIG. 4.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 illustrates a defibrillator with an electrocardiographic monitor
according to an embodiment of the present invention. Reference numeral 1
denotes a preamplifier for amplifying electrocardiographic signals induced
at electrodes, which preamplifier has a dynamic range of .+-.500 mV in
proportion to a polarization voltage of approximately .+-.300 mV which
develops as a result of the application of a high voltage when a
defibrillator 6 is operated. Reference numeral 2 denotes a high-pass
filter having a time constant of 0.52 seconds, i.e., the cut-off frequency
is approximately 0.3 Hz. Reference numeral 3 denotes a high-pass filter
having a third-order cut-off frequency of approximately 0.6 Hz in which RC
circuits of the same time constant are cascade-connected in two steps to
the high-pass filter 2 through a preamplifier 3a. Reference numeral 4
denotes a filter switching circuit which operates the high-pass filter 3
for, for example, 10 seconds, which is the time period the polarization
voltage is generated, in synchronization with a trigger signal which
operates the defibrillator 6. Reference numeral 5 denotes an
electrocardiographic signal processing circuit for amplifying or
converting the electrocardiographic signals transmitted in an analog form
through such high-pass filter to a digital form and for performing data
processing, the result of the processing being displayed or recorded on an
output unit 7. Reference numeral 8 denotes an instantaneous switch similar
to a conventional instantaneous switch.
Electrocardiographic signals are input in a normal state to the
electrocardiographic signal processing circuit through the high-pass
filter 2. When a polarization voltage (FIG. 2A) of, for example,
approximately +300 mV develops in the preamplifier 1 when the
defibrillator 6 is operated, the voltage is amplified by the wide dynamic
range of the defibrillator 6 without being saturated. At this time, as a
result of the filter switching circuit 4 being operated in synchronization
with a trigger signal, the high-pass filter 3 is connected to the circuit
for 10 seconds. Electrocardiographic signals (indicated by the solid line
in FIG. 2B) in which the low-band components of the superimposed
polarization voltage are attenuated greatly are input to the
electrocardiographic signal processing circuit 5. During this time,
particularly the ST components with many low-band components, of the
electrocardiographic signals are slightly distorted as shown in FIG. 2D
from the normal state of FIG. 2C. However, the QRS waves are hardly
distorted and return to the normal state in 10 seconds.
If only the high-pass filter 2 is connected to the circuit 4 for 10 seconds
when the polarization voltage (FIG. 2A) develops, an input signal is as
indicated by the dotted line in FIG. 2B. The scale-over time in an output
unit, for example, in a recorder, becomes quite long. An excessive input
signal can be blocked by turning on the instantaneous switch 8 at an
electrode switching time or the like.
It is possible in the above-described embodiment to form the high-pass
filter 3 in various ways so that the filter 3 has a cut-off frequency
higher than that of the high-pass filter 2 even if CR circuits of the same
time constant are not used. Instead of forming the second high-pass filter
by the high-pass filters 2 and 3, they may be formed independently of each
other in such a way that they are connected parallelly so as to be
selectable.
FIG. 3 illustrates the circuitry of a defibrillator with an
electrocardiographic monitor according to another embodiment of the
present invention. An amplified output from the preamplifier 1 is
converted into a digital form by an A/D converter 10 having a dynamic
range of 20 bits, i.e., .+-.5.24 V at, for example, 10 .mu.mV/LSB, and
then supplied to a high-pass digital filter 11 employing a CPU. High pass
digital filter 11 includes a serial I/O port 11a, a CPU 11d, a ROM 11b and
a RAM 11c. Output signals from the filter are converted from the digital
form into the analog form by an electrocardiographic signal processing
circuit 12 or data-processed as they are in the form of digital signals.
Stored in the ROM 11b are a routine of a high-pass digital filtering
operation of a cut-off frequency of 0.3 Hz, which routine is to be
executed by the CPU 11d, and a program in which input signals stored in
the RAM 11c through the serial I/O port 11a are made to circulate the
above routine two times and then output. The use of digital filters in
this manner suppresses switching noise or transient signal changes at
switching time.
A high-pass digital filter may be formed in such a way that two types of
separate digital filters may be connected parallelly or serially so as to
be selectable.
FIG. 4 illustrates the circuitry of a defibrillator with an
electrocardiographic monitor according to still another embodiment of the
present invention. In this embodiment, an A/D converter 20 which has a
narrow dynamic range of .+-.5.12 mV at 10 .mu.m V/LSB. 10 bits in terms of
input conversion is used in place of the A/D converter 10. Added to the
defibrillator are a differential amplifier 21 whose amplified output is
supplied to one of the input terminals so that input signals from the A/D
converter are always moved to a window W having a width of 1.2 mV (.+-.0.6
mV) within the dynamic range. Instantaneous processing means 23 supply a
subtraction signal which decreases in a stepped manner to the other input
terminal of the differential amplifier 21 when the defibrillator is
operated, in accordance with the output signal level of the A/D converter
20 so that the input signal level outside of the dynamic range of the A/D
converter 20 is moved to the window W. Window processing means 24 supplies
a subtraction signal having an amplitude corresponding to the window width
to the other input terminal through the D/A converter 22 if the input
signal is outside of the window W so that the input-signal level of the
A/D converter 20 is set within the window W within the dynamic range after
the instantaneous processing means is operated. Adding means 26 add a
subtraction signal from the instantaneous processing means 23 or the
window processing means 24, which subtraction signal is supplied through
an OR gate 25, to an output signal from the A/D converter 20 in order to
restore the input signal and for supplying the signal to a digital filter
27 having first and second high-pass filtering functions which are
selectable.
The various above parts 23 to 27 can be realized by using the common CPU
11d in such a way that a program is added to the above-mentioned ROM 11b.
The instantaneous processing means 23 performs the operation shown in the
flowchart of FIG. 5. First, the polarity of the output signal from the A/D
converter 20 is checked. If it is a +signal, an input conversion operation
is performed by the A/D converter 20 as shown in FIG. 6, and a weighting
signal (+307.2 mV) at a 9th bit is output as a subtraction signal.
Determinations are made whether the input signal is present within the
window W and whether the input-signal level is greater or smaller than the
window W. If it is greater than the window W as shown in Table 1, the 9th
bit is entered, and a weighting signal (153.6 mV) at an 8th bit is added
and output. At this time, if the input-signal level is smaller than the
added output, it is not entered, and a weighting signal (76.8 mV) at a 7th
bit is added and output to the 9th bit. If, however, the input-signal
level is greater than the added output, it is entered. The addition signal
at the bit entered in this manner is formed to be a subtraction signal. A
subtraction/determination operation is performed up to the 0-th bit of
+0.6 mV, and the input signal is set within the window W having a width of
+0.6 mV. When the input-signal level is set within the window W while the
instantaneous processing is being performed, the instantaneous processing
is terminated.
TABLE 1
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9 8 7 6 5 4 3 2 1 0
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D/A 1 0 1 0 .fwdarw.
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In this way, the instantaneous processing is terminated in a required time
of, at most, approximately 20 ms. Thereafter, if the input-signal level is
greater than the window W having a width of 1.2 mV set within the dynamic
range of 12 mV of the A/D converter 10, a reduction signal of -0.6 mV is
added and the result is output. If the input-signal level is smaller than
the window W, +0.6 mV is added and output. Thus, the window operation for
ensuring that the A/D converter 20 is always operated within the dynamic
range is performed.
The operation of this embodiment will now be explained.
If, for example, a +polarization voltage (FIG. 7A) is input to the
preamplifier 1 when the defibrillator is operated, an output signal (FIG.
7B) saturated beyond the dynamic range is output from the A/D converter
20. At this time, the instantaneous processing is performed in
synchronization with the receiving of the trigger signal so that the input
signal is instantaneously set in the window W. Thereafter, if the
input-signal level is outside of the window W, a window processing for
performing a subtraction is performed. The input signal is always
converted from the analog form into the digital form within a dynamic
range of .+-.5.12 mV of the A/D converter 20. Output signals (FIG. 7B)
from the A/D converter 20 change in steps of 0.6 mV as a result of the
subtraction signal being decreased in units of +0.6 mV in a window
processing step for such input signals whose amplitudes decrease gradually
in the form of triangular waves. Therefore, the input signal (FIG. 7A) is
restored except in the instantaneous processing region (the time width is
enlarged in FIG. 7C) by the signal (FIG. 7C) produced by adding the output
signal to the subtraction signal and supplied to the digital filter 27.
As a result, a conversion operation by a 20-bit A/D converter is
equivalently performed by using a 10-bit A/D converter. In the normal
state in which the polarization voltage is vanished, if the
electrocardiographic signal level is outside of the window W, a follow-up
operation in 0.6 mV steps is performed. As a result of the subtraction
signal being added, normal electrocardiographic signals with the base line
as a reference are subjected to a filtering operation of a time constant
of 0.52 seconds and output. The electrocardiographic signal shown in FIG.
7D can be obtained by a filtering operation in which the cut-off frequency
is switched from 0.3 Hz to approximately 0.6 Hz for 10 seconds including
the instantaneous region.
In the above-described embodiment, the resolution of the A/D converter 20
can be increased in accordance with the amplification of the differential
amplifier 21 by interposing an amplifier between the A/D converter 20 and
the differential amplifier 21.
Many different embodiments of the present invention may be constructed
without departing from the spirit and scope of the present invention. It
should be understood that the present invention is not limited to the
specific embodiments described in this specification. To the contrary, the
present invention is intended to cover various modifications and
equivalent arrangements included with the spirit and scope of the claims.
The following claims are to be accorded the broadest interpretation, so as
to encompass all such modifications and equivalent structures and
functions.
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Description |
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