US3215136A - Electrocardiographic means - Google Patents

Description

Nov. 2, 1965 N. .LHOLTER ETAL 3,215,136

ELECTROCARDIOGRAPHIC MEANS Filed July 6, 1962 2 sheets-sheet 2 United States Patent Office 3,215,136 Patented Nov. 2, 1965 3,215,136 ELECTROCARDIOGRAPHIC MEANS Norman J. Holten' and Wilford R. Glasscock, Helena', Mont., assignors to The Halter Research Foundation, Inc., Helena, Mont., a corporation of Montana Filed July 6, 1962, Ser. No. 207,963 Claims. (Cl. 12S-2.06)

The present invention relates to means for processing electrocardiac signals and more particularly to means for obtaining large quantities of electrocardiac signals and to means for facilitating the processing and observing of large volumes of such signals in a short interval of time.

As is well known, there are electrical signals that circulate upon the surface of a persons skin as a result of the expansions and contractions of the cardiac muscle. These electrical signals are the so-called electrocardiac or EKG signals and have waveshapes that have many known relationships to the action of the cardiac muscle and to the condition thereof. By placing electrodes on the patients skin, these electrocardiac or EKG signals may be sensed and by employing a suitable cathode ray oscilloscope, electrocardiograph or similar device, the waveshapes of the EKG signals may be visually presented for viewing by a highly trained person such as an electrocardiologist. The electrocardiologist may then visually observe the electrocardiogram and endeavor to make a determination of the characteristics of the heart.

Although many heart disorders have been detected in this manner, it has been found that a failure to detect an abnormal EKG signal has not been an altogether reliable indication of a normal and healthy heart. During their early stages, some forms of disorders produce abnormal EKG signals at only random or infrequent intervals and/ or only when the patient is engaged in certain forms of activity. As a result, to obtain a record of such abnormal EKG signals, it is necessary to make EKG recordings that extend over protracted periods of time while the patient is engaged in a wide variety of activities. Since heretofore it has been necessary for the patient to be directly connected to the electrocardiograph as a practical matter, it has been extremely di'lcult if not irnpossible to accumulate EKG recordings over an extended period of time and especially while the patient is active during the period. Moreover, if such large volumes of recordings could be made, it would be impractical for a highly trained person, such as an electrocardiologist, to expend the excessive amounts of time required for carefully reviewing the recordings. It is also extremely difficult, if not impossible, for an operator to manually examine the large volume of data and accurately identify all abnormalities that are of a very random and infrequent nature. It may thus be seen that although electrocardiographs have been a very valuable research and clinical tool, they have not been entirely satisfactory as they are subject to numerous operating diculties that have limited their usefulness, particularly in routine check-ups for detecting aliments during their early stages.

It is now proposed to provide electrocardiographic means that will overcome the foregoing diculties. More particularly, it is proposed to provide electrocardiographic means that will permit the accumulation of large volumes of EKG signals from a patient even though he is engaged in virtually unlimited types of activities and that will permit the observing and analyzing of large volumes of EKG signals in short intervals of time, and will also insure a more accurate detecting and identifying of abnormal beats which may occur only infrequently and/or randomly during an extended recording period. After detecting and locating abnormal beats, the cardiologist may concentrate his entire attention on such individual beats, thereby making a more e'icient use of his skills. This is to be accomplished by providing electrocardiographic means wherein the EKG signals may be recorded by means of a small, compact recorder worn by the patient while he engages in any desired activity. The EKG signals may then be visually presented on a device such as a cathode ray oscilloscope for subsequent study. Although the recordings may be recorded in real time, over an extended time interval, they may be reproduced at a greatly accelerated rate. This will not only permit reproducing the EKG signals in a small fraction of the time required to accumulate them, but will also permit the waveforms to be superimposed upon one 4or more of the preceding waveforms.

,Since EKG signals are of a generally aperiodic nature, i.e., occur at random time intervals, heretofore it has been impossible to cause the signals to provide a visual display wherein the waveform will remain stationary. It is, therefore, also proposed to provide means for triggering the display means from a predetermined portion of the signal so that the display of the waveform may be made to remain stationary. In one form of the present electrocardiac means, the reproduction portion includes means that are effective to produce a pair of EKG signals wherein one of the signals is delayed from the other. This will permit triggering the display means from the earlier of the signals whereby the display means will include any desired amount of the waveform of the EKG waveform and at least the important portons of the Waveform will remain stationary.

It may thus be seen that the entire waveforms of succeeding EKG may be superimposed on each other. As long as the EKG signals are all substantially identical, the display pattern will be substantially steady. However, in the event of the presence of one or more Vabnormal EKG signals, the display pattern will include an erratic portion that differs from the steady Waveform portion and will appear as an abrupt and perceptible change in the pattern. As a result, an observer may review large volumes of EKG signals in a much shorter time than has heretofore been possible and may readily observe the presence of even random and erratic beats. In addition, means may also be provided which will simultaneously, audibly reproduce a sound which corresponds to the EKG signal. In the event of an abnormal EKG signal, the sound will have a corresponding variation.` Thus, the operator may simutaneously audibly and visually perceive any abnormalities.

Although it has been possible to determine the average pulse rate over an extended period of time due to the aperiodic or random nature of the pulse rate, it has been extremely difficult if not impossible to determine the instantaneous pulse rate or fluctuations in the rhythm thereof. It is, therefore, also proposed to provide means that will sense the time interval between successive heart beats and will be effective to produce a visual display of the time intervals. This display will thus provide a continuous indication of the instantaneous pulse rate and fluctuations in the rhythm thereof.

These and other features and advantages and objects of the present invention will become readily apparent from the following detail description of one form of the present invention particularly when taken in connection with the accompanying drawings wherein like reference numerals refer to like parts, and wherein:

FIGURE l is a block diagram of a recording portion of electrocardiographic means embodying one form of the present invention;

FIGURE 2 is a block diagram of a reproducing portion of electrocardiographic means embodying another form of the present invention;

FIGURE 3 is a view of one of the visual display pat- .materially interfering with his actions.

yportion of FIGURE 2.

Referring to the drawings in more detail, the present invention is embodied in electrocardiographic means It) for obtaining electrocardiac or EKG signals and displaying them for observation. In the present instance this means includes arecording portion 12 for receiving and recording EKG signals and a reproduction 14 for 'reproducing the recorded EKG signals and producing a visual and audio reproduction of the signals.

Therecording portion 12 of the electrocardiographic means which is shown in FIGURE 1 is preferably a substantially conventional tape recorder for recording signals on amagnetic tape 16. However, it is preferably a selfcontained unit having its own power supply so as to be capable of operating for extended periods vof time. In addition, the tape lrecorder is also preferably miniaturized to be sufficiently small to be worn by a patient without As a result, it will be possible for the patient to indulge in a wide variety of activities while his EKG is being recorded on the tape .16. For example, the EKG signals recorded may be those produced while the patient engages in his normal day-to-day living or, if desired, they may be those produced as a result of the patient engaging in certain prescribed exercises designed to reveal predetermined characteristics of the heart. n

The input to therecorder 12 includes an amplifier I8 which may be of conventional design for receiving EKG signals and amplifying them to a more useful level. The input of the amplifier 18 may include one or more electrical conductors for being electrically connected to one or more electrodes for being secured to the patient. The electrodes may be disposed in any suitable location on the patients skin such, for example, as the so-called unipolar position.

Although the various characteristics of EKG signals obtained in the foregoing manner may vary throughout a wide range, as a general rule in a normal or healthy person the EKG signal will have a waveform that includes, in the following sequence, a P wave, a QRS complex, a T wave that is Aseparated from the QRS complex by an ST segment. Although there maybe several additional waves present in a normal EKG signal, since they will have little or no affect on the operation of the present invention, for purposes of simplicity, the present descripvtion will be conned to a waveform of this nature.

The P wave is normally a small, positive pulse that corresponds to the initial impulse that triggers. the coinmencement of .the heartbeat. Shortly after the P wave, there is a quiescent or isoelectric portion of substantially Auniform amplitude .which separates the P wave from the QRS complex. The QRS complex is substantially coincident with the actual expansion and contraction of the cardiac muscle producing the actual pumping action. This complex commences and terminates with the Socalled Q and S waves, respectively. These waves are generally relatively small negative pulses, and are separated from each other by the intervening R wave. The R wave, which is the most conspicuous .portion of the EKG signal has the appearance of a positive spike with a sharp rise and fall and a relatively short duration, normally on the order of up to 0.03 to 0.04 seconds.

Following the QRS complex, there will usually be a T wave which is separated from the S Wave by the socalled ST segment. The T wave represents the end of the beat and is usually followed 'by a substantially quiescent signal. This quiescent condition will continue to exist until the following EKG signals -occurs as indicated by the commencement of the succeeding P wave.

As previously stated, the input 20 of the amplifier 13Y may be connected directly with the pick-up electrodes y be substantially identical.

by one or more conductors.

However, if desired, it may be indirectly connected with the electrodes by means of a telemetry system wherein a radio transmitter worn. by the patient is connected with the electrodes so as to radiate a signal containing the EKG signal and a radio receiver receives the radiated signals and feeds the EKG signal to the input 20 of the amplier 18.

The amplier 18 may be of any conventional design provided it has a substantially uniform amount of gain over an adequate bandwidth to eifectively amplify all of the components in the EKG signal without any distortions thereof. The signal at the output 22 from the amplier 18 will thus be a faithful reproduction of the EKG signal but of increased amplitude.

The output 22 from the amplifier 18 may 'be connected with one of theinputs 24 to a mixer 26. The mixer 26 be of a conventional variety such as is employed in tape recording devices. The mixer 26 is effective to mix the EKG signal on theinput 24 with the signal on asecond input 28. Thesecond input 28 may be connected to a bias oscillator 30 which may be of a variety commonly employed in tape recorders. It may thus be seen that the signal on theoutput 32 of the mixer 26 will be an EKG signal suitable for recording directly onto themagnetic tape 16.

Theoutput 32 is electrically connected to a pair of recording heads 34 and 36. Theseheads 34 and 36 may be substantially identical to each other and connected in series so that identical signals will ow through each. Theheads 34 and 36 are particularly adapted to have the magnetic tape pass therethrough so that each head may separately record signals on separate laterally displaced tracks extending axially along thetape 16.

Themagnet tape 16 may have a portion wound upon asupply reel 38 and a portion wound on a take-up reel 4t) so that the portion therebetween may be disposed in theheads 34 and 36. Driving means may be operatively connected to one or both of thereels 38 and 40 so as to drive the tape through theheads 34 and 36. In order to obtain a substantially constant tape velocity through the heads, it has been found desirable to employ asynchronous motor 42 that is controlled by a substantially c-onstant frequency oscillator 44.

In order to permit recording of large volumes of EKG signals over extended periods of time and to facilitate the subsequent reproducing the EKG signals at an accelerated rate, it is desirable for the tape speed during recording to be slow. Although the tape speed may be any desired amount, by way of example, it has been found that a speed on the order of 71/2 inches per minute will permit a faithful recording of the EKG and will .permit recording over extended time intervals on a short length of tape. However, the tape speed may be faster or slower if so desired.

As previously stated, the .two recording heads 34 and 36 are physically laterally displaced so that they will record on separate tracks and they are electrically interconnected so that the recordings on the two tracks will As will subsequently become apparent, it is also desirable for the twoheads 34 and 36 to be staggered or displaced longitudinally of the `tape 16. The recording in the two tracks will thus be 'displaced from each other by .an amount corresponding to lthe spacing between the heads. By way of example, in one -operative embodiment, the two tracks were displaced from each other by a distance of approximately ll/z inches.

The reproduction portion 14 of the electrocardiac means 10 is preferably a separate unit from therecording portion 72. It may be larger and heavier so as to be suitable for use in a doctors otiice or in a laboratory. The reproduction portion 14 includes a substantially conventional .tape deck 40 having asupply reel 42 .and a take-up reel 44 with thetape 16 extending therebetween. Amotor 46 is interconnected with one or both Qf the reels.

. so as to drive thetape 16 therebetween.

Although the speed of thetape 16 may be any desired amount, it has been desirable to employ a drive mechanism and/or motor that will cause the speed of thetape 16 to be equal to the recording speed for example 71/2 inches per minute' and a higher speed. The high speed is preferably a standard tape speed such as 71/2 inches per second as this will permit thetape deck 40 and transport mechanism to be of substantially conventional design. If the recording speed is on the order of 71/2 inches per minute and the playback speed is on the order of 71/2 inches per second, this will produce a change in speed of approximately 60 to 1. As a result, one minute of playback time will represent sixty minutes or one hour of recording time and twenty-four hours of real time recordings may be reproduced in twenty-four minutes. As a result, this will make it practical to review large volumes of recordings in a relatively short time interval. It should be noted that if it is so desired, the speed ratios may be larger or small so as to reduce or increase the reproducing time. A pair of playback heads 48 and 50 may be provided for scanning thetape 16 as it passes therethrough.

Thefirst head 48 may act as a trigger head and is operatively interconnected with ahorizontal trigger branch 52 for actuating the horizontal sweep circuits in a cathode ray oscilloscope 54. Thesecond head 50 may act as a signal head and is operatively interconnected with a vertical branch 56 for actuating the vertical sweep circuits of the cathode ray oscilloscope 54.

Theseheads 48 and 50 are displaced laterally to scan only one of the two recorded tracks. In addition, the two heads are staggered axially of thetape 16 so that the recorded EKG signal on one track will pass through the first head 48 a predetermined time interval before theother head 50. As a result, the signal in thehead 50 will be delayed from the signal in thehead 48 by a predetermined time interval. One or both of the heads may be adjustable longitudinally of thetape 16 so as to vary the amount of this time delay.

Thesignal head 50 is interconnected with the vertical deflection branch 56 by means of a reversing switch 58. This reversing switch 58 may be movable between a first set of fixed contacts and a second set of fixed contacts so as to effectively reverse the polarity of the signal produced by thehead 50. The movable contact in the switch 58 is operatively interconnected with the input to asignal preamplifier 60.

Thepreamplifier 60 may be of conventional design for increasing the amplitude of the signal to a more useful level. It should be noted that since the signal reproduced by thehead 50 is a function of the magnetic recordings travelling past the head, the signal fed into and through thepreamplifier 60 will be a derivative of the original recorded EKG signal. Accordingly, the output from thepreamplifier 60 may be interconnected with a compensatingamplifier 62. Thisamplifier 62 in addition to further amplifying the signal may include compensating or integrating means for effectively restoring the signal to its original EKG waveshape. Theoutput 64 from the compensatingamplifier 62 may be connected to one of the fixed contacts in aselector switch 66.

If so desired, a non-compensating amplifier 68 may also be provided. This amplifier 68 is interconnected with the output of thesignal preamplifier 60 so as to receive the derivative signal. The non-compensating amplifier 68 may be free of any integrating characteristics. As a result, the signals from theamplifiers 62 and 68 will be of equivalent amplitude, but the signal from the amplifier 68 will still be the differentiated signal. The output 70 of the compensating amplifier 68 may be interconnected with a second fixed contact in theselector switch 66.

The movable contacts in theswitch 66 may be interconnected With the input to anaudio amplifier 71 which will be effective tol amplify the signal supplied thereto and drive a louds-peaker 72. Theloudspeaker 72 will thus be effective to produce an audible signal which will correspond to the EKG signal or the first derivative thereof depending upon the setting of theselector switch 66. In the event that the playback speed is on the order of 60 times the recording speed, and the original pulse rate was on the order of 60-15O beats per minute, the fundamental frequency of the audio signal will be on the order of 60-150 cycles per second. Thus, the audible signai will have the characteristics of a low frequency growl. If the successive EKG signals are substantially identical and occur at a substantially constant rate, this growl will have a correspondingly uniform characteristic. However, in the event there are any irregularities in the EKG signals, there will be a corresponding variation in the audible signal. As a result, the operator will very quickly perceive that a change has occurred.

In addition, the movable contact in theswitch 66 is operatively interconnected with one side of adifferential amplifier 74. Thisamplifier 74 may be' of a conventionall design and' is effective to amplify only the difference between the signals on the opposite sides of the amplifier. The opposite side of theamplifier 74 may be interconnected with a variable reference 'bias source 76. Thissource 76 will be effective to supply a D.C. bias signal for maintaining one side of theamplifier 74 at `a desired level. Since thedifferential amplifier 74 will be effective to amplify only the difference between the EKG signal on the one side and the reference bias on the opposite side, varying the reference bias will be effective to vary the D.C. level of the output signal without in any way varying the configuration or waveform of the signal.

The output of theamplifier 74 may be operatively p interconnected with theinput 78 to the vertical deflection circuitry of a suitable display device such as the cathode ray oscilloscope 54. The electron beam in the oscilioscope 54 will thus be deflected vertically in response to the signal from theamplifier 74. In addition, the vertical position or D.C. level of the signai may be varied by adjustment of thereference bias source 76.

The second or trigger head is operatively interconnected with thehorizontal branch 52 by means of a reversing switch 80. This switch 80 may be substantially identical to the first reversing switch 58. The switch includes movable contacts that may be positioned to engage a first set of fixed contacts or a second set of fixed contacts so that the polarity of the signal on the movable ycontacts may be reversed.

The movable contact in the switch 801 may be interconnected with the input to atrigger preamplifier 82. Thisamplifier 82 may be substantially identical to theamplifier 60 and is effective to amplify the signal from theplayback head 48 to a more useful level. Theamplifier 82 is preferably free of any form of compensating or integrating circuitry so that the signal in theoutput 84 of theamplifier 82 will be a derivative of the EKG signal as originally recorded on thetape 16.

More particularly, the signal in theoutput 84 is shown at A. If the switch 80 is set to feed a positive signal to theamplifier 82, normally, the derivative signal will include a large positive pulse corresponding to the beginning of the R wave. This results from the rapidly rising l'eading edge of the R wave. This will be followed immediately by a large negative pulse. This pulse results from' the rapidly falling trailing edge of the R wave. It may thus be seen that the negative pulse is coincident with the termination of the R wave and beginning of the S wave.

If desired, a Calibrating switch may be connected to the input of thepreamplifier 82 for operatively interconnecting the amplifier with a source of 60 cycles. In the event the reproduction portion 14 operates 60 times the speed of the original recording, a 60 cycle calibrating signal will correspond to a pulse Vrate of 60 beats per minute and will thus provide a known reference for Achecking the ele-ctrocardiac means 10.

Theoutput 84 from thetrigger preamplifier 82 is interconnected with the input to aclipper circuit 86 so as to feed the derivative signal A thereto. Thisclipper circuit 86 may lbe of a substantially standard variety for suppressing or clipping all negative portions of a signal. As a result, the signal on theoutput 88 will be only a positive pulse such as shown at B. It may thus be seen that with the switch 80 in the position shown, the signal B in theoutput 88 from theclipper circuit 86 will be a positive pulse corresponding to the commencement of the R wave. However, if desired, the switch 80 may be reversed to invert the signal A on theoutput 84 from thetrigger preamplifier 82. The positive portion of the derivative signal A will then correspond to the trailing edge of the R wave and the signal B from theclipper circuit 86 will be -a positive pulse substantially coincident with the termination of the R wave and/ or the beginning of the S wave.

Theoutput 88 of theclipper circuit 86 may be connected to the input of amultivibrator 90. Thismultivibrator 90 may be of the one-shot variety. That is, each time a triggering signal such as a positive pulse is applied to the input thereof, themultivibrator 90 will change its state for a predetermined time interval. The duration of the time interval will, of course, be determined by the various characteristics such as the time constants of the circuit. In the present instance, a variable capacitance 92 may be included in t-he multivibrator 90 so that the time constant may be varied throughout a predetermined range. It will thus be seen that the output signal C from themultivibrator 90 will be a positive squarewave having a time duration determined by the setting of the capacitance 92.

The output from themultivibrator 90 may be operatively interconnected with the input to adifferentiator 94. Thedifferentiator 94 is effective to differentiate the squarewave pulse C fromIthe multivibrator 90 and produce a positive pulse and a negative pulse -corresponding to the commencement and termination of the squarewave. However, the positive pulse is clipped or otherwise suppressed so that only the negative pulse D will remain. The timing of this pulse will correspond to the termination of the squarewave C. Accordingly, the pulse D will be delayed behind the positive portion of the derivative signal A by the duration of squarewave C.

This negative pulse D from thedifferentiator 94 may be -fed into va saw-tooth generator 96. The potential of the'output 98 of the saw-tooth generator will gradually increase at a substantially uniform rate once the generator is triggered by the pulse D. This pulse will reset thegenerator 96 to zero and cause a new saw-tooth waveform to build up at a substantially uniform rate. This build-up will be yfree to continue until a succeeding pulse is applied to the input thereof at which time the potential will return to zero and start to repeat the build-up. It may be seen that the maximum amplitude of the saw-tooth will correspond to the length of time that the Waveform is permitted to build up. Thus, the amplitude of each saw-tooth will be proportional to the time between the successive pulses D applied thereto. Theoutput 98 of thegenerator 96 may be interconnected with a fixed contact in a selector Switch 100'.

In addition, a second saw-tooth generator 102 may be operatively interconnected with a second fixed contact in theselectorv switch 100 for supplying a series of saw-tooth waveforms thereto. This generator 102l is preferably of the free-running variety. As a result, the period of the saw-tooth waves w-ill be substantially constant. Although the period may be any desired amount, it is preferably several times as long as the real time interval between the EKG signals as recorded from the patient. By way of example, the period may be on the order of an interval of approximately 21/2 seconds.

The movable contact in theselector switch 100 is operatively interconnected with one side of adifferential amplifier 104. Although this amplifier may be of any suitable design, in the present instance it is substantially identical to the firstdifferential amplifier 74. That is, it is effective to amplify only the difference between the two sides. The second side of theamplifier 104 may be operatively interconnected with an adjustablereference bias source 106. Thesource 106 will permit manual adjustment of the D.C. level in the output of the second side. Since the output signal will represent the difference between the saw-tooth and the reference -bias 106, the output signal will include a D C. component that may be varied without affecting the shape of the saw-tooth wave.

Theoutput 108 of thedifferential amplifier 104 may be interconnected to the horizontal deiiection system of the cathode ray oscilloscope 54. The saw-tooth potential on theoutput 108 will thus cause the electron beam to be swept across the face of the oscilloscope 54 at a substantially uniform rate. It should be noted that since thegenerator 96 will be triggered from the trailing edge of the squarewave'pulse, the horizont-al sweep will be synchronized with either the commencement of the R wave or the S wave, depending upon the setting of switch 80, but will be delayed therefrom by the duration of the pulse C from themultivibrator 90. Accordingly, the cornmencement of the horizontal sweep in the oscilloscope 54 will be coordinated with a particular portion of the signal from thesignal reproduction head 50 even though the signal is of an aperiodic or random nature.

In addition, if it is so desired, lasecond oscilloscope 108 may be provided. The horizontal sweep circuitry of thisoscilloscope 108 preferably is effective to require an extended period 0f time. Por example, the horizontal circuitry may be connected to the output of the free-running saw-tooth generator 102. This will require 2 or 3 seconds to complete a sweep and, during this time, one hundred or more EKG signals will be reproduced.

The vertical deflection circuitry may be interconnected to the output side of thedifferential amplifier 104. As will ybe remembered, the output signal fromamplifier 104 will be la saw-tooth waveform that has a peak amplitude which is proportional to the time between each EKG signal.

As a result, it may be seen that the display pattern on the face of theoscilloscope 108 will be similar to FIGURE 4 and will consist of a plurality of substantially vertical lines. T-he oscilloscope preferably includes a memory such as a long persistence screen whereby a large number of lines will always remain on the screen. The height of each line -will correspond to the instant avenues pulse rate and uniformity of the upper edge of the pattern will indicate the rhythm.

In order to employ the present electrocardiac means 10, therecording unit 12 may be interconnected with electrodes attached to the'patient and placed on the patient in an operative condition. If therecording unit 12 is sufficiently miniaturized it will not materially interfere with the normal activities of a patient. As a result, the patient may engage in certain preselected activities or exercises that are specifically designed to reveal certain characteristics of the EKG signal. Or, if desired, the patient may carry` on -his normal daily routine so as to determine the ability of the Iheart to withstand such a routine. Because of the large capacity of the recorder and the rapid processing of the EKG signals, it will now he practical to accumulate recordings of the patients EKG over extended periods of time. Thus, even if t-he patient has only random and infrequent abnormal beats or has abnormal beats that occur only during particular types of activities, a sufficient volume of recordings may be obtained to permit a reasonably accurate determination of the patients cardiac condition.

Once an adequate volume of recordings has been made under the desired circumstances, t-he recordingunit 12 may ibe removed `from the patient and the reel of recordedtape 16 may be placed in the reproduction portion 14. Thetape 16 will then -be stripped olf of thesupply reel 42, drawn through the playback heads 48 and 50 and wound onto the take-up reel 44. Although the speed at which thetape 16 travels throughthe heads 48 and 50 may be any desired amount, it has `been found desirable to employ a relative standard speed such as 'Z1/2 inches per second. This speed will permit the use of a substantially standard tape deck. In addition, it will permit the :use of a tape speed of 71/2, inches per minute to be used in therecording unit 12 whereby the playback time will be sixty times shorter than the recordingtime. Thus, one second of playback time will represent one minute of real time recording and one minute of playback will represent one hour of recording. As a result, t-he EKG recordings for an entire twenty-four hour day may be reproduced in a period of only twenty-four minutes. This will now make lthe reviewing of an entire days EKG economically feasible.

As thetape 16 travels through the twoheads 48 and 50, the EKG signal on the leading track will pass through thetrigger head 48 rst. T-he signal from thetrigger head 48 will be amplified in and pass through thetrigger preamplifier 82. Since thisampli'er 82 does not include any form of compensating or integrating circuitry, the signal A at theoutput 84 will be a signal that corresponds to the derivative of the original EKG. Its primary characteristic of this signal will be rst a sharp positive pulse, if switch 80 is in the position shown. This pulse corresponds to the beginning of the R wave. Secondly, there will be a sharp negative pulse corresponding to the ending of the R wave. rThis derivative signal will then pass through theclipper 86 and the negative pulse will be eliminated. Theoutput 88 will thus include only a positive pulse such as signal B. The time of this pulse will correspond to the .beginning of the R wave unless the switch 80 is reversed in which case it will correspond timewise to the S wave. This pulse B will then trigger themultivibrator 90 and produce the squarewave pulse C. This pulse C will have a predetermined time duration regulated by the setting of the time control 92.

The pulse C from themultivibrator 90 will be fed into thedifferentiator 94. Thedifferentiator 94 will be effective to produce a negative pulse D corresponding to the ending of the pulse C. This negative pulse will then be fed into the input of the saw-tooth generator 96 so as to cause it to gradually increase the saw-tooth wave. This saw-tooth wave will then be fed into thedifferential amplifier 104. As t-he potential of the saw-tooth wave changes about the reference level set by thebias source 106, the output potential will produce a corresponding change. This saw-tooth wave will then pass into the horizontal deection circuitry of the oscilloscope 54 and cause the electron beam to be horizontally swept across the tube at a substantially uniform velocity.

At the same time that the beam is being swept horizontally across the face of the oscilloscope tube, a signal from thesignal head 50 will feed a signal into the vertical branch 56. This signal will Ibe amplified in theamplifiers 60 and 62 and converted into a form substantially identical to the original EKG. Assuming theselector switch 66 is positioned as shown, thedifferential amplifier 74 will then feed the EKG signal to the oscilloscope S4 and cause the electron beam therein to be deflected vertically. .'Ihe inter-action of the vertical and horizontal deflections of the beam will be effective to cause a trace or oscillogram to be visually displayed on the face of the oscilloscope that corresponds to the waveform of the EKG.

It should be noted that the horizontal sweep will be triggered as a result of the R wave portion of the EKG signal on the trigger track passing through thetrigger head 48. However, the commencement of the sweep will be delayed from the instant the R wave passes through the head by the time duration of the squarewave pulse C from t-he multivibrator 90. Since the recordings in the trigger track lead those in the signal track by a distance corresponding to the spacing between the recording heads 34 and 36 by properly positionin-g the playback heads 48 l@ and S0, the R wave portion of the signal may pass through thetrigger head 48 prior to the time the corresponding signal Vbegins to pass through thesignal head 50. It rnay thus be seen that prior to the beginning of an EKG signal in the vertical branch 56, thehorizontal branch 52 will be triggered. The length of this time will 'be determined by the displacement between the two recording tracks and the relative displacement of the two` heads 48 and 50 and the duration of the pulse C. Thus, the horizontal sweep can be made to commence just prior to the beginning of each EKG signal.

Normally, the control 92 will be set such that the horizontal sweep will commence just prior to the P wave. As .a result, each of the EKG waveforms displayed on the oscilloscope will commence at substantiall-y the same point in the waveform. Thus, all of the waveforms will be synchronized with each other even though the sign-als are aperiodic or of a random nature. -As may be seen from the display pattern shown in FIGURE 3, the wavef-onm of each EKG signal will be superimposed over the preceding waveform. Since the EKG signals will be created at a rate on the order of at least 60 per second, the persistence -of the oscilloscope tube .and the opera-tors vision will cause the waveforms to blend into a somewhat broad but well-.defined pat-tern. In the event all of the EKG signals have waveforms that are substantially identical, the display pattern will show substantially the same waveform. It may then be determined by lobserving the pattern and general characteristics of the EKG waveform. However, in the event there are a few random or erratic EKG signals Khaving waveforms differingy from the remaining signals, they will produce a :corresponding variation in the display pattern and simultaneously a change in the audible signal from theloudspeaker 72.

More particularly, assuming that practically all of t'he EKG signals are normal, `they will produce a broad pattern such :as thepattern 110 of FIGURE 3. vUpon the yoccurrence of an ectopic beat and/ or ST segment depression, the electron beam will be deflected outside of the normal pattern and produce anindividual trace 112. Althrough the persistence of thisindividual trace 112 may be too short for the operator to study the details thereof, he will be immediately aware of its existence :and the approximate time thereof. If so desired, the appropriate porti-on of thetape 116 may be re-played at its original recording speed, 7%. inches per minute in the present eX- ample, yand the switch y may be set to cause the freerunning saw-tooth generator 102 to supply the horizon-tal sweep signals. Since the EKG signals will now be reproduced `at their original rate and it will take several seconds, for example 21/2 seconds, for a horizontal sweep to be made, several EKG waveforms will be displayed on the face of the oscilloscope. In addition, they will be created .at a suiciently slow rate t-o permit studying each individual waveform. Thus, each abnormal EKG waveform may be located and identified and, if desire-d, unay 'be permanently recorded, for example, by photographing the display pattern while the waveform or waveforms are present thereon.

While the reproducing portion 14 is running at 71/2 inches per second, theoscilloscope 108 will be producing a display pattern such as sh-own in lFIGURE 4. This display .pattern will include a large number of substantially vertical lines with the lengt-h of each line corresponding to the peak amplitude of the saw-tooth wave from .thegenerator 96. Since this is dependent upon .the time interval between each beat, the lines will 'be a function of the instantaneous pulse rate. Thus, if the pulse rate is uniform and regula-r and fast, the pattern will have Ian appearance of thesection 114. As the pulse rate slows down, the lines will lengthen such as insection 116. In the event the heart skips a beat, there will be a conspicuously long line such as 118, or if it provides a double beat, it will produce an equally consp-icousshort line 120.

It Vmay thus be seen that electrocardiac means have been provided that now permit the accumulation of large volumes of EKG signals under virtually any desired `type of operating -condition and that also permit observing and accurately analyzing all of the accumulated EKG signals. Although only a single embodiment of the present invention has been disclosed and described herein, it will be readily apparent to persons skilled in the fart that numerous changes and modifications may 'be made thereto without departing from the spirit there-of. Accordingly, the foregoing disclosure and description are for illustrative purposes only and do not limit the invention which is defined only =by the claims that follow.

What is claimed is:

1. Apparatus for visually displaying waveforms of signals magnetically recorded on a tape, said apparatus in- -cluding the combination of:

a first playback head for scanning 4a track on said tape containing said magnetic recordings and producing trigger signals in Iresponse to :said recordings,

a second playback head for scanning a track containing said magnetic recordings and producing a signal in response thereto, said heads being positioned relative to each other so that said trigger signal-s occur predetermined time intervals before corresponding portions of said signals from said second Ihead,

display means interconnected with said second playback head to receive the second reproduced .signals therefrom, said display means in-clud-ing a display area .and being responsive 'to the second reproduced signal from said second head for producing visual displays of the waveforms on said display area, and

sweep means in said display means for sweeping across :sa-id display area and being interconnected with said first playback head for receiving said trigger signals, said sweep means bein-g responsive to the trigger signals for synchronizing said display means in response to said ltrigger signals to initiate a new sweep across s-aid display .area to produce .a visual display of the second reproduced signal.

2. Apparatus f-or visually displaying waveforms of aperiodically occurring signals magnetically .recorded lon ,a tape and having similar waveforms with a tri-gger portion, said apparatus including the combination of:

a first playback head for scanning a track on said tape containing magnetic recordings of said signals, said head being responsive to said trigger portion to provide an :aperiodic trigger signal in response to the 1passage of each of said trigger portions through said ead,

a second playback head for scanning a track containing magnetic recordings of said aperiodic signals and producing an aperiodic Vsi-gnal in response thereto, said heads being separated by a predetermined distance so that said trigger signal-s occur predetermined fixed time intervals before the corresponding reproduced aperiodic signal from said sec-ond head,

display means interconnected with said second playback head and .responsive to each of the second reproduced signals therefrom, said display means including a visual display area for presenting a display of a waveform, and

sweep means in said display means for repeatedly scanning across said display ar-ea at a uniform rate and repeatedly ygenerating visual displays of the waveforms of each of said -signals from said second lhead, said sweep means being interconnected with said first playback head f-or receiving the trigger .signals therefrom and being responsive to said trigger signal-s yto .aperiodically init-iate and synchronize a new sweep across said display area each time -a trigger signal occurs.

3. Means for visually displaying waveforms of signals magnetically recorded on a tape, said means comprising the combination of a first playback head for scanning a track on said tape containing said magnetic recordings and producing trigger signals in response to said recordings,

a second playback head for scanning a track containing said magnetic recordings and producing a signal in response thereto, said heads being positioned relative to each other so that said trigger signal occurs a predetermined time interval before at least a portion of said signal from said second head,

a cathode ray oscilloscope,

means operatively interconnected with said second playback head for deflecting the electron beam in said oscilloscope in a vertical direction in response to the amplitudes of the signals from said second head, Y

means for simultaneosuly sweeping said beam horizontally to scan said beam at a substantially uniform rate, and

means operatively interconnected with said sweep means and said first playback head, said means being responsive to said trigger signal for starting said horizontal sweep in predetermined fixed time relations to each of said signals from said second head.

4. Apparatus for visually displaying waveforms of signals magnetically recorded on a tape, said apparatus comprising the combination of:

a first playback head for scanning a first track on said tape containing said magnetic recordings of said first signal and producing trigger signals in response to said recordings,

a second playback head for scanning a second track laterally displaced from said first track and containing magnetic recordings of said first signal and producing a final signal in response thereto, said' heads being positioned longitudinally of said tape relative to each other so that each of said trigger signals occur a predetermined time interval before the corresponding nal signal,

display means interconnected with said second playback head to receive the final signals therefrom, said display means including a display area and being responsive to the final signal for producing visual displays of the waveforms thereof, on said display area, and

sweep means in said display means for sweeping across said display area and being interconnected with said first playback head for receiving said trigger signals, said sweep means -being responsive to said trigger signal for synchronizing said sweep means to initiate a new sweep across said display area to produce visual displays of the final signals.

5. Apparatus for visually displaying waveforms of electrocardiac signals magnetically recorded on a tape, said apparatus including the combination of:

a first playback head for scanning a track on said tape containing said magnetic recordings of said signal and producing a signal that is a derivative of said electrocardiac signal,

a second playback head for scanning a track containing said magnetic recordings of said electrocardiac signal and producing a signal in response thereto, said heads being positioned longitudinally of said tape relative to each other so that said derivative signal occurs a predetermined time interval before corresponding portions of said signal from said second head,

display means interconnected with said second playback head to receivethe signal from said head, said display means including a display area and being responsive to said signals from said second head for producing visual displays on said area of the waveform of said signal, and

sweep means in said display means for sweeping across said display area and repeatedly generating visual displays of the waveforms of each of said signals from said second head, said sweep means being interconnected with said first head for receiving the signal therefrom and being responsive to said derivai3 tive signal from said first head to synchronize said sweep means to initiate a new sweep across said display area to superimpose the displays of the successive electrocardiac signals.

6. Apparatus for Visually displaying waveforms of electrocardiac signals magnetically recorded on a tape, said apparatus including the combination of:

a first playback head for scanning a track on said tape containing said magnetic recordings of said signal and producinga signal that is a derivative of said electrocardiac signals,

a second playback head for scanning a track containing said magnetic recordings of said electrocardiac signal and producing a signal in response thereto, said heads being so positioned longitudinally of said tape relative to each other that each of said derivative signals occurs a predetermined time interval before a corresponding signal from said second head,

a cathode ray oscilloscope,

vertical deflection means in said oscilloscope interconnected with said second playback head and responsive to the signal from said head for deiiecting the electron beam in said oscilloscope in a vertical direction in response to the amplitudes of the signals from said second head,

horizontal deflection means in said oscilloscope for simultaneously sweeping said beam horizontally to scan said beam at a substantially uniform rate, and

means operatively interconnected with said horizontal deflection means and said first playback head for receiving said derivative signal therefrom, said last means being responsive to said derivative signal for initiating a horizontal sweep across said oscilloscope each time one of said derivative signals occurs so the horizontal scanning will occur in predetermined fixed time relations to each of said electrocardiac signals.

7. Apparatus for visually displaying waveforms of electrocardiac signals magnetically recorded on a tape, said apparatus including the combination of:

a first playback head for scanning a first track on said tape containing magnetic recordings of said electrocardiac signals and producing signals that are derivatives of said electrocardiac signals,

a second playback head for scanning a second track that is laterally displaced from said first track and contains magnetic recordings of said electrocardiac signal and producing a signal in response thereto, said heads being so positioned longitudinally of said tape relative to each other that said derivative signals occur predetermined time intervals before corresponding portions of said signal from said second head,

display means interconnected with said second playback head for receiving said signal therefrom, said display means including a display area and being responsive to the signal from said second head for producing visual displays of the waveforms thereof on said display area, and

sweep means in said display means for sweeping across said display area and being interconnected with said first playback head to receive the derivative signal therefrom, said sweep means being responsive to said derivative signal to initiate a new sweep across said display area synchronously with said derivative signal so that the waveforms in said display will be superimposed on each other.

8. Apparatus for visually displaying waveforms of electrocardiac signals magnetically recorded on a tape, said apparatus including the combination of:

a rst playback head for scanning a first track on said tape containing magnetic recordings of said electrocardiac signals and producing signals that are derivatives of said electrocardiac signals, said derivative signals having a high rate of change substantially coincident with the beginning of each QRS complex of the electrocardiac signals,

a second playback head laterally displaced from said first head for scanning a second track that is laterally displaced from said first track and contains magnetic recordings of said electrocardiac signals and producing a signal in response thereto, said heads being 1ongitudinally spaced of said tape relative to each other so that the QRS complex of the electrocardiac signal thereon passes through said first head before the electrocardiac signal on the second `track passes through said second head,

a cathode ray oscilloscope,

vertical deflection means in said oscilloscope interconnected with said second playback head and responsive to the signal from said second head for deflecting the electron beam in said oscilloscope in a vertical direction in response to the amplitudes of the electrocardiac signals from said second head,

longitudinal deflection means in said oscilloscope for simultaneously sweeping said beam horizontally to scan said beam at a substantially uniform rate, and

means operatively interconnected with said horizontal deflection means and said first playback head for receiving said derivative sign-al therefrom, said last means being responsive -to said derivative signals for initiating a said horizontal sweep of said beam in predetermined fixed time relations to each of said electrocardiac signals.

9. Means for reviewing electrocardiac signals obtained from a human being comprising the combination of:

magnetic tape recording adapted tov be worn by said human being and having a tape mechanism that drives the tape therein at a first speed for recording the electrocardiac signals thereon, and

means including a second tape mechanism that drives a tape with the signals recorded thereon at a second speed for reproducing said electrocardiac signals and including display means for producing a visual display of the waveforms of said reproduced electrocardiac signals,

said second speed being sufficiently faster than said first speed to insure each waveform being displayed while at least the preceding displayed waveform persists.

10. Means for reviewing electrocardiac signals obtained from a human being comprising the combination of:

magnetic tape recording means adapted tov be worn by said human being and having a tape mechanism that drives the tape therein at a first speed for recording the electrocardiac signals thereon, and

means including a tape mechanism that drives said tape at a second speed and includes a pair of playback heads that are staggered from each other for reproducing said electrocardiac signals and a trigger signal that precedes said electrocardiac signal by a fixed time interval and including display means for producing a visual display of the waveforms of said reproduced electrocardiac signals,

said second speed being faster than said first speed and sufficiently fast to insure each waveform to be displayed while at least the preceding displayed wave- .form persists.

11. Means for reviewing electrocardiac signals obtained from a human being comprising the combination of:

magnetic tape recording means adapted to be worn by said human being and having a tape mechanism that drives the tape therein at a first speed and includes a pair of recording heads that are laterally and longitudinally displaced with respect to each other and to said tape to record a pair of tracks for recording the electrocardiac signals thereon, and

means including a tape mechanism that drives said tape at a second speed and includes a pair of playback heads that are staggered from each other for reproducing said electrocardiac signals and a trigger signal that precedes said electrocardiac signal by a xed time interval and including display means for producing a visual display of the waveforms of said reproduced electrocardiac signals,

said second speed being faster than said rst speed and sufficiently fast to insure each waveform to be displayed while at least the preceding displayed waveform persists. 12. The method of producing visual displays of the waveforms of successive signals comprising the steps of: magnetically recording said signals on a magnetic tape while said tape is travelling at a iirst speed,

reproducing said recorded signals from said tape while said tape is travelling at a second speed that is greater than said rst speed to form a sequence of higher frequency signals, and

producing superimposed visual displays of each of the waveforms of the signals in said sequence, said second speed of said tape being sufficiently fast to insure each of said waveform displays persisting until at least the display of the waveform of the next signal is produced.

13. The method of producing visual displays of the waveforms of successive electrocardiac signals comprising the steps of:

magnetically recording said electrocardiac signals on a magnetic tape while said tape is travelling at a rst speed, reproducing said recorded electrocardiac signals from said tape while said tape is travelling at a second speed that is faster than said iirst speed to form a Sequence of Ahigher frequency electrocardiac signals,

coupling said reproduced electrocardiac signals into display means effective to produce visual displays of the waveforms of said signals, and

producing visual superimposed displays of said successive electrodcardiac signals, said second tape -speed being fast enough to insure each of said waveform displays persisting until at least the succeeding waveform display is produced.

14. Means for providing a display of the intervals between electrocardiac signals comprising the combination of:

means responsive to said electrocardiac signals and effective to produce a trigger signal each time an electrocardiac signal occurs,

a generator operatively interconnected with said means and responsive to said trigger signals to produce a pulse each time `a trigger signal occurs having an amplitude proportional to the interval between said trigger signals, and

display means operatively interconnected with said generator to produce verticaldisplays having heights 16 proportional to the amplitude of said pulses and having a horizontal sweep that has a period much longer than the interval of said electrocardiac signals to provide a series of substantially parallel displays that form an envelope that varies with the variations in said heights. 15. Means for providing a display of the interval between electrocardiac signals having R waves, said means comprising the combination of:

input means responsive to the R waves in said electrocardiac signals and effective to produce a trigger signal each time an R wave occurs,

a pulse generator operatively interconnected with said means and responsive to said trigger signal to produce a pulse each time a trigger signal occurs and having an amplitude proportional to the interval between said R waves,A and -a cathode ray oscilloscope having a horizontal sweep rate with a period much longer than the interval of said electrocardiac signals and having a vertical deection portion interconnected with said pulse generator to produce a series of vertical displays having heights proportional to the amplitudes of said pulses and having an envelope that varies with the heights of said displays.

References Cited by the Examiner UNITED STATES PATENTS 2,370,134 2/45 Begun 324-68 2,378,383 6/45 Arndt 324-77 2,416,353 2/ 47 Shipman et al 324-77 2,424,218 7/47 Begun 324-77 2,457,744 12/48 Sturm 12S-2.06 2,534,712 12/50 Gray 324-68 2,727,209 12/55 Mayer 324-68 2,729,803 1/56 Harrison 324-68 2,795,273 6/57 Putnam 324-682 2,932,549 4/60 Kling 12S-2.06 2,998,568 8/61 Schlessel 324-77 3,048,166 8/62 Rodbard 12S-2.06 3,105,192 9/63 Messin et al. 324"79 OTHER REFERENCES New Method for Heart Studies, article by N. J. Holter in Science, Oct. 20, 1961,'pages 1214-1220.

The Cathode Ray `Sound Spectroscope, article by K. H. Davis in Bell Labs. Record, June 1950, pages Annals: New York Academy of Sciences for v1957, pages 913-923. Article by Norman I. Holter.

RICHARD A. GAUDET, Primary Examiner.

JORDAN FRANKLIN, Examiner.

Claims (1)

1. APPARATUS FOR VISUALLY DISPLAYING WAVEFORMS OF SIGNALS MAGNETICALLY RECORDED ON A TAPE, SAID APPARATUS INCLUDING THE COMBINATION OF: A FIRST PLAYBACK HEAD FOR SCANNING A TRACK ON SAID TAPE CONTAINING SAID MAGNETIC RECORDINGS AND PRODUCING TRIGGER SIGNALS IN RESPONSE TO SAID RECORDINGS, A SECOND PLAYBACK HEAD FOR SCANNING A TRACK CONTAINING SAID MAGNETIC RECORDINGS AND PRODUCING A SIGNAL IN RESPONSE THERETO, SAID HEADS BEING POSITIONED RELATIVE TO EACH OTHER SO THAT SAID TRIGGER SIGNALS OCCUR PREDETERMINED TIME INTERVALS BEFORE CORRESPONDING PORTIONS OF SAID SIGNALS FROM SAID SECOND HEAD, DISPLAY MEANS INTERCONNECED WITH SAID SECOND PLAYBACK HEAD TO RECEIVE THE SECOND REPRODUCED SIGNALS THEREFROM, SAID DISPLAY MEANS INCLUDING A DISPLAY AREA AND BEING RESPONSIVE TO THE SECOND REPRODUCED SIGNAL FROM SAID SECOND HEAD FOR PRODUCING VISUAL DISPLAYS OF THE WAVEFORMS ON SAID DISPLAY AREA, AND SWEEP MEANS IN SAID DISPLAY MEANS FOR SWEEPING ACROSS SAID DISPLAY AREA AND BEING INTERCONNECTED WITH SAID FIRST PLAYBACK HEAD FOR RECEIVING SAID TRIGGER SIGNALS, SAID SWEEP MEANS BEING RESPONSIVE TO THE TRIGGER SIGNALS FOR SYNCHRONIZING SAID DISPLAY MEANS IN RESPONSE TO SAID TRIGGER SIGNALS TO INITIATE A NEW SWEEP ACROSS SAID DISPLAY AREA TO PRODUCE A VISUAL DISPLAY OF THE SECOND REPRODUCED SIGNAL.

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