JPH05154118A - Portable electrocardiograph - Google Patents

Abstract

PURPOSE:To clearly grasp a correlation of an event waveform and a heart rate/trend graph. CONSTITUTION:The portable electrocardiograph is provided with a means for superposing a heart rate/trend graph 100 and an event waveform 200 so as to become two upper and lower stages on a screen of a liquid crystal device 16 and displaying them simultaneously, in a reproducing display mode, and a means for displaying together a time indication mark d3 on the heart rate/ trend graph 100 in accordance with a data storage time of the displayed event waveform 200. Also, this electrocardiograph is provided with a means for moving the event waveform 200 to be displayed and the time indication mark d3 by synchronizing them with each other in a state that the data storage time is held in the same by operating scroll keys d4-1-d4-4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is carried by a patient on a daily basis, constantly measures the electrocardiographic data of the patient, and calculates the heart rate from the electrocardiographic data, so that the patient has palpitation and chest pain. By operating the event switch when you are aware of symptoms such as, the event waveform data and heart rate / trend data for several minutes before and after the symptom are memorized (event recording), and if necessary, when The present invention relates to a portable electrocardiograph configured to be reproduced and displayed as an electrocardiogram waveform (event waveform) and a heart rate / trend graph at the time of subjective symptoms.

[0002]

2. Description of the Related Art In this type of portable electrocardiograph, electrocardiographic data for event recording is stored, for example, for several minutes before and after a subjective symptom, and is stored as an event waveform on a liquid crystal display screen or the like when a doctor or the like makes a diagnosis. By displaying it, it is used for qualitative diagnosis of whether the subjective symptom is derived from heart disease.

On the other hand, in the conventional portable electrocardiograph, the heart rate / trend data is continuously stored for a long time of, for example, 24 hours regardless of the subjective symptoms of the patient, and the heart rate at the time of diagnosis. -It was used for quantitative diagnosis of heart disease by displaying it as a trend graph. This heart rate / trend data (graph) is not when the patient felt subjective symptoms.

In the conventional portable electrocardiograph,
At the time of playback display, the process of calling the event waveform on the display screen and the process of calling the heart rate / trend graph are performed independently and completely separately. That is, the heart rate / trend graph is not displayed when the event waveform is being reproduced and displayed, and conversely, the event waveform is not displayed when the heart rate / trend graph is being reproduced and displayed.

By the way, recently, the heart rate / trend data is not continuously stored for a long time regardless of the presence / absence of subjective symptoms of the patient, but is limited to a few minutes before and after the subjective symptoms as in the event waveform. The idea of remembering things has come into being.

[0006]

The size of the event waveform reproduced and displayed on the screen is adjusted to the standard scale of a general electrocardiograph, or is set to a scale of a double or a half of the standard scale for the purpose of diagnosis. There is. Therefore, the event waveform that can be displayed on one screen is
The reality was that it was limited to a few seconds.

In view of the fact that the event waveform data (electrocardiogram data) is for several minutes, this means that only extremely fragmentary information is displayed.

Therefore, in order to observe changes over time during the event recording period, it was necessary to scroll the displayed waveform sequentially by operating the keys.
When diagnosing only the event waveforms, it is not possible to determine whether there is an abnormality regarding heart disease without observing all the recorded waveforms, so all waveforms during the event recording period are displayed. It is necessary to perform a sequential scroll operation.

However, the operation of scrolling once to stop the waveform and observing, and when the observation of the waveform is finished, scrolling again and moving to the display of the next waveform must be repeated many times. Such work is very troublesome, and it takes a lot of time for diagnosis, which is a problem.

Also, by switching from the event waveform display screen to the heart rate / trend graph display screen, it is possible to grasp the overall tendency and to have an approximate idea of whether there is an abnormality, but the heart rate / trend. There is no way to directly connect the graph and the event waveform on the time axis, and even if an abnormal part is found on the heart rate / trend graph, to observe that part in more detail. When switching to the event waveform display screen, the scroll key is displayed from the beginning, so it is necessary to operate the scroll key in the same way as above, and even if scrolling, it is possible to confirm whether the event waveform is the abnormal part. The confirmation was complicated and difficult.

[0011] Therefore, it has been a major obstacle in promptly and accurately determining whether or not the subjective symptom is derived from heart disease.

The present invention was devised in view of such circumstances, and an object thereof is to enable the correlation between the event waveform and the heart rate / trend graph to be grasped at a glance.

[0013]

A first portable electrocardiograph according to the present invention is a means for temporarily updating and storing electrocardiogram data obtained from a patient, and calculating a heart rate based on the electrocardiogram data. Means, a means for temporarily updating and storing the calculated heart rate data, a means for storing electrocardiogram data for a certain time before and after the operation of the event switch as event waveform data together with time information, and the event. At the same time when operating the switch, a means for storing heart rate data for a certain time before and after the operation as heart rate / trend data together with time information, and in the playback display mode,
A means for displaying the event waveform and the heart rate / trend graph on the display screen at the same time by superimposing them in upper and lower two steps, and on the heart rate / trend graph corresponding to the data storage time of the displayed event waveform. Means for displaying the time indication mark together, and means for moving the event waveform to be displayed on the display screen by operating the scroll key and the time indication mark in synchronization with each other and keeping the data storage time the same. It is characterized by having.

The second portable electrocardiograph according to the present invention is a means for determining whether or not the event waveform to be displayed in the first portable electrocardiograph exceeds the predetermined waveform display area. , And a means for correcting the amplitude and the baseline of the event waveform to be displayed when it is determined that the waveform is to be projected so that the displayed waveform fits within the waveform display area.

[0015]

According to the first portable electrocardiograph, since the event waveform and the heart rate / trend graph are simultaneously displayed in the upper and lower two stages, it is necessary to scroll the entire waveform as in the conventional example. If not, there is no need to switch from the display screen of the heart rate / trend graph to the display screen of the event waveform.While watching the heart rate / trend graph and the event waveform at the same time, scroll the key to display the heart rate / trend graph. When the time indication mark is moved to a portion that seems to be abnormal, the event waveform is scrolled in synchronization with this and the data storage time is kept the same. That is,
By using the heart rate / trend graph, it is possible to observe the event waveforms in the simultaneous display state in association with the temporal change of the heart rate during the event recording period. In short, the correlation between the heart rate / trend graph and the event waveform can be clearly understood at a glance.

By the way, if the heart rate / trend graph and the event waveform are simply displayed by superimposing them in two steps, the amplitude is too large depending on the waveform and a part of the waveform overlaps the heart rate / trend graph. It can be hidden and hidden, making it difficult to see.

However, according to the second portable electrocardiograph, a display area of a predetermined size in which the event waveform is to be displayed is defined, and it is determined whether or not the event waveform to be displayed now extends from the waveform display area. If it is judged that it is out of range, the event waveform is displayed after correcting the amplitude and baseline so that the displayed waveform fits within the waveform display area. The event waveform can be always displayed in a predetermined waveform display area without being hidden in the heart rate / trend graph.

[0018]

An embodiment of a portable electrocardiograph according to the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a block diagram showing the electrical construction of the main part of a portable electrocardiograph.

In the figure, 2 is a body surface electrode to be worn on a patient, 4 is an electrocardiographic amplifier for amplifying an electrocardiographic signal picked up by the body surface electrode 2, and 6 is an amplified analog electrocardiographic signal for digital electrocardiographic data. Convert A
A / D converter, 8 is a central processing unit of a microcomputer and is in charge of overall control, 10 is a ROM storing programs, 12 is a RAM as a working memory and a user memory, and 14 is a drive control by the CPU 8. A liquid crystal driver, 16 is a liquid crystal display device in which fine liquid crystal display elements are arranged in a matrix vertically and horizontally so that various data can be displayed in any of numerical values, graphs, and waveforms, and 18 is for inputting various operations. A touch key 20 is an event switch that is pressed when the patient feels subjective symptoms such as palpitation or chest pain. The touch keys 18 are formed on a transparent plate according to the key display of the liquid crystal display device 16.

The RAM 12 stores the electrocardiogram data sampled by the A / D converter 6 together with the time information in the CPU.
And a storage area for temporarily storing the trend data of the heart rate calculated based on the electrocardiogram data together with the time information by the memory loop method via the memory loop method of FIG. ing. CPU8
Has a function of calculating the heart rate based on the electrocardiogram data temporarily stored in the RAM 12, and when the event switch 20 is pressed, one minute before and after the operation, for a total of two minutes. The function of storing the electrocardiogram data of the above as event waveform data in the RAM 12 and a total of 2 minutes each before and after the pressing operation of the event switch 20
The RAM 12 has a function of storing heart rate / trend data for minutes.

FIG. 2 shows a memory map of the RAM 12.

As shown in FIG. 2, the RAM 12 has first and second electrocardiogram data storage areas 12a and 12b and a first electrocardiogram data storage area 12a.
And second heart rate data storage areas 12c and 12d.

The first electrocardiogram data storage area 12a is for one minute before the event, and the latest electrocardiogram data for one minute is constantly updated and stored together with the time information by the memory loop method, and the event switch 20 is used. This is an area for permanently storing the electrocardiogram data for one minute before the event as event waveform data together with time information by stopping the update storage when is pressed.

The second electrocardiographic data storage area 12b is for one minute after the event, and is for storing electrocardiographic data obtained for one minute from the time when the event switch 20 is pressed together with the time information. Area.

The first heart rate data storage area 12c is for one minute before the event, and the latest heart rate / trend data for one minute is constantly updated and stored together with time information by a memory loop method. This is an area for permanently storing the heart rate / trend data for one minute before the event together with the time information by stopping the update storage when the event switch 20 is pressed.

The second heart rate data storage area 12d is for one minute after the event, and the heart rate / time obtained for one minute after the event switch 20 is pressed.
This is an area for storing trend data together with time information.

3 and 4 show a display example in the liquid crystal display device 16 in which fine liquid crystal display elements are arranged in a matrix vertically and horizontally so that various data can be displayed in any of numerical values, graphs and waveforms.

On the display screen, displays corresponding to various keys of the touch key 18 are also performed.

FIG. 3 shows the features of the present invention most simply. That is, the heart rate for 2 minutes in total, 1 minute before and after the event switch 20 is pressed,
Trend graph 100 and several event waveforms 200
It shows a state in which and are superimposed and displayed in a state of being divided into upper and lower two stages.

D ₁ is a vertical axis display for indicating the heart rate HR, d ₂ is a horizontal axis display for indicating time (2-minute trend), d ₃ is a time indication mark, and d ₄ is a time indication mark d.
A scroll key for scrolling the event waveform 200 at the same time as the movement of ₃ .

Of these, d _4-1 and d _4-2 are the right scroll key and the left scroll key for moving the event waveform 200 in a unit of one heartbeat, and d _4-3 and d _4-4 are scrolls in a unit of one screen. The right skip key and the left skip key. d
₅ is a trend graph key, and d ₆ is a display magnification changing key.

FIG. 4 shows a display example of only the event waveform 200. d ₇ is a display showing the heart rate of the first one heartbeat of the displayed event waveform 200, and d ₈ is the displayed event waveform 200. The waveform of one heartbeat at the beginning of is a display showing the displacement time from the time when the event switch 20 is pressed and operated. When "+" is attached, the displacement time after the event switch 20 is pressed and operated, "-". When is attached, it is the displacement time before the event switch 20 is pressed.

When the trend graph key d ₅ is pressed and operated, the heart rate / trend graph 100 and the event waveform 200 shown in FIG. It is for switching to the display screen.

Next, the operation of the portable electrocardiograph of this embodiment will be described with reference to the flow charts shown in FIGS.

When the power is turned on, the control operation by the CPU 8 is started. The electrocardiogram signal picked up by the body surface electrode 2 and amplified by the electrocardiographic amplifier 4 is A / D.
It is input to the converter 6. The CPU 8 performs the following control operation according to the program read from the ROM 10.

When the power is turned on, the liquid crystal display device 16
The notation of the measurement key and the reproduction key is displayed as the touch key 18.

First, in step S1, it is determined whether or not the measurement key of the touch keys 18 has been operated, and when it is determined that the operation has been performed, the routine of steps S2 to S15 is executed. Otherwise, in step S16, it is determined whether or not the reproduction key of the touch keys 18 has been operated. If it is determined that the reproduction key has been operated, step S1
The routine of 7 to S29 is executed (details will be described later).

After the power is turned on, generally, the measurement key is first input. Therefore, the process proceeds to step S2 to control the A / D converter 6,
The amplified electrocardiographic signal input by is sampled at regular intervals, converted into digital electrocardiographic data by A / D conversion, and taken into the CPU 8. And CPU8
In step S3, the continuously sampled electrocardiographic data is transferred to the RAM 12 and temporarily stored together with the time information. At this time, the CPU 8 updates and stores in the first electrocardiogram data storage area 12a (for 1 minute before the event) in the RAM 12 by the memory loop method so that the electrocardiogram data for the latest 1 minute from the present is always secured. The stored contents are constantly changing until the event switch 20 is operated.

The CPU 8 is a RAM 12 in step S4.
The electrocardiogram waveform is analyzed based on the electrocardiogram data read from to search for data corresponding to the R-wave apex that is the delimiter of one heartbeat. The R-wave apex is the portion with the sharpest rise in the QRS complex, which is the characteristic point of the electrocardiogram waveform. As a method of searching for the R-wave apex, for example, the value of the electrocardiogram data at a certain point exceeds 70% of the maximum value of the electrocardiogram data group within one heartbeat before that, and the maximum point. It can be realized by determining the condition.

When it is recognized that it is the R wave apex, step S5
Otherwise, returns to step S2 through step S7 (judgment of operation of event switch 20) and step S8 (judgment of operation of stop key).
Steps S2 to S4, S7 and S8 are repeated.

When the R wave apex is found, the process proceeds to step S5, and the heart rate is calculated. That is, the reciprocal of the time from the R-wave apex of the previous heartbeat to the R-wave apex of the current heartbeat is calculated, and this is set as the heart rate. The time is obtained by [sampling number × sampling period] between both R wave vertices.

Next, in step S6, the CPU 8 transfers the heart rate data to the RAM 12 together with the time information, and temporarily stores the data. At this time, the CPU 8 also executes step S3.
Similarly, in the first heart rate data storage area 12c (for one minute before the event) in the RAM 12, the heart rate / trend data for the latest one minute from the present is updated and stored by the memory loop method so as to be always secured. The stored contents are constantly changing until the event switch 20 is operated.

When the event switch 20 is not pressed,
Further, unless the stop key of the touch keys 18 is pressed, the process returns to step S2 and the above operation is repeated. When it is determined in step S8 that the stop key has been operated, the process returns to step S1.

Event switch 2 in step S7
If it is determined that 0 has been operated, step S9 in FIG.
Proceed to. In step S9, similarly to step S2, the amplified electrocardiogram signal is sampled at regular intervals and A /
D-convert and read into CPU8, and in step S10,
The continuously sampled electrocardiographic data is stored in the RAM 12 together with the time information. At this time, the CPU 8
The electrocardiogram data is recorded in the second electrocardiogram data storage area 12b (for 1 minute after the event) in the RAM 12. Since update storage by the memory loop method is not performed in the first electrocardiogram data storage area 12a, the electrocardiogram data from 1 minute before the operation of the event switch 20 to the operation time is fixedly stored in this storage area 12a. Become.

In step S11, as in step S4, the electrocardiogram waveform is analyzed to form one heartbeat R.
Search for data corresponding to wave vertices. If it is recognized as an R-wave apex, the process proceeds to step S12. If not, the process returns to step S9 through step S14 (judgment of event recording end), and then steps S9 to S11, S.
Repeat 14.

When the R wave apex is found, the process proceeds to step S12 to calculate the heart rate, and in step S13, the calculated heart rate / trend data is stored together with time information in RAM1.
Store in 2. At this time, the CPU 8 stores the heart rate / trend data in the second heart rate data storage area 12d (for 1 minute after the event) in the RAM 12. Since update storage by the memory loop method is not performed in the first heart rate data storage area 12c, heart rate / trend data from 1 minute before the operation of the event switch 20 to the operation time is fixedly stored in this storage area 12c. Will be done.

At step S14, the event switch 2
It is determined whether or not the event recording is completed depending on whether or not 1 minute has elapsed after the operation of 0. Until the event recording is completed, the process returns to step S9 to store the electrocardiogram data and the heart rate / trend data for one minute after the operation of the event switch 20. When it is determined that the event recording is completed, the process proceeds to step S15, the power is automatically turned off, and the measurement of the electrocardiogram data is completed.

As described above, when a patient feels subjective symptoms such as palpitation or chest pain and operates the event switch 20, a total of 2 minutes of electrocardiographic data (event waveform data; The heart rate / trend data is stored in the RAM 12.

When the power is turned on again after the event recording is completed, the determination in step S1 is usually negative, and the process proceeds to step S16. That is, touch key 1
After waiting for the reproduction key to be operated in step 8, the process proceeds to step S17 in FIG.

In step S17, the CPU 8 causes the RAM 1
2 to 1 screen of electrocardiographic data (event waveform data)
Is read, the electrocardiogram data is converted into electrocardiogram waveform display data in step S18, the display data is transferred to the liquid crystal driver 14 in step S19, and step S20 is executed.
Then, the liquid crystal driver 14 is controlled to reproduce and display the event waveform 200 (for several seconds) on the liquid crystal display device 16. This display, or determines that the trend graph key d ₅ in step S21 has been operated or is continued until it is determined that the cancel key in the touch key 18 is operated in step S22. When the stop key is operated, the process returns to step S1.

In step S21, the trend graph key d ₅
When it is determined that the button has been operated, the process proceeds to step S23, the heart rate / trend data is read from the RAM 12 into the CPU 8, and the heart rate / trend data is converted into the display data of the heart rate / trend graph in step S24. The heart rate / trend graph is a graph showing the temporal variation of the heart rate, with the horizontal axis representing time and the vertical axis representing heart rate. At this time, the heart rate / trend graph 100 is converted into display data that is displayed slenderly at the upper end of the screen so that the upper and lower two-stage superimposed display with the event waveform 200 can be performed on the liquid crystal display device 16.

Then, in step S25, the CPU 8
The display data of the heart rate / trend graph 100 is superimposed on the display data of the event waveform 200 and transferred to the liquid crystal driver 14, and the liquid crystal driver 14 is controlled in step S26 to display the heart rate / trend graph on one screen of the liquid crystal display device 16. 1
00 and the event waveform 200 are simultaneously displayed in the upper and lower two rows. At this time, the CPU 8 also displays the time indication mark d ₃ on the heart rate / trend graph 100 in association with the recording time of the displayed event waveform 200.

In step S27, it is determined whether the scroll key d ₄ of the touch key 18 has been operated,
If it is not operated, skip to step S29,
When operated, the process proceeds to step S28, the type of the scroll key d ₄ (right scroll key d _4-1, the left scroll key d _4-2, right skip key d _4-3, left skip key d _4-4 ), The event waveform 200 to be displayed on the liquid crystal display device 16 is scrolled, and the time indication mark d ₃ is displayed on the heart rate / trend graph 100 in synchronization with the scrolling of the event waveform 200. Move with.

In step S29, it is determined whether or not the stop key of the touch keys 18 has been operated. If not, the process returns to step S23 and step S23.
The routine from S29 to S29 is repeated, but when the stop key is operated, the process returns to step S1.

Such a heart rate / trend graph 100
And the event waveform 200 are simultaneously displayed in two stages, the ECG waveform 200 is scrolled in synchronization with each other, and the time indication mark d is displayed.
The movement of ₃ makes it possible to configure a screen in a state in which the electrocardiogram waveform 200 at each data storage time is associated with a temporal change in the heart rate during the event recording period.

By displaying the heart rate / trend graph 100 and the event waveform 200 on the liquid crystal display device 16 in two stages at the same time, the doctor can quickly and clearly grasp the correlation between the heart rate / trend graph 100 and the event waveform 200. can do. This means whether the subjective symptom that is the basis of the event waveform 200 is derived from a heart disease, or when it is derived from a heart disease, elucidation of the mechanism of its occurrence, This is extremely advantageous for promptly and accurately performing necessary treatments such as determination of severity and confirmation of drug effect.

By the way, the heart rate / trend graph 100
If the event waveform 200 and the event waveform 200 are simply displayed in an upper and lower two-step manner, the amplitude is too large depending on the event waveform 200, and a part of the heart rate / trend graph 1
There is a possibility that it will be hidden by overlapping 00, making it difficult to see.

Therefore, as shown in FIG. 8, the display screen of the liquid crystal display device 16 is displayed on the trend graph display area 16 of a predetermined size in which the heart rate / trend graph 100 is to be displayed.
a, an event waveform display area 16b of a predetermined size in which the event waveform 200 is to be displayed, and a scroll key display area 16c, and as a control operation of the CPU 8, between step S24 and step S25 of FIG. , The routine shown in FIG. 9 is added. As an example of the screen size of the liquid crystal display device 16, for example, the entire screen is relatively small at 80 × 128 dots, and 16 × 128 dots are allocated as the trend graph display area 16a.
48 × 128 dots are allocated as the event waveform display area 16b and 16 as the scroll key display area 16c.
× 128 dots are allocated.

The flow will be described below.

When the CPU 8 creates the display data of the heart rate / trend graph 100 in step S24,
In step S30, the peak value of the event waveform 200 (p
to calculate the eak to peak) V _PP. And
In step S31, V _PP is the event waveform display area 16
It is determined whether or not it is smaller than the height H of b.

When V _PP ≦ H, the event waveform 200 to be displayed fits within the event waveform display area 16b, and there is no problem.
Although it skips to 34, it does not fit when V _PP > H, so the process proceeds to step S32, and the peak value of the electrocardiogram data for one screen is reduced to 1/2 (V _PP ← V _PP / 2).
Then, in step S33, instead of the display data of the event waveform 200 in step S18, the reduced electrocardiogram data is converted into the display data of the event waveform 200.

Next, in step S34, the peak value V of the event waveform 200 is set so that the event waveform 200 can be surely included in the event waveform display area 16b.
_PP middle level V _PP / 2 event waveform display area 1
The baseline is shifted so that it coincides with the center position of 6b.

In step S35, the display data of the event waveform 200 whose amplitude and baseline have been corrected as described above and the display data of the heart rate / trend graph 100 are superimposed on each column, and then, as shown in FIG. Then, the process proceeds to step S25.

In this case, the event waveform 200 is the heart rate
It is possible to avoid being hidden by the trend graph 100 and becoming invisible, and it is possible to display the entire amplitude range of the event waveform 200 in the event waveform display area 16b at all times, and display the heart rate / trend graph 100 and the event waveform 200 in two stages. Can be made highly visible.

Regarding the two-stage display of the heart rate / trend graph 100 and the event waveform 200, the event waveform 200 may be displayed in the upper stage and the heart rate / trend graph 100 may be displayed in the lower stage.

[0067]

According to the first portable electrocardiograph according to the present invention, the heart rate / trend graph and the event waveform are superposed on the upper and lower sides of the same screen, and the heart rate When the time indication mark is moved on the trend graph, the event waveform is scrolled in synchronization with the data storage time kept the same, so it is possible to synchronize the event waveform with the temporal change in heart rate. It can be displayed, and the correlation between the two can be clearly understood at a glance.

By displaying the heart rate / trend graph, it is possible to judge the presence or absence of extrasystole and the tendency of tachycardia or bradycardia without looking at the entire waveform as in the conventional example. In addition, the display of the heart rate / trend graph and the event waveform in the upper and lower two stages, the movement of the time indication mark on the heart rate / trend graph synchronized with each other, and the scrolling of the event waveform lead to the occurrence of an abnormality. It is possible to promptly and accurately determine the progress, the progress of returning to normal, and eventually the determination of whether the subjective symptom is caused by heart disease.

Further, according to the second portable electrocardiograph according to the present invention, a display area of a predetermined size is defined for the event waveform display, and whether the event waveform to be displayed is out of the waveform display area. If it is determined that it is out of range, the amplitude and baseline are corrected so that the display waveform fits within the waveform display area, and then the event waveform is displayed. Nevertheless, the event waveform can be displayed in the entire amplitude range at all times, avoiding the event waveform being hidden by the heart rate / trend graph and becoming invisible. Can be something.

[Brief description of drawings]

FIG. 1 is a block diagram showing an electrical configuration of a main part of a portable electrocardiograph according to an embodiment of the present invention.

FIG. 2 is a memory map of a RAM in the embodiment.

FIG. 3 is a display example of a two-stage display of a heart rate / trend graph and an event waveform in the embodiment.

FIG. 4 is a display example of an event waveform in the embodiment.

FIG. 5 is a flowchart for explaining the operation of the embodiment.

FIG. 6 is a flowchart for explaining the operation of the embodiment.

FIG. 7 is a flowchart for explaining the operation of the embodiment.

FIG. 8 is a diagram showing a divided configuration of a display screen according to another embodiment.

FIG. 9 is a flowchart for explaining the operation of another embodiment.

[Explanation of symbols]

2 body surface electrode 4 electrocardiographic amplifier 6 A / D converter 8 CPU 10 ROM 12 RAM 12a first electrocardiogram data storage area 12b second electrocardiogram data storage area 12c first heart rate data storage area 12d second heart rate Data storage area 14 Liquid crystal driver 16 Liquid crystal display device 16a Trend graph display area 16b Event waveform display area 16c Scroll key display area 18 Touch key 20 Event switch 100 Heart rate / trend graph 200 Event waveform d ₃ Time indication mark d ₄ Scroll key d ₅ Trend playback key

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location 8119-4C A61B 5/04 312 U

Claims (2)

[Claims] 1. A means for temporarily updating and storing electrocardiographic data obtained from a patient, a means for calculating a heart rate based on the electrocardiographic data, and a means for temporarily updating and storing the calculated heart rate data. And a means for storing the electrocardiogram data for a certain period of time before and after the operation of the event switch as event waveform data together with time information, and the heart rate data for a certain period of time before and after the operation of the event switch at the same time.・ Means for storing trend data together with time information, and means for simultaneously displaying the event waveform and heart rate / trend graph on the display screen in the upper and lower two layers in the playback display mode, and displaying the displayed event. The time indication mark is also displayed on the heart rate / trend graph in association with the waveform data storage time. And a means for moving the event waveform to be displayed on the display screen and the time indication mark by operating the scroll key in synchronization with each other and keeping the data storage time the same. Portable electrocardiograph. 2. The portable electrocardiograph according to claim 1, wherein a means for determining whether an event waveform to be displayed exceeds a predetermined waveform display area, and an event waveform to be displayed when it is determined that the event waveform is to be displayed Means for correcting the amplitude and baseline of the waveform so that the displayed waveform fits within the waveform display area.