JP3036954U - Portable heartbeat interval recorder - Google Patents

Abstract

(57) Abstract: A portable heartbeat interval recording apparatus for recording heartbeat interval data itself together with acceleration data for a long time is provided. A battery mounted on a subject, an acceleration sensor for detecting acceleration in three orthogonal directions, and
Data output terminal 1 connectable to a personal computer
9 is provided, and the lead wire provided with the electrocardiogram electrode is led out from the case. As a circuit portion, a heartbeat interval data creating means 11 for creating heartbeat interval data by detecting a heartbeat signal in the induced electrocardiogram signal and sequentially measuring a time interval between immediately preceding heartbeat signals, and a predetermined heartbeat interval data. A storage unit 12 for storing time and an acceleration data creating unit 16 for creating an acceleration data by calculating an average acceleration per unit time based on the acceleration signal detected by the acceleration sensor.
And storage means 17 for storing acceleration data for a predetermined time. The heartbeat interval data and the acceleration data are sent from the data output terminal 19 to the personal computer as recording data for a predetermined time.

Description

[Detailed description of the invention]

[0001]

[Technical field to which the invention belongs]

 The present invention relates to a portable heartbeat interval recording apparatus capable of recording heartbeat interval data along with acceleration data for a long time so that they can be compared on a common time axis.

[0002]

[Prior art]

 Monitoring of cardiac function in daily life using a portable electrocardiograph for long-term recording (Holter electrocardiograph) has been widely performed in recent years, for example, for patients with heart disease after discharge. At that time, the subject may also be equipped with an acceleration sensor to grasp the correlation between the electrocardiogram and exercise, or to detect the heartbeat interval (RR interval) from the recorded electrocardiogram signal waveform for diagnosis. It is being appreciated.

[0003]

[Problems to be solved by the device]

 However, since the electrocardiogram signal or acceleration signal is recorded as waveform data that is sampled as it is, the memory capacity increases accordingly, and conversely, if the sampling period is lengthened to record for a long time, the data accuracy is sacrificed. Inevitably, there was room for improvement in terms of circuit cost or portable structure for long-term recording.

In view of such a point, the present invention has an object to provide a portable heartbeat interval recording apparatus of the kind described at the beginning which records heartbeat interval data itself together with acceleration data for a long time. .

[0005]

[Means for Solving the Problems]

 In order to achieve this object, the present invention provides, according to claim 1, a circuit part, a battery for supplying power to the circuit part, and an orthogonal triaxial shaft in a case to be attached to a subject as shown in FIG. An acceleration sensor that detects acceleration in the direction and a data output terminal 19 that can be connected to a personal computer are provided, and a lead wire having an electrocardiogram electrode at the tip end that is attached to the subject is led out from the case, and the circuit portion As a heartbeat interval data creating means 11 for creating heartbeat interval data by detecting a heartbeat signal in an electrocardiogram signal induced in an electrocardiogram electrode and sequentially measuring a time interval between immediately preceding heartbeat signals, The storage means 12 for storing the heartbeat interval data for a predetermined time, and the average acceleration per unit time are calculated based on the acceleration signals in the orthogonal three-axis directions detected by the acceleration sensor. An acceleration data creating unit 16 for calculating and creating acceleration data and a storage unit 17 for storing sequentially created acceleration data for a predetermined time are provided, and the stored heartbeat interval data and acceleration data are output as data. The recording data for a predetermined time is sent from the terminal 19 to the personal computer.

The subject puts on the case and attaches the electrocardiogram electrode to the electrocardiogram induction portion of the subject, whereby the circuit portion is powered by the battery and is in an operating state. The heartbeat interval data creating means 11 detects the heartbeat signal of the electrocardiogram signal induced in the electrocardiogram electrode and sequentially measures the heartbeat interval between the immediately preceding heartbeats to create heartbeat interval data and sequentially stores it in the storage means 12. Let The acceleration data creating means 16 successively calculates the average acceleration per unit time from the acceleration signals in the three axis directions detected by the acceleration sensor, creates acceleration data, and causes the storage means 17 to sequentially store the acceleration data. The heartbeat interval data and acceleration data for a predetermined time stored in the storage means 12 and 17 are output as recording data from the data output terminal 19 to the personal computer, and are output in time series on the screen or recording paper. By doing so, the heartbeat interval for a predetermined time can be diagnosed, and if necessary, the correlation between the heartbeat interval and the exercise state of the subject can be confirmed by collating with the acceleration data of the corresponding time.

In order to make it possible to inspect the electrocardiogram signal waveform at the time of abnormality, according to claim 2, the case is provided with a switch to be operated at the time of abnormality of the subject, and a clock for outputting a time signal as a circuit portion. 15, a temporary storage means 13 for storing at least several tens of standard heartbeats while sequentially updating the electrocardiogram signal, and an electrocardiogram signal stored in the temporary storage means 13 in response to a switch operation by the subject, A memory means 14 for storing electrocardiographic signals for at least several tens of standard heartbeats before and after the operation time point and a time signal at the operation time point is provided.

The memory means 14 reads the electrocardiogram signal stored in the temporary memory means 13 in response to the operation of the switch, and stores the electrocardiogram signal before and after the operation time point and the time signal at the operation time point supplied from the clock. It As a result, the personal computer can perform diagnosis by adding the electrocardiogram signal waveforms before and after the switch operation time and the time of their occurrence, together with the heartbeat interval and exercise state at the corresponding time.

According to a third aspect of the present invention, the case is provided with a tilt sensor for detecting a tilt more than a predetermined angle from the vertical direction, and a storage means 18 for storing a detection signal of the tilt sensor for a predetermined time as a circuit portion. With the provision, it becomes possible to make a diagnosis in consideration of whether the subject is lying down and resting.

According to the fourth aspect, since the unit time is about 0.1 to 5 seconds, the exercise of the subject can be grasped to the extent necessary for diagnosis, and the storage capacity of the storage means can be saved. According to claim 5, the predetermined time period corresponds to one to three days of the standard heartbeat, so that the suitable length of the heartbeat interval can be obtained without giving the subject an excessive burden of wearing the device. It can be implemented as a portable time recording device.

[0011]

[Embodiment of the invention]

 A portable heartbeat interval recording apparatus according to an embodiment of the present invention will be described with reference to FIGS. 2 and 3. In FIG. 2, reference numeral 1 is a belt worn on the waist of the subject, to which a case 9 is attached. In this case, a circuit part, a battery for supplying the power, and an acceleration sensor 20 known per se for detecting acceleration in the three orthogonal directions are provided, and a data output terminal connectable to a personal computer is provided on the surface of the case. Jack 8 and event switch 6 to be operated when the subject feels an abnormality, power switch 7, and mercury that outputs an ON signal when the body is tilted by 40 ° or more in either direction from the vertical direction. A tilt sensor 4 known per se and a heartbeat indicator 5 for sequentially displaying heartbeat intervals converted to a heartbeat for one minute are provided, and two electrocardiographic electrodes 2 and a reference potential electrode worn by a subject are provided. Lead wires 3 each having a tip 2a are led out.

FIG. 3 shows a configuration of a circuit portion of the present invention using a CPU. This circuit portion includes a ROM 31 in which an operation program is stored, a RAM 32 having a work area and the like, a non-volatile memory 33 that stores stored data even after the power switch 7 is turned off, and an operation program in the RAM 32 according to the operation program of the ROM 31. A CPU 30 for performing data processing according to the present invention using a region, an amplifier 21, a low-cut filter 22, and an A / D converter for amplifying the acceleration signals in the three directions to remove low-frequency components and digitize the signals. 23, an amplifier 24 for amplifying the electrocardiogram signal induced between the electrocardiogram electrodes 2 to remove low-frequency components and then digitizing the electrocardiogram signal, a low-cut filter 25 and an A / D converter 26, and a personal computer. A clock 35 for measuring the time from the start time, these input signal sources and a personal computer. And a interface 34 to perform a signal exchange between the CPU30 when.

The memory 33 stores the heartbeat interval data of standard heartbeat intervals for 250,000 beats corresponding to 2.5 days for a predetermined time, for a unit time of the acceleration signal in the three axis directions, for example, 0.1 seconds. The averaged acceleration data of 2.5 days can be stored for 2.5 days, the electrocardiographic signal for 1 minute can be stored for 4 times together with the time signal, and the detection signal of the tilt sensor 4 sampled at intervals of 0.1 seconds can be stored for 2.5 days. Has capacity.

The CPU 30 cooperates with the ROM 31, the RAM 32, the memory 33, etc. to configure the heartbeat interval data creating means 11 and the storage means 12 of the present invention, and stores the data in the RAM 32 at a high-speed sampling period of several milliseconds. For example, the rising of the captured QRS wave of the digital electrocardiogram signal is detected to detect the heartbeat, that is, the R wave, and the time interval immediately before the R wave is sequentially measured and stored in the memory 33. By not storing the electrocardiogram signal as it is, high-speed sampling becomes possible and the heartbeat interval can be timed with high accuracy.

In order to configure the temporary storage means 13, the storage means 14 and the clock 15 of the present invention, the electrocardiogram signal is sequentially updated as it is, temporarily stored in the RAM 32 for one minute, and the event switch 6 is operated. In response to, the electrocardiogram signal for 1 minute from 30 seconds before the operation time to 30 seconds after the operation time and the time signal of the clock 35 at this operation time are stored in the memory 33.

As the acceleration data creation means 16 and the storage means 17 of the present invention are configured, the motion of the subject can be grasped to the extent necessary for diagnosis with respect to the digitized acceleration signals in the directions of the three orthogonal axes. In addition, the acceleration signal for a unit time of, for example, 0.1 seconds, which can effectively save the storage capacity, is sequentially loaded into the RAM 32 every 0.25 milliseconds, and the average acceleration during that time is calculated every 0.1 seconds. Sequentially stored in the memory 33.

Further, every time the R wave is detected, the CPU 30 converts the time interval measured between the immediately preceding R waves into a heartbeat rate of 1 minute and causes the heartbeat display 5 to display it. As the storage means 18 of the present invention is configured, 2.5 days of ON signals detected by the tilt sensor 4 are sampled at 0.1 second intervals and stored in the memory 33. Receives the signal sent from the jack 8 through the interface 34 when connecting to a personal computer, transfers the data and the signal stored in the memory 33 in response to the operation, clears the clock, resets the clock 35, and starts the time. Storage in the memory 33 and the like.

The operation of the portable heartbeat interval recording apparatus configured as described above is as follows. The subject wears the belt 1 on the waist and the electrocardiogram electrode 2 and the reference potential electrode 2a on the chest. The electrocardiogram signal is fetched for one minute while being updated in the RAM 32 at a high-speed sampling cycle of several ms intervals, and the heartbeat interval data obtained by successively detecting the R waves is stored in the memory 33 in order. Heartbeat interval data converted into the heartbeat rate for one minute is displayed on the heartbeat display 5 each time. The clock 35 starts timing based on the start time.

The acceleration signals are averaged in units of 0.1 seconds, and are stored in the respective regions of the memory 33 in order together with the detection signals of the tilt sensor 4. As a result, acceleration data corresponding to the front-back, left-right, and up-down movements of the subject can be recorded in time corresponding to the RR interval data at that time, and at the same time, the tilted state of the body can also be processed in time. Is recorded in.

When the event switch 6 is operated, an electrocardiogram signal for one minute from 30 seconds before to 30 seconds after the operation time is read from the RAM 32 and stored as waveform data together with the time signal of the clock 35 at this operation time. It is stored in the area to which 33 belongs.

When the recording time of about 2.5 days is reached and the heartbeat interval data is inspected, the data stored in the memory 33 is transferred as recording data by connecting the plug of the personal computer to the jack 8. As a result, the personal computer calculates the RR interval data as a heart rate for one minute, for example, and displays the trend on the screen or the recording paper with the time axis aligned with the acceleration data and the tilt data. It is also possible to correspond to the elapsed time based on the transferred start time.

At the same time, the original waveform of the electrocardiogram signal at the time when the event switch 6 is operated is monitored together with its generation time. Based on the detection signal of the inclination sensor 4, it is possible to confirm whether the subject was resting or sleeping when the heartbeat interval data was diagnosed. Furthermore, various analyzes of RR interval data are possible according to the software built in the personal computer.

When new recording is performed, the contents of the memory 33 are cleared by operating the personal computer, and the recording start time of the clock 35 is set. The subject turns on the power switch 7 according to the time and restarts the recording.

[0024]

[Effect of the invention]

 According to the invention of claim 1, since the heartbeat interval is directly recorded on the portable device, and the acceleration signal is also recorded as the average value of the unit time, the memory capacity is saved and the exercise state of the subject is taken into consideration. It is possible to diagnose heartbeat interval data for a long time. The memory capacity can be saved, in other words, the highly accurate heartbeat interval data can be obtained.

According to the second aspect of the invention, not only the RR interval but also the original waveform of the electrocardiogram signal at the time of operating the switch can be monitored. Therefore, the memory capacity can be saved and the electrocardiogram signal itself at the time of abnormality can be monitored. Based diagnosis is also possible.

According to the third aspect of the invention, it is possible to record the state of resting while lying on the body of the subject such as sleeping or taking a break. According to the invention of claim 4, it is possible to save the storage capacity and grasp the exercise condition of the subject to the extent necessary for the diagnosis. According to the invention of claim 5, it is possible to realize a heartbeat interval recording apparatus suitable for a long-time cost and a portable shape, which does not give an uncomfortable feeling to a subject wearing the apparatus.

According to the invention of claim 6, not only the RR interval but also the electrocardiographic signal waveform at the time of abnormality can be monitored, and whether the subject's motion state or body is lying at each heartbeat occurrence time. The heartbeat interval recording device which can also confirm the above is realized by saving the memory capacity and favorably in terms of cost and portable shape.

[Brief description of the drawings]

FIG. 1 is a diagram showing a circuit configuration of a portable heartbeat interval recording apparatus of the present invention.

FIG. 2 is a front view showing a use state of the portable heartbeat interval recording apparatus according to the embodiment of the present invention.

FIG. 3 is a diagram showing a configuration of a circuit portion of the portable heartbeat interval recording apparatus according to FIG.

[Explanation of symbols]

 2 ECG electrodes 4 Tilt sensor 6 Event switch 8 Jack 9 Case

Claims (6)

[Utility model registration claims] 1. A case to be mounted on a subject, a circuit portion, a battery for supplying power to the circuit portion, an acceleration sensor for detecting acceleration in directions of three orthogonal axes, and a data output terminal connectable to a personal computer. A lead wire provided with an electrocardiographic electrode at the tip of the electrocardiogram electrode to be attached to the subject is further derived from the case, and the heartbeat signal in the electrocardiographic signal induced in the electrocardiographic electrode is detected as the circuit portion immediately before. Heartbeat interval data creating means for creating heartbeat interval data by sequentially measuring the time intervals between the heartbeat signals, storage means for storing the sequentially created heartbeat interval data for a predetermined time, and the acceleration sensor detected Acceleration data creating means for sequentially calculating average acceleration per unit time based on acceleration signals in the directions of the three orthogonal axes to create acceleration data; And a storage means for storing the acceleration data created next for the predetermined time, and the stored heartbeat interval data and the acceleration data respectively to the personal computer as recording data for the predetermined time from the data output terminal. A portable heartbeat interval recording device characterized by being transmitted. 2. A case is provided with a switch to be operated when the subject is in an abnormal state, and a clock for outputting a time signal and a circuit for storing at least several tens of standard heartbeats while sequentially updating an electrocardiogram signal as a circuit part. The memory means and the electrocardiogram signal stored in the temporary memory means in response to the operation of the switch by the subject are read, and the electrocardiogram signal before and after the operation time point and the time signal at the operation time point are at least several tens. 2. A portable heartbeat interval recording apparatus according to claim 1, further comprising a storage unit for storing the standard heartbeat amount. 3. The case is provided with a tilt sensor for detecting a tilt more than a predetermined angle from the vertical direction, and a storage means for storing a detection signal of the tilt sensor for a predetermined time as a circuit portion. The portable heartbeat interval recording apparatus according to claim 1. 4. The portable heartbeat interval recording apparatus according to claim 1, wherein the unit time is about 0.1 to 5 seconds. 5. The predetermined time is a time corresponding to one to three days of a standard heartbeat.
Portable heartbeat recording device. 6. A circuit part, a battery for supplying power to this circuit part, an acceleration sensor for detecting acceleration in the directions of three orthogonal axes, and a switch operated when the subject has an abnormality in a case to be mounted on the subject. , A case in which a lead wire provided with a tilt sensor for detecting tilting more than tens of degrees from the vertical direction and a data output terminal connectable to a personal computer, and further having an electrocardiographic electrode at the tip end to be attached to a subject is provided in the case. From the above, as the circuit portion, heartbeat interval data is created by detecting a heartbeat signal in the electrocardiogram signal induced in the electrocardiogram electrode and sequentially measuring the time intervals between immediately preceding heartbeat signals to create heartbeat interval data. Means, storage means for storing the sequentially created heartbeat interval data for one to three days of a standard heartbeat, and addition in the orthogonal three-axis directions detected by the acceleration sensor. Acceleration data creating means for sequentially calculating average acceleration per 100 to several hundreds of milliseconds based on the frequency signal and creating acceleration data, and the sequentially created acceleration data for about 1 to 3 days. Storage means,
Temporary storage means for storing about one minute while sequentially updating the electrocardiogram signal, a clock for outputting a time signal, and the electrocardiogram signal stored in the temporary storage means in response to an operation of the switch by a subject. And a storage means for storing the electrocardiographic signals for about 30 seconds before and about 30 seconds after the operation time point and the time signal at the operation time point,
A storage means for storing detection signals of the inclination sensor at intervals of about 100 to several 100 milliseconds for about 1 to 3 days, the stored heartbeat interval data, the acceleration data, the electrocardiogram signal, and the time, respectively. A portable heartbeat interval recording apparatus, wherein the signal and the detection signal of the tilt sensor are sent from the data output terminal to the personal computer as recording data for about 1 to 3 days.