JP6155053B2 - Biological information monitor input device - Google Patents

Description

  The present invention relates to an input device for a biological information monitor.

  The biological information monitor is a medical device capable of collectively displaying biological information such as heart rate, blood pressure, and respiratory rate measured from a patient in a numerical value or waveform format on a display unit (for example, see Patent Document 1). Such a biological information monitor is mainly acquired from an input device that is connected to a biological information detection unit (such as an electrocardiogram electrode and various biological information measurement sensors) attached to the patient and measures biological information data from the patient. And a display device for displaying biometric information data. As a conventional biological information monitor, a type in which these devices are separate and connected to each other at the time of use, and a type in which these devices are integrated are known.

JP 2004-194996 A

  Incidentally, in recent years, in medical facilities, with the spread of data processing systems such as electronic medical record systems, it has become possible to store enormous amounts of biological information data measured over a long period of time from patients. Therefore, for example, in a medical facility where an electronic medical record system is introduced, the biological information data measured from the patient is transmitted from the biological information monitor to the electronic medical record system in real time, thereby allowing the electronic medical record system to store the biological information data. There is. In this case, while the biological information data is being measured from the patient, all the biological information data can be stored seamlessly. However, if the biological information monitor and the electronic medical record system are not in a communicable state, the biological information data cannot be transmitted from the biological information monitor to the electronic medical record system in real time. Therefore, after that, it may be necessary to supplement the biometric information data during the partially missing period in the electronic medical record system.

  However, the conventional input device that is separate from the display device cannot hold the patient's biological information data therein. For example, when an input device connected to a biological information detection unit attached to a patient is separated from a display device and this input device is transported together with the patient, the input device may receive the biological information data of the patient during the transport period. Even if it can be measured, it cannot be retained. Therefore, the conventional input device that is separate from the display device has a problem in that it cannot provide the biometric data of the past necessary for the external device to the external device.

  The objective of this invention is providing the input device of the biometric information monitor which can provide the past biometric information data required with an external device.

The input device of the biological information monitor of the present invention,
An input device that constitutes a biological information monitor together with a separate display device,
An input connector unit for connecting a biological information detection unit mounted on a patient;
A communication connector for connecting an external device and the input device in a communicable manner;
A clock section in the input device for measuring time, and
A storage unit for storing data;
The biological information is measured by measuring the biological information data from the patient via the biological information detecting unit connected to the input connector unit and acquiring the date / time data at the time of measurement from the clock unit in the input device. A measurement processing unit that associates data and acquired date / time data with each other and stores them in the storage unit as measurement result data;
Have
The measurement processing unit
When outputting the measurement result data stored in the storage unit to the external device via the communication connector unit, the measurement result data after being read from the storage unit and before being output to the external device As time difference reflection processing to reflect the time difference between the external device and the input device ,
Obtaining the time counted in the external device from the external device,
By comparing the time acquired from the external device with the time measured by the clock unit in the input device, the time difference between the external device and the input device is determined,
The date time data included in the measurement result data after being read from the storage unit and before being output to the external device is corrected based on the determined time difference .
Moreover, the input device of the biological information monitor of the present invention is
An input device that constitutes a biological information monitor together with a separate display device,
An input connector unit for connecting a biological information detection unit mounted on a patient;
A communication connector for connecting an external device and the input device in a communicable manner;
A clock section in the input device for measuring time, and
A storage unit for storing data;
The biological information is measured by measuring the biological information data from the patient via the biological information detecting unit connected to the input connector unit and acquiring the date / time data at the time of measurement from the clock unit in the input device. A measurement processing unit that associates data and acquired date / time data with each other and stores them in the storage unit as measurement result data;
Have
The measurement processing unit
When the measurement result data stored in the storage unit is output to the external device via the communication connector unit during the period specified by the external device, after being read from the storage unit and As a time difference reflecting process for reflecting the time difference between the external device and the input device in the measurement result data before being output to the external device,
Obtaining the time counted in the external device from the external device,
By comparing the time acquired from the external device with the time measured by the clock unit in the input device, the time difference between the external device and the input device is determined,
The specified period is corrected based on the determined time difference, and measurement result data including date / time data corresponding to the corrected period is read as measurement result data of the specified period.

  ADVANTAGE OF THE INVENTION According to this invention, the past biometric information data required with an external apparatus can be provided from the input device of a biometric information monitor.

The front perspective view and back perspective view which show the external appearance of the biological information monitor which concerns on one embodiment of this invention The figure which shows the state which isolate | separated each component of the biological information monitor which concerns on one embodiment of this invention The figure which shows the bottom face of the carrier which concerns on one embodiment of this invention The rear perspective view which shows the external appearance of the base unit which concerns on one embodiment of this invention The block diagram which shows the structure of the biological information monitor which concerns on one embodiment of this invention The flowchart for demonstrating the measurement result data processing operation of the measurement process part which concerns on one embodiment of this invention The flowchart for demonstrating the read-out operation | movement of the measurement result data of the measurement process part which concerns on one embodiment of this invention The flowchart for demonstrating the time difference reflection process operation | movement of the measurement process part which concerns on one embodiment of this invention. The flowchart for demonstrating the modification of the time difference reflection process operation | movement of the measurement process part which concerns on one embodiment of this invention

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a front perspective view (FIG. 1 (a)) and a rear perspective view (FIG. 1 (b)) showing an appearance of a biological information monitor according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a state in which each component of the biological information monitor according to the present embodiment is separated, and FIG. 3 is a diagram illustrating the bottom surface of the carrier of the biological information monitor according to the present embodiment.

  The biological information monitor 1 according to this embodiment includes four components such as a carrier 100, an input device 200, a display device 300, and a base unit 400.

  The input device 200 includes an input connector unit 201 for connecting a biological information detection unit attached to a patient, and is a device for acquiring biological information data from the patient via the input connector unit 201. The display device 300 is a device having a display unit 301 for displaying the biological information data acquired by the input device 200. The base unit 400 is installed at a predetermined place such as a bedside, and serves as a mounting table for mounting the monitor main body of the biological information monitor 1 (that is, a combination of the carrier 100, the input device 200, and the display device 300). The device used.

  The carrier 100 includes a carrier main body 100a configured to be connectable to each component in order to carry the biological information monitor 1 or some of the components. Further, the carrier body 100a is provided with a handle portion 101 configured to be gripped when the carrier body 100a is carried together with the connected components. In FIG. 1, the input device 200, the display device 300, and the base unit 400 are integrated with each other by connection with the carrier 100, but each component can be separated from the carrier 100 as shown in FIG. 2.

  Therefore, the carrier main body 100a of the carrier 100 has a first mounting portion 102 to which the input device 200 can be mounted and a second mounting portion 103 to which the display device 300 can be mounted. The bottom portion 104 of the carrier main body 100a is It is configured so that it can be placed on the base unit 400.

  The 1st mounting part 102 is comprised so that the input apparatus 200 can be mounted in the carrier main body 100a by inserting the input apparatus 200 from the side surface opening part of the carrier main body 100a. When the inserted input device 200 hits the deepest part in the insertion direction of the carrier body 100a, the connector 202 (see FIG. 5) of the input device 200 is connected to the first connector 105 (see FIG. 5) of the carrier 100. Thus, the input device 200 is held by the carrier 100. The input device 200 can be separated from the carrier body 100a by being pulled out in the direction opposite to that at the time of insertion.

  The second mounting portion 103 is configured such that the display device 300 can be mounted on the carrier body 100a by inserting a connector portion 302 (see FIG. 5) provided on the back surface of the display device 300 from above. When the connector portion 302 is inserted into the second mounting portion 103 and locked, the display device 300 is held by the carrier body 100a. The display device 300 can be separated from the carrier main body 100a by pulling it upwards as opposed to inserting it.

  An engagement projection 106 and a third connector 107 are provided on the bottom 104 of the carrier body 100a. The bottom 104 of the carrier body 100a is placed above the upper surface 401 of the base unit 400 so that the engaging protrusion 106 is aligned with the position of the engaging recess 402 (see FIG. 4) provided on the upper surface 401 (see FIG. 4) of the base unit 400. The carrier protrusion 100 is engaged with the engagement recess 402, so that the carrier body 100a can be stably placed on the base unit 400. Further, when the engagement protrusion 106 engages with the engagement recess 402, the connector cover 403 (see FIG. 4) provided on the upper surface 401 of the base unit 400 is opened, and the base unit 400 disposed therein is opened. The third connector portion 107 of the carrier body 100a is connected to the connector portion 404 (see FIG. 5). The carrier body 100a can separate the carrier body 100a from the base unit 400 by pressing the lock release button 405 of the base unit 400 and holding the handle 101 of the carrier body 100a to lift the carrier body 100a upward.

  FIG. 4 is a rear perspective view showing the appearance of the base unit 400 (FIGS. 4A and 4B). The base unit 400 has a removable cover 406 on the back surface thereof. The cover 406 is a member for covering the network interface unit 407 and the like. After removing the cover 406, a connection means (for example, a LAN cable) that enables communication with an external device (in this embodiment, the data processing system 800) is connected to the network interface unit 407. The components of the information monitor 1 can be communicated with the external data processing system 800 via the communication network 700 (see FIG. 5). Further, the base unit 400 has a power cord connector portion 408 for connecting to a commercial power source 600 (see FIG. 5) on the back surface thereof. By connecting the power cord to the power cord connector 408, it is possible to receive power from the commercial power source 600.

  FIG. 5 is a block diagram showing a configuration of the biological information monitor 1, and schematically shows a functional configuration of each component. As described above, the biological information monitor 1 includes the carrier 100, the input device 200, the display device 300, and the base unit 400. In FIG. 5, solid lines connecting the blocks indicate transmission paths for various biological information data and operation signals, and dotted lines indicate power supply paths.

  The input device 200 includes an input connector unit 201, a connector unit 202, a measurement processing unit 203, a storage unit 204, a power supply control unit 205, and a clock unit 206.

The input connector unit 201 is a connector for connecting the biological information detection unit attached to the patient to the input device 200. In the present embodiment, the biological information detection unit detects an electrocardiogram electrode 501 for detecting an electrocardiogram, a blood pressure measurement cuff 502 for detecting blood pressure, a body temperature sensor 503 for detecting body temperature, and SpO ₂ . The SpO ₂ sensor 504 for detecting the cardiac output and the cardiac output sensor 505 for detecting the cardiac output are included, but the biological information detection unit is not limited thereto. Therefore, in this embodiment, the input connector unit 201 includes the first input connector unit 201a for connecting the electrocardiographic electrode 501, the second input connector unit 201b for connecting the blood pressure measurement cuff 502, and the body temperature sensor 503. A third input connector portion 201c for connecting the SpO ₂ sensor 504, a fourth input connector portion 201d for connecting the SpO ₂ sensor 504, and a fifth input connector portion 201e for connecting the cardiac output sensor 505. Yes. The input connector unit 201 functions as an interface between the connected biological information detection unit and the measurement processing unit 203.

  The clock unit 206 constituting the clock unit in the input device of the present invention measures time and generates date / time data indicating the time. In the present embodiment, the date / time data has a concept including data of year / month / day / hour / minute / second.

  The measurement processing unit 203 executes a predetermined measurement process by executing a program stored in the storage unit 204. Through this measurement process, the measurement processing unit 203 measures the biological information data of the patient using the biological information detection unit connected to the input connector unit 201. In addition, since the conventionally well-known thing is applicable about the measuring method of various biological information using the said biological information detection part, the detailed description is abbreviate | omitted here. In addition, the measurement processing unit 203 acquires date / time data at that time from the clock unit 206 when measuring the biological information data, and generates measurement result data that associates the measured biological information data with the acquired date / time data. Then, the measurement result data is stored in the storage unit 204. In addition, the measurement processing unit 203 reads measurement result data generated in the past and stored in the storage unit 204, and performs processing for outputting the data to the outside (hereinafter referred to as “measurement result data processing”). You can also. Specific operations of the measurement result data processing will be described later.

  The storage unit 204 stores a program executed by the measurement processing unit 203 and measurement result data generated by the measurement processing unit 203.

  The connector unit 202 constituting the communication connector unit of the present invention is connected to the first connector unit 105 of the carrier 100 when the input device 200 is mounted on the carrier 100, thereby electrically connecting the carrier 100 and the input device 200. It is a connector to be connected to. The power supply and biological information data transmission paths between the carrier 100 and the input device 200 are connected when the carrier 100 and the input device 200 are electrically connected, and the carrier 100 and the input device 200 are connected. Shut off when electrically disconnected.

  The power control unit 205 receives power supply from the outside of the input device 200 via the connector unit 202, and thereby drives each unit of the input device 200.

  As described above, in the present embodiment, measurement result data including the biological information data measured by the measurement processing unit 203 can be stored in the storage unit 204 in the input device 200. Therefore, the input device 200 can hold the biological information data measured from the patient inside regardless of whether the input device 200 is connected to the display device 300 or an external device. Moreover, since the input device 200 also has a built-in clock function, the measured biological information data can be stored in association with the date / time data at the time of measurement.

  The display device 300 includes a display unit 301, a connector unit 302, a clock unit 304, a display processing unit 305, a storage unit 306, and a power supply control unit 307.

  The connector unit 302 is a connector that is connected to the second connector unit 108 of the carrier 100 when the display device 300 is attached to the carrier 100, thereby electrically connecting the carrier 100 and the display device 300. The power supply path and the transmission path between the carrier 100 and the display device 300 are connected when the carrier 100 and the display device 300 are electrically connected, and the carrier 100 and the display device 300 are electrically connected. Blocked when disconnected.

  The display processing unit 305 executes a predetermined display process by executing a program stored in the storage unit 306. By this display processing, the display processing unit 305 causes the display unit 301 to display the biological information data in the form of measurement values or waveforms. The display processing unit 305 can display the biological information data on the display unit 301 in real time when performing display processing on the biological information data received from the outside via the connector unit 302. However, the display processing unit 305 can display the past biological information data in a form such as a trend graph by reading the biological information data stored in the storage unit 306 and performing display processing on the data. .

  The display unit 301 is a touch panel, for example, and has not only a display function for displaying biometric information data but also a function as an input unit that receives an input operation by an operator. When the display unit 301 receives an input operation by the operator, the display unit 301 generates an operation signal for operating each unit in the display device 300 or each unit in the biological information monitor 1 according to the content of the operation. The generated operation signal is appropriately transmitted through a transmission path in the display device 300 or the biological information monitor 1.

  The clock unit 304 counts time and generates date / time data indicating the time. This date / time data is displayed on the display unit 301 together with the biological information data, for example, during a patient monitoring operation.

  The storage unit 306 stores biometric information data displayed on the display unit 301 by display processing.

  The power control unit 307 receives power supply from the outside of the display device 300 via the connector unit 302, and thereby drives each unit of the display device 300.

  The base unit 400 includes a connector unit 404, a network interface unit 407, a main power supply unit 409, a standby power supply unit 410, and a power supply control unit 411.

  The connector unit 404 is a connector that electrically connects the carrier 100 and the base unit 400 when the carrier 100 is placed on the base unit 400 and the third connector unit 107 of the carrier 100 is connected to the connector unit 404. It is. The power supply path and the transmission path between the carrier 100 and the base unit 400 are connected when the carrier 100 and the base unit 400 are electrically connected, and the carrier 100 and the base unit 400 are electrically connected. Blocked when disconnected.

  The power control unit 411 supplies power to the carrier 100 via the connector unit 404. The power supply control unit 411 supplies the power supply from the main power supply unit 409 to the carrier 100 in normal times, but alternatively supplies the power supply from the standby power supply unit 410 to the carrier 100 in an emergency (for example, during a power failure). May be supplied.

  The main power supply unit 409 receives a power supply from an external commercial power supply 600 through a power cord connected to a power cord connector unit 408 (see FIG. 4), and includes a circuit that performs AC-DC conversion and the like. It is.

  The standby power supply unit 410 includes a charging unit 412 and a battery housing unit 413. The standby power supply unit 410 charges the battery stored in the battery storage unit 413 using the main power supply unit 409 as a driving power supply. The battery accommodating part 413 is comprised so that the battery which can be accommodated in the battery accommodating part 109 in the carrier 100 mentioned later can be accommodated. Therefore, the standby power supply unit 410 can charge the backup battery used in the carrier 100 in the base unit 400. In addition, the power supply from the battery after the charge accommodated in the battery accommodating part 413 can be used as a power supply for emergency.

  The network interface unit 407 is an interface that connects the base unit 400 to the communication network 700. By connecting the base unit 400 to the communication network 700, data communication between the input device 200 and the display device 300 of the biological information monitor 1 and the external data processing system 800 becomes possible.

  The carrier 100 includes a first connector unit 105, a second connector unit 108, a third connector unit 107, a transmission processing unit 110, a power supply control unit 111, and a standby power supply unit 112.

  Each of the first connector unit 105, the second connector unit 108, and the third connector unit 107 electrically connects the carrier 100 and each component as described above.

  The transmission processing unit 110 is configured to relay a transmission path between the first connector unit 105, the second connector unit 108, and the third connector unit 107, and includes the input device 200, the display device 300, and the base unit 400. Data transmission between them.

  The standby power supply unit 112 includes a charging unit 113 and a battery housing unit 109. The standby power supply unit 112 charges the battery stored in the battery storage unit 109 using the main power supply unit 409 as a driving power supply. In addition, the power supply from the battery after the charge accommodated in the battery accommodating part 109 can be used as a power supply for emergency.

  The power control unit 111 is a control unit that selects a driving power source for the input device 200 and the display device 300. That is, the power supply control unit 111 is configured to supply power from the standby power supply unit 112 (more specifically, a battery housed therein) in the carrier 100 and the base unit 400 (mainly the main power supply unit 409 in the base unit 400). ) Is selected as the drive power supply. For example, the power supply control unit 111 selects the power supply from the base unit 400 when the power supply from the base unit 400 can be received, and the power supply from the standby power supply unit 112 in the carrier 100 otherwise. select.

  The data processing system 800 is a data processing system used in a medical facility, for example, an electronic medical record system, a data processing system in an operation room or a general ward, and the like. The data processing system 800 includes a display unit and a storage unit (both not shown), and can display or store biological information data acquired from the outside (for example, the biological information monitor 1). .

  The data processing system 800 includes a clock unit 801. The clock unit 801 measures time and generates date / time data indicating the time. This date / time data is used for storage and display of biometric information data in the data processing system 800.

  Next, the operation of the biological information monitor 1 of the present embodiment will be described. Here, a case where biological information data about a specific patient is requested from the external device to the input device 200 of the biological information monitor 1 will be described. In the input device 200, it is assumed that the biological information data measured from the patient is stored in the storage unit 204 in advance as measurement result data before the request from the external device. The external device is a data processing system 800 connected to the biological information monitor 1 via the communication network 700. However, since the display device 300 of the biological information monitor 1 is an external device for the input device 200, the display device 300 connected to the input device 200 via the carrier 100 may be an external device.

  When biometric information data about a specific patient is requested from an external device, the input device 200 executes the measurement result data processing shown in the flowchart of FIG.

  First, the measurement processing unit 203 obtains date / time data of the current time (hereinafter referred to as “external current time”) generated in the external device from the external device, and the current time (hereinafter referred to as “internal”) generated in the clock unit 206. Date / time data (referred to as “current time”) is acquired from the clock unit 206 (step S10). Then, the measurement processing unit 203 determines the time difference between the external device and the input device 200 by comparing the external current time with the internal current time (step S20). And the measurement process part 203 reads the measurement result data from the memory | storage part 204 in consideration of the time difference determined by step S20 (step S30). And the measurement process part 203 performs a time difference reflection process with respect to the measurement result data read from the memory | storage part 204 (step S40). Then, the measurement processing unit 203 outputs the measurement result data subjected to the time difference reflection process to the external device.

  Hereinafter, the reading of the measurement result data in step S30 will be described more specifically with reference to FIG.

  In step S31, the measurement processing unit 203 determines which period of biometric information data is requested from the external device. If the entire period of the measurement result data stored in advance in the storage unit 204 is designated, the process proceeds to step 32, and a part of the period of the measurement result data stored in the storage unit 204 in advance Is specified, the process proceeds to step S33. Even if there is no designation, it is assumed that the entire period is designated, and the process proceeds to step S32. In step S32, the measurement processing unit 203 reads the measurement result data for the entire period, and in step S33, the measurement processing unit 203 determines whether or not there is a time difference between the external device and the input device 200 in step S20. Judgment is made with reference to the time difference judgment result.

  If there is no time difference (step S33: NO), the measurement processing unit 203 reads measurement result data including date / time data corresponding to a period designated from the external device (step S34). On the other hand, when there is a time difference (step S33: YES), the measurement processing unit 203 corrects the period specified by the external device based on the time difference (step S35).

  In step S <b> 36, the measurement processing unit 203 reads out measurement result data including date / time data corresponding to the corrected period from the measurement result data stored in the storage unit 204.

  As described above, in the present embodiment, when the measurement processing unit 203 reads the measurement result data stored in the storage unit 204, the time difference between the external device and the input device 200 is taken into consideration. Correct the period.

  For example, it is assumed that the external device requests biometric information data “12: 0 to 12:10” in a situation where the internal current time is 10 minutes ahead of the external current time. In this case, the measurement processing unit 203 corrects the period (12: 0 to 12:10) designated by the external device by 10 minutes and corrects it to (12:10 to 12:20), and the corrected period (12: 10-12: 20) The measurement result data including the date / time data corresponding to 10:12:20) is read out. If the internal current time is 10 minutes behind the external current time, the measurement processing unit 203 returns the period designated by the external device by 10 minutes, and the corrected period (11:50 to 12:00) Read out the measurement result data including the corresponding date and time data. Thereby, even if there is a time difference between the external device and the input device 200, the measurement processing unit 203 can read out the biological information data corresponding to the period requested by the external device. Therefore, it is possible to accurately read out the biological information data that the external device truly requests.

  Next, the time difference reflection process in step S40 will be described with reference to the flowchart shown in FIG.

  In step S41, the measurement processing unit 203 determines whether or not there is a time difference between the external device and the input device 200 with reference to the time difference determination result in step S20. If there is no time difference (step S41: NO), the measurement processing unit 203 ends the time difference reflection process. On the other hand, when there is a time difference (step S41: YES), the measurement processing unit 203 generates time difference data indicating the time difference, and adds the time difference data to the measurement result data read from the storage unit 204 (step S41). S42). The measurement result data to which the time difference data is added is output to the external device in the above-described step S50. That is, the input device 200 can provide past biological information data requested from the external device to the external device.

  As described above, in the present embodiment, when there is a time difference, the time difference can be transmitted to the external device using the time difference data. For example, in a situation where the internal current time is advanced by 10 minutes from the external current time, the time difference data indicating that the date / time data included in the measurement result data read from the storage unit 204 is advanced by 10 minutes is the measurement result. The data is output from the input device 200 to the external device together with the data. In a situation where the internal current time is 10 minutes behind the external current time, the time difference data indicating that the date / time data included in the measurement result data read from the storage unit 204 is 10 minutes behind is the measurement result. The data is output from the input device 200 to the external device together with the data. Therefore, in the external device, even if the period of the date / time data included in the measurement result data read by the input device 200 does not match the period specified in advance, the measurement result data is appropriately determined based on the transmitted time difference. Can be corrected. Thereby, the external device can reliably acquire necessary past biological information data.

  In the time difference reflection process, the time difference is reflected in the measurement result data by adding the time difference data. However, the time difference reflection process is not limited to the above. For example, the time difference reflection process shown in the flowchart of FIG. 9 may be performed.

  In the time difference reflection process shown in FIG. 9, step S43 described below is executed instead of step S42 in the time difference reflection process shown in FIG. In step S43, the measurement processing unit 203 corrects the date / time data included in the measurement result data read from the storage unit 204 based on the time difference. For example, in a situation where the internal current time is 10 minutes ahead of the external current time, correction is performed to return the date time data included in the measurement result data read from the storage unit 204 by 10 minutes, and the corrected date time Measurement result data including data is output from the input device 200 to an external device. In a situation where the internal current time is 10 minutes behind the external current time, correction is performed to advance the date / time data included in the measurement result data read from the storage unit 204 by 10 minutes, and the corrected date time Measurement result data including data is output from the input device 200 to an external device. Therefore, regardless of whether or not there is a time difference between the external device and the input device 200, the external device does not have to perform processing for correcting the time difference on the measurement result data output from the input device 200. That is, the time difference reflection process shown in FIG. 9 is advantageous over the time difference reflection process shown in FIG. 8 in that an additional process for an external device is not necessary. In addition, the date / time data corrected by the time difference reflection process is the date / time data included in the measurement result data read from the storage unit 204, and therefore is included in the measurement result data itself held in the storage unit 204. It is also advantageous in that the date / time data that is stored is not changed.

  Note that the display device connected to the input device 200 may be replaced with another display device from the display device 300. At this time, the measurement processing unit 203 can execute measurement result data processing even when biometric information data about a specific patient is requested from the display device after replacement to the input device 200. Thereby, even if there is a time difference between the display device 300 before the replacement and the display device after the replacement, the input device 200 can accurately obtain the biological information data that the display device after the replacement truly requests. It is possible to read out the biometric information data necessary for the display device after replacement.

  Although the embodiment of the present invention has been described above, the above description is an illustration of a preferred embodiment of the present invention, and the scope of the present invention is not limited to this. Therefore, the above embodiment can be implemented with various modifications.

DESCRIPTION OF SYMBOLS 1 Biological information monitor 100 Carrier 100a Carrier main body 101 Handle part 102 1st mounting part 103 2nd mounting part 104 Bottom part 105 1st connector part 107 3rd connector part 108 2nd connector part 109, 413 Battery accommodating part 110 Transmission processing part 111 205, 307, 411 Power control unit 112, 410 Standby power unit 113, 412 Charging unit 200 Input device 201 Input connector unit 202, 302, 404 Connector unit 203 Measurement processing unit 204, 306 Storage unit 206, 304, 801 Clock unit DESCRIPTION OF SYMBOLS 300 Display apparatus 301 Display part 305 Display processing part 400 Base unit 407 Network interface part 409 Main power supply part 700 Communication network 800 Data processing system

Claims (4)

An input device that constitutes a biological information monitor together with a separate display device,
An input connector unit for connecting a biological information detection unit mounted on a patient;
A communication connector for connecting an external device and the input device in a communicable manner;
A clock section in the input device for measuring time, and
A storage unit for storing data;
The biological information is measured by measuring the biological information data from the patient via the biological information detecting unit connected to the input connector unit and acquiring the date / time data at the time of measurement from the clock unit in the input device. A measurement processing unit that associates data and acquired date / time data with each other and stores them in the storage unit as measurement result data;
Have
The measurement processing unit
When outputting the measurement result data stored in the storage unit to the external device via the communication connector unit, the measurement result data after being read from the storage unit and before being output to the external device As time difference reflection processing to reflect the time difference between the external device and the input device ,
Obtaining the time counted in the external device from the external device,
By comparing the time acquired from the external device with the time measured by the clock unit in the input device, the time difference between the external device and the input device is determined,
The date and time data included in the measurement result data after being read from the storage unit and before being output to the external device is corrected based on the determined time difference.
Biological information monitor input device. An input device that constitutes a biological information monitor together with a separate display device,
An input connector unit for connecting a biological information detection unit mounted on a patient;
A communication connector for connecting an external device and the input device in a communicable manner;
A clock section in the input device for measuring time, and
A storage unit for storing data;
The biological information is measured by measuring the biological information data from the patient via the biological information detecting unit connected to the input connector unit and acquiring the date / time data at the time of measurement from the clock unit in the input device. A measurement processing unit that associates data and acquired date / time data with each other and stores them in the storage unit as measurement result data;
Have
The measurement processing unit
When the measurement result data stored in the storage unit is output to the external device via the communication connector unit during the period specified by the external device, after being read from the storage unit and As a time difference reflecting process for reflecting the time difference between the external device and the input device in the measurement result data before being output to the external device,
Obtaining the time counted in the external device from the external device,
By comparing the time acquired from the external device with the time measured by the clock unit in the input device, the time difference between the external device and the input device is determined,
Correcting the specified period based on the determined time difference, and reading out measurement result data including date and time data corresponding to the corrected period as measurement result data of the specified period;
Biological information monitor input device. The external device is a data processing system connected via a communication network.
The input device for a biological information monitor according to claim 1 or 2 . The external device is the separate display device.
The input device for a biological information monitor according to claim 1 or 2 .

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