JP2017077344A - Biological information measuring device, and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a biological information measuring device having a function for differentiating an action according to whether the device is in transit or not in transit; and to provide a control method thereof.SOLUTION: At least one of a measurement action of biological information of a patient and a display action of measured biological information is differentiated according to determination made as to whether a biological information measuring device is in transit or not in transit. It may be determined automatically or designated by a user whether the device is in transit or not in transit.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a biological information measuring apparatus and a control method thereof.

A biological information measuring device such as a biological information monitor or a telemeter continuously measures so-called vital signs such as an electrocardiogram, respiratory rate, heart rate, blood pressure, body temperature, arterial oxygen saturation (SpO ₂ ), and the measurement result. It is a device that transmits and displays in real time. There are two types of biological information measuring devices: a stationary type and a portable type. Either one is used depending on the application, but a portable type can be used as a stationary type or a stationary type input. Some have a configuration that can be used as a module (Patent Document 1).

JP 2014-132931 A

  The portable biological information measuring device has a smaller display screen than the stationary type for downsizing. Therefore, when the same display as that of the stationary type is performed, the display is reduced in accordance with the size of the display screen, and the visibility and legibility of the biological signal waveform and the measurement value are worse than those of the stationary type. However, even if the conventional portable biological information measuring apparatus is used as a stationary type at the bedside, the display form does not change even when it is used while being transported with the patient to be measured.

  During patient transportation, the screen readability may be lower than when used at the bedside due to vibration or changes in the brightness of the environment. It would be useful if the display format could be improved. However, the conventional portable biological information measuring device does not have a function of changing the operation depending on whether it is being transported or not.

  The present invention has been made in view of such a problem of the prior art, and an object of the present invention is to provide a biological information measuring apparatus having a function of changing the operation depending on whether it is being conveyed or not, and a control method therefor.

  The above-described object is to provide portable biological information having measuring means for measuring biological information of a patient, display means for displaying the measured biological information in real time, and control means for controlling the operation of the measuring means and the display means. In the measurement device, the control unit makes the operation of at least one of the measurement unit and the display unit different between a case where it is determined that the biological information measurement device is being transported and a case where it is determined that the biological information measurement device is not being transported. This is achieved by a biological information measuring device characterized by this.

  With such a configuration, according to the present invention, it is possible to provide a biological information measuring apparatus having a function of changing the operation depending on whether it is being conveyed or not, and a control method therefor.

It is a block diagram which shows the function structural example of the biological information monitor as an example of the biological information measuring device which concerns on embodiment of this invention. It is a perspective view which shows the example of an external appearance of the biometric information monitor and docking station which concern on embodiment. It is a flowchart for demonstrating the operation | movement at the time of the measurement of the biological information monitor which concerns on embodiment. It is a figure which shows the example of a screen display of the biometric information monitor which concerns on embodiment.

  Hereinafter, the present invention will be described in detail based on exemplary embodiments with reference to the drawings. Hereinafter, an embodiment in which the present invention is applied to a portable biological information monitor as an example of a portable biological information measuring device will be described. The term “portable” as used herein means that the battery can be driven and can be moved with the patient while measuring biological information.

  FIG. 1 is a block diagram showing a functional configuration example of a portable biological information monitor 100 according to an embodiment of the present invention and a docking station (base unit) 200 for using the portable biological information monitor 100 as a stationary monitor device. It is. FIG. 2 is a perspective view showing an external appearance example of the portable biological information monitor 100 (hereinafter simply referred to as a biological information monitor) and the docking station 200 of the present embodiment.

  As will be described later, the biological information monitor 100 according to the present embodiment has a transporting mode and a non-transporting mode as operation modes, and the operation of the apparatus differs between the transporting mode and the non-transporting mode. The non-transporting mode is an operation mode that assumes that the biological information monitor 100 is used in a stationary state (stable environment) as in the case where the biological information monitor 100 is used as a stationary biological information monitor at the bedside. It is. On the other hand, the in-transport mode is an operation mode that is assumed to be used in a state where the biological information monitor 100 is moving (unstable environment) as in the case where the biological information monitor 100 is being transported with the patient. . Switching between the in-conveyance mode and the non-conveyance mode can be performed automatically or in response to a user instruction.

The biological information monitor 100 includes an input unit 110 to which various sensors and measurement modules can be connected. The biological information monitor 100 constantly monitors a patient's state by displaying biological signals sequentially obtained from the sensors and detecting abnormalities. It is a device for doing. Since the biological information monitor 100 is usually used for patients who need to monitor vital signs, such as critically ill patients, a plurality of living bodies such as an electrocardiogram, respiratory rate, heart rate, blood pressure, body temperature, arterial oxygen saturation (SpO ₂ ) and the like are used. It has a function to measure information.

  The input unit 110 includes connectors and interfaces that mechanically and electrically connect various sensors and measurement modules. In the present embodiment, it is assumed that the following sensors and measurement modules are connected as an example. In addition, depending on the measurement module connected to the input unit 110, bidirectional communication is possible.

  The electrocardiogram electrode 111 is composed of a plurality of electrodes attached to a predetermined part of the patient's limbs and / or chest surface, and detects an induced waveform corresponding to the attachment part. The number and type of electrocardiographic electrodes 111 vary depending on the number and type of induced waveforms to be measured. Further, the respiration rate can be calculated by an impedance method in which a thin high-frequency current is passed between the electrocardiographic electrodes to measure the impedance of the rib cage and the movement of the rib cage is detected from the change. A blood pressure transducer 112 is attached to the end of a catheter inserted into the patient's blood vessel and converts blood pressure into an electrical signal.

The pulse wave / SpO ₂ sensor 113 is a so-called pulse oximeter, which optically detects and inputs arterial blood oxygen saturation (SpO ₂ ) and fingertip volume pulse wave. Utilizing the fact that the light absorbance of hemoglobin varies depending on whether it is associated with oxygen, and also the absorbance varies depending on the wavelength of light. Generally, arterial oxygen saturation is obtained using two wavelengths of red light and infrared light. Measure. Further, since the AC component of the transmitted light or reflected light changes according to the blood volume, this AC component is detected as an optical fingertip volume pulse wave (PTG: photoplethysmograph).

The body temperature sensor 114 is, for example, a thermistor temperature sensor attached to a patient, and indicates a resistance value corresponding to the temperature. The cardiac output sensor 115 is a thermistor temperature sensor placed in the blood vessel of the patient, and measures the blood temperature. A thermodilution curve is obtained from the time change of the blood temperature, and the cardiac output (CO) can be obtained from an equation applying the infusate temperature and the Stewart-Hamilton formula. Further, vascular resistance (SVR) can be obtained from the cardiac output and the blood pressure value. The cardiac output may be obtained non-invasively by the impedance method. The respiratory gas sensor 116 measures the carbon dioxide (CO ₂ ) concentration in the exhaled breath. Note that the sensors and modules connected to the input unit 110 illustrated in FIG. 1 are merely examples, and other components may be included, or some of the illustrated components may be omitted.

  The non-invasive blood pressure monitor 117 includes a cuff, a pump, an exhaust valve, a pressure sensor, and the like. By acquiring the signal from the pressure sensor, blood pressure can be measured noninvasively by the oscillometric method. Since non-invasive blood pressure cannot be continuously measured, measurement is performed at predetermined intervals. The operation of the non-invasive blood pressure monitor 117 (operation of the pump and the exhaust valve) is controlled by the control unit 140 through the input unit 110. In the present embodiment, the operation of the non-invasive blood pressure monitor 117, more specifically, the exhaust speed is different between the in-transport mode and the non-transport mode.

  The pre-processing unit 120 performs a pre-determined operation on the biological signal input to the input unit 110 according to a signal, such as application of an A / D conversion process, a power supply noise removal filter, and a band removal filter (LPF, HPF, etc.). The process is executed and stored in the buffer memory 130. In the present embodiment, the cutoff frequency of the low-frequency cut filter that the preprocessing unit 120 applies to the electrocardiogram signal is different between the in-transport mode and the non-transport mode. The preprocessing unit 120 may be configured by hardware such as a DSP or an ASIC, or at least a part of functions may be realized by software by the control unit 140. The buffer memory 130 is used as a temporary storage of signals, a work area of the control unit 140, and a video memory.

  The control unit 140 has a programmable processor such as a central processing unit (CPU), a RAM, and a ROM, and controls the operation of the biological information monitor 100 by loading a program stored in the ROM into the RAM and executing it by the CPU. To achieve the overall functionality. Note that at least a part of the ROM may be rewritable.

  The external interface (I / F) 150 is a communication interface with the docking station 200, and is connected to the external interface 220 of the docking station 200 directly or via a connector provided on a housing of the apparatus. The control unit 140 can detect whether the docking station 200 is connected and whether power is supplied from the docking station 200.

  The alarm indicator 160 is alerted by light or sound, for example, when the control unit 140 determines that the operation of the device, the waveform or numerical value of the biological signal, etc. satisfy the conditions defined in a predetermined condition (alarm setting). Are one or more output devices for outputting and notifying. The alarm indicator 160 may typically be a light emitting element or a speaker. Alarms can be classified according to importance (level), and alarms according to importance can be output. The alarm can be combined with not only the alarm indicator 160 but also a message display on the touch display 170. For example, when a predetermined operation on the operation unit 180 is detected, the control unit 140 stops outputting the alarm.

  The touch display 170 is a display device having a touch panel function. The control unit 140 causes the touch display 170 to display important biological information such as an electrocardiogram waveform, a heart rate, a body temperature, a blood pressure value, a respiration rate, and a respiration waveform in real time according to a predetermined layout. In addition, the control unit 140 changes the content and / or layout displayed on the touch display 170 in response to an instruction from the operation unit 180. In the present embodiment, at least one of the content or layout displayed on the touch display 170 and the display luminance is different between the in-transport mode and the non-transport mode.

  The operation unit 180 is a key and switch group including a power switch, and allows the user to input instructions and information to the biological information monitor 100. Note that at least some of the switches and keys may be implemented as software switches that combine a touch panel provided on the touch display 170 and a GUI display by the control unit 140. The operation unit 180 may include an external key or switch.

  The motion sensor 185 may be an acceleration sensor, a gyro, or the like, for example, and outputs a signal representing the movement of the biological information monitor 100. The control unit 140 determines whether the output of the motion sensor 185 is in a state where the biological information monitor 100 is stationary (not being transported) or in a state of being moved (during transport), or the magnitude of the motion. It can be used to discriminate.

  The wireless communication unit 190 causes the biological information monitor 100 to transmit data that has been measured and information about an event that has occurred during the measurement to an external device such as a central monitor device or another biological information measurement device that takes over measurement of biological information. Used for. There is no particular limitation on the protocol used for the wireless communication, and for example, a proximity wireless communication (NFC) protocol such as Wi-Fi (IEEE802.11x), Bluetooth (registered trademark), IrDA, ISO / IEC 18092, or the like can be used. Also, a plurality of communication methods may be combined, such as Bluetooth / Wi-Fi handover in which NFC is used for authentication processing and communication after authentication processing is performed by Bluetooth or Wi-Fi. Instead of the wireless communication unit 190 (or in addition to the wireless communication unit 190), a wired communication unit for realizing the same function may be included.

  In addition to the illustrated configuration, a configuration for handling a memory card (such as a memory card slot) and a printer (recorder) may be included. The biological information monitor 100 can be driven by a battery, but can be supplied with power from the docking station 200 through the external I / F 150 when connected to the docking station 200. When power is supplied through the external I / F 150, the biological information monitor 100 operates with the power from the external I / F 150 and charges the built-in battery.

  In the biological information monitor 100 having such a configuration, for example, when the power is turned on through the operation unit 180, processing for a biological signal input through the input unit 110 is started. Specifically, the preprocessing unit 120 performs A / D conversion and the like, and starts storing various biological signals in the buffer memory 130 as measurement data. Then, the control unit 140 starts various parameter calculation processing, display processing, evaluation processing, abnormality determination processing, and the like for the measurement data stored in the buffer memory 130. In addition, the control unit 140 transfers measurement data from the buffer memory 130 to the storage unit 195, or when a predetermined event occurs, the control unit 140 associates predetermined information such as measurement data at that time with the event in the storage unit 195. Save it. The control unit 140 further analyzes the measured biological signal, generates a report in a predetermined format, and displays the report as required. There are various types of reports, but trend displays that are useful for grasping changes in biological signals over time and occurrences of events are typical examples of reports.

  The docking station 200 reads data stored in the storage unit 195 of the biological information monitor 100 and transmits the data to an external device for managing the biological information monitor 100 and patient-related data, such as a central monitor and a server device. An external device that provides a function. If the biological information monitor 100 is connected in a measurement state, the docking station 200 outputs measurement data to an external device in real time.

  The external I / F 220 is a communication interface for connecting the biological information monitor 100. The external I / F 200 is also used to supply power to the connected biological information monitor 100. Therefore, the docking station 200 is also an external power source for the biological information monitor 100. The buffer memory 240 is used for temporarily storing measurement data received through the external I / F 220 or used as a work area for the control unit 210. The control unit 210 includes a programmable processor such as a central processing unit (CPU), a RAM, and a ROM, and controls the operation of the docking station 200 by loading a program stored in the ROM into the RAM and executing it by the CPU. To realize the overall function. Note that at least a part of the ROM may be rewritable.

The operation unit 230 is a key and switch group including a power switch. When the biological information monitor 100 is connected, some functions of the operation unit 180 of the biological information monitor 100 can be invalidated and the operation of the operation unit 230 can be validated.
The communication unit 250 is connected to a hospital network and is used to communicate with an external device on the network. The communication unit 250 may be a wired communication unit or a wireless communication unit.
Bus 260 interconnects the components of docking station 200.

FIG. 2A is a perspective view showing an example of the external appearance of the biological information monitor 100, and the same reference numerals are assigned to the same components as those in FIG.
As shown in FIG. 2C, the docking station 200 is provided with a space for mounting the biological information monitor 100. The biological information monitor 100 can be attached to the docking station 200 by directly fitting the connector of the external I / F 150 provided at the lower right side to the connector of the external I / F 220 of the docking station 200. In addition, not only the connector of the external I / F 220 but also the casings of the biological information monitor 100 and the docking station 200 are fitted to prevent the biological information monitor 100 from being inadvertently detached. FIG. 2B shows a state in which the biological information monitor 100 is connected to the docking station 200.

  Next, the operation | movement at the time of the measurement of the biological information monitor 100 of this embodiment is demonstrated using the flowchart shown in FIG. As described above, the biological information monitor 100 constantly measures the biological signal of the patient according to the control of the control unit 140, and displays predetermined information based on the measurement value in real time (S10).

  FIG. 4A shows an example of the layout (first layout) of the display screen 300 of the touch display 170 in the non-transporting mode of the biological information monitor 100 of the present embodiment. The first layout includes a bibliographic information area 310 for displaying bibliographic information such as patient information such as ID and gender and date and time information, a waveform area 320 for displaying a waveform of a predetermined biological signal, and a measurement value of biological information. Has a measurement value area 330 and a user key area 340 for displaying user keys. The user key has a plurality of selectable areas having a button-like appearance, and a predetermined function is assigned to each area. The function to be assigned can be set by the user and can be used as a so-called shortcut key.

  The control unit 140 monitors whether the biological information monitor 100 is moving (transporting) or stationary (not transporting) while performing the measurement operation and the normal display in S10. (S15). The control unit 140 advances the process to S20 when it is determined that the sheet is being conveyed, and advances the process to S40 when it is determined that the sheet is not being conveyed.

  The determination in S15 can be performed based on various information. However, when the biological information monitor 100 (the control unit 140) automatically determines whether the conveyance is in progress or not, at least in the present embodiment, It is determined that the biological information monitor 100 is being transported when the battery is driven. Therefore, the control unit 140 determines that the biological information monitor 100 is not transported if it is driven by a power source supplied from the outside, and is being transported if the biological information monitor 100 is driven by the built-in battery. be able to.

In addition to being driven by a battery, the biological information monitor 100 may be determined to be carrying when one or more other conditions are satisfied. Examples of other conditions include the following conditions.
・ External devices (such as docking station 200 and other medical devices) are not connected to the external I / F 150. ・ The output of the motion sensor 185 continuously exceeds a predetermined threshold for a certain period of time. Information obtained from biological information, such as an increase in noise included in biological information, satisfies a predetermined condition. In addition, it is set in advance what conditions are used to determine whether the information is being conveyed or not. be able to.

  Alternatively, in S15, the control unit 140 determines whether or not the setting of the in-transport mode is designated through the operation unit 180, and determines that the in-conveyance mode is set if it is determined that the setting of the in-conveyance mode is designated. If it is not determined that the mode setting is designated, it may be determined that the sheet is not being conveyed. Thus, in the present embodiment, the user can directly specify whether or not the biological information monitor 100 is being transported. Thereby, for example, when the conveyance state of the biological information monitor 100 cannot be automatically detected or when the user desires, the biological information monitor 100 can be reliably and easily operated in the conveying mode. . Since the user's designation has priority over the automatic determination by the biological information monitor 100, if the user designates, the biological information monitor 100 operates in the in-transport mode even if it is driven by a power source supplied from the outside. Similarly, when cancellation of the in-transport mode (setting of the non-transport mode) is designated through the operation unit 180, priority is given to automatic determination by the biological information monitor 100.

  When it is determined that the biological information monitor 100 is being transported (moving), the control unit 140 determines in S20 whether or not it has been transported from non-transport. Then, the control unit 140 advances the process to S30 if it is determined that the sheet is not being transferred from the non-transfer state, and if it is not determined that the transfer is being performed from the non-transfer state (if it is continuously determined that the transfer is being performed). ) Return the process to S10.

In S <b> 30, the control unit 140 sets the in-transport mode in the biological information monitor 100. Specifically, the setting is changed so that the predetermined operation is different from the non-transporting mode. As described above, in the biological information monitor 100 of the present embodiment,
(1) Display contents of biological information (2) Display method of biological information (3) Display brightness of biological information (4) Cut-off frequency of filter applied to electrocardiogram signal (5) Cuff of non-invasive blood pressure measurement One or more decompression speeds are different between the non-transporting mode and the transporting mode. However, these are merely examples, and other items may be configured to differ between the non-transporting mode and the transporting mode.

  For example, the setting value group for the non-transporting mode and the setting value group for the transporting mode are stored in the storage unit 195 in advance, and the control unit 140 acquires the setting value group from the storage unit 195 and reflects it. As a result, the operation mode can be switched. These set values may be customizable by the user.

  On the other hand, when it is not determined in S15 that the biological information monitor 100 is being transported, in S40, the control unit 140 determines whether or not the transport is changed from being transported to non-transporting. Then, if it is determined that the conveyance is not being performed, the control unit 140 advances the process to S50 and sets the non-conveying mode in the biological information monitor 100, and is determined that the conveyance is not being performed. If not (if it is determined that it is not being conveyed continuously), the process returns to S10.

Next, the operation in the transporting mode and the non-transporting mode will be specifically described.
FIG. 4B shows an example of the layout (second layout) of the display screen 300 of the touch display 170 in the transporting mode of the biological information monitor 100 of the present embodiment. The second layout includes areas 310 to 340 similar to the first layout, but the waveform area 320 ′ and the measurement value area 330 ′ are different in display content and display method.

  Specifically, in the second layout, at least one of the number and the length of the displayed waveforms is reduced for the waveform area 320 ', and the display is enlarged for the measurement value area 330'. The measurement value region 330 ′ may be reduced without reducing the number of display items. In the example of FIG. 4B, the display of the respiration rate is reduced, which contributes to the expansion of the measurement value region 330 '.

  The purpose of the second layout is to improve the visibility or legibility of the specific biometric information that is necessary at the minimum during transport, as compared with the non-transport mode. Therefore, it is not always necessary to increase the display size except for specific biological information. Further, visibility or legibility may be improved by a method other than increasing the display size. For example, the display color can be changed to a color that increases the contrast with the background color. In this case, it is preferable to display using the same color as before the change. This is because, in this type of apparatus, the display color and the type of measurement value may be associated with each other.

  In addition, the control unit 140 can increase the display brightness of the touch display 170 in the transporting mode in consideration of a change in the environment, particularly brightness, during the transporting. In general, it is unlikely that the patient will be transported for a long time, and the biological information monitor is also unlikely to be driven by a battery for a long time, so ensuring or improving visibility is better than saving power consumption. Prioritize.

  Further, the control unit 140 can set the cutoff frequency of the filter applied to the electrocardiogram signal in the in-transport mode to be higher than that in the non-transport mode. Specifically, the time constant of the filter may be reduced. During transport, the base line of the electrocardiogram signal may fluctuate greatly due to the influence of external noise or the like. However, by reducing the time constant of the filter, the base line fluctuation can be suppressed and the stability of the base line can be increased.

  In addition, the control unit 140 can lower the cuff pressure reduction speed when measuring the non-invasive blood pressure in the in-transport mode than in the non-transport mode. For example, it can be 10 mmHg / second in the non-transporting mode and 5 mmHg / second in the transporting mode. Considering the vibration during movement and slowing down the decompression speed, it becomes easier to catch the pulse and measurement can be performed reliably. Note that, when the in-transport mode is set during the measurement of the non-invasive blood pressure, the measurement is once ended, and the measurement based on the setting in the in-transport mode is performed again.

  Note that when it is determined that the movement of the biological information monitor 100 is small, for example, when the output of the motion sensor 185 is less than the threshold value for a certain period of time during operation in the conveying mode, the decompression in the non-invasive blood pressure The measurement time may be shortened by returning the speed to the value in the non-transport mode.

  As described above, according to the present embodiment, the operation of the portable biological information measuring device is performed depending on whether the device is determined to be transporting or not (or determined not to be transporting). Can be different. In particular, the operation mode includes a transport mode and a non-transport mode, and the operation mode is set by associating the setting suitable for the operation during transport and the setting suitable for the operation during non-transport with the operation mode. Settings can be changed at once by switching. Therefore, the usability of the portable biological information measuring device can be greatly improved. Further, in the in-transport mode, an operation suitable for the transport can be realized, so that it can be expected that measurement accuracy is improved and monitoring of changes in important biological information becomes easy. In particular, when it is automatically determined whether or not the biological information measuring device is carrying, it is not necessary for the user to explicitly specify the operation mode, so the effect is further increased.

(Other embodiments)
In place of or in addition to the output of the motion sensor 185, whether or not the biological information monitor 100 is carrying the output of a positioning sensor such as a GPS receiver or the access point information obtained by the wireless communication unit 190 is determined. You may use for the conditions in.

  The present invention can also be realized as a program that causes the processing according to the above-described embodiment to be performed by one or more processors in the computer of the system or apparatus. Therefore, such a program and a computer-readable recording medium recording the program also constitute the present invention. Further, the processing according to the above-described embodiment can be performed using hardware (for example, ASIC, programmable logic, or the like).

DESCRIPTION OF SYMBOLS 100 ... Biometric information monitor, 110 ... Input part, 120 ... Pre-processing part, 130 ... Buffer memory, 140, 210 ... Control part, 170 ... Display part, 180 ... Operation part, 200 ... Docking station

Claims (18)

A measuring means for measuring the biological information of the patient;
Display means for displaying the measured biological information in real time;
A portable biological information measuring device having a control means for controlling the operation of the measuring means and the display means,
The control means makes the operation of at least one of the measurement means and the display means different between a case where the biological information measurement device is determined to be transporting and a case where it is not determined to be transporting. A biological information measuring device as a feature.   The control means determines that at least one of the measurement means and the display means is being carried by the biological information measurement device in response to an input designating that the biological information measurement device is being carried. The biological information measuring device according to claim 1, wherein the biological information measuring device is different from a case where the biological information is not performed. A determination means for determining whether or not the biological information measuring device is being conveyed;
In response to the determination by the determination unit that the biological information measurement device is being transported, the control unit performs at least one operation of the measurement unit and the display unit while the biological information measurement device is being transported. The biological information measuring device according to claim 1, wherein the biological information measuring device is different from a case where it is not determined that the biological information is present.   4. The biological information measuring device according to claim 3, wherein the determining means determines that the biological information measuring device is being transported based on at least the biological information measuring device being driven by a battery. . An acceleration sensor;
5. The biological information measurement according to claim 3, wherein the determination unit determines that the biological information measurement device is carrying when the output of the acceleration sensor satisfies a predetermined condition. apparatus.   6. The determination unit according to claim 3, wherein the determination unit determines that the biological information measurement device is carrying when the biological information measured by the measurement unit satisfies a predetermined condition. The biological information measuring device according to claim 1.   The said determination means determines that the said biometric information measuring device is conveying when the signal different from the biometric information which the said measurement means measured satisfy | fills the predetermined condition. Item 7. The biological information measuring device according to any one of items 6 to 6.   The said determination means determines that the said biometric information measuring device is conveying when the external apparatus is not connected to the said biometric information measuring device, The any one of Claim 3-7 characterized by the above-mentioned. The biological information measuring device according to item.   When it is determined that the biological information measuring device is being transported, the control means is configured to improve the visibility of display related to specific biological information, compared to the case where it is not determined that the biological information measuring device is being transported. The biological information measuring device according to any one of claims 1 to 8, wherein the means is controlled.   The control means controls the display means so that the display brightness is higher when it is determined that the biological information measuring device is being transported than when it is not determined that the biological information measuring device is being transported. The biological information measuring device according to any one of claims 1 to 8.   When it is determined that the biological information measuring device is being transported, the control means is configured so that at least one of a size or a color for displaying specific biological information is different from a case where it is not determined that the biological information measuring device is being transported. The biological information measuring device according to claim 9 or 10, wherein the display means is controlled.   When it is determined that the biological information measuring device is being transported, the control means is configured to reduce the number of items of the biological information to be displayed, compared to a case where it is not determined that the biological information measuring device is being transported. It controls, The biological information measuring device of any one of Claim 9 to 11 characterized by the above-mentioned. The biological information includes an electrocardiogram signal,
When it is determined that the biological information measuring device is being transported, the control means increases the cutoff frequency of the filter applied to the electrocardiogram signal, compared to a case where it is not determined that the biological information measuring device is being transported. The biological information measuring apparatus according to any one of claims 1 to 12, wherein the measuring means is controlled. The measurement means measures blood pressure using a cuff as one of the biological information,
When it is determined that the biological information measurement device is being transported, the control means is configured to decrease the pressure reduction speed of the cuff than when the biological information measurement device is not determined to be being transported. The biological information measuring apparatus according to claim 1, wherein the measuring unit is controlled. A measuring means for measuring the biological information of the patient;
Display means for displaying the measured biological information in real time;
A portable biological information measuring device having a control means for controlling the operation of the measuring means and the display means,
The operation mode includes a transporting mode that assumes a state in which the biological information measurement device is transported and a non-transporting mode that assumes a state in which the biological information measurement device is not transported,
The biological information measuring apparatus according to claim 1, wherein the control means makes the operation of at least one of the measurement means and the display means different between the in-transport mode and the non-transport mode. A measuring means for measuring the biological information of the patient;
A control method of a portable biological information measuring device having display means for displaying the measured biological information in real time,
It has a control process in which the operation of at least one of the measurement unit and the display unit is made different between a case where it is determined that the biological information measuring device is being transported and a case where it is not determined that it is being transported. A control method of the biological information measuring device. A measuring means for measuring the biological information of the patient;
A display means for displaying the measured biological information in real time, and a control method for a portable biological information measuring device,
The biological information measuring device has an operation mode of a transporting mode assuming that the biological information measuring device is transported and a non-transporting mode assuming a state where the biological information measuring device is not transported. Have
A control method for a biological information measuring device, comprising: a control step of causing at least one operation of the measuring unit and the display unit to differ between the in-transport mode and the non-transport mode.   One or more processors included in a portable biological information measuring device having a measuring means for measuring biological information of a patient and a display means for displaying the measured biological information in real time. The program for performing the control method of the biological information measuring device of description.