KR101161311B1 - Patient monitoring system using medical wireless telemetry communication - Google Patents

Abstract

The present invention is to wirelessly transmit the vital signs of the patient collected by the PMS to the sub-monitoring device, so that the PMS information of various groups can be managed in one place, the patient monitoring system of the medical wireless telecommunication method A sensor 11 for collecting a bio-signal of a patient; and a converter 150 for converting a digital format of the bio-signal collected by the sensor 11 into an analog signal and a transmission frequency band. The control unit 123 and the channel for transmitting the channel information including the selection signal to the channel setting switch 124 for receiving the selection signal for the set channel, the PLL (120a) for controlling the local oscillation frequency of the VCO (120b) And a mixer 140 for merging the analog signal to the local oscillation frequency generated according to the information and converting the analog signal into an RF signal for wireless transmission. A PMS (10); and a mixer for receiving and converting the RF signal and filtering the analog signal including the frame format, a converter for converting the analog signal into a digital signal, and the digital signal. A communication device (100 ') including a demodulation modem, a memory for storing the protocol, and a data processing unit for analyzing the frame format of the demodulated digital signal according to the processing criteria of the protocol to confirm the biosignal. Sub-monitoring device (35).

Description

Patient monitoring system using medical wireless telemetry communication

The present invention relates to a medical wireless telecommunications patient monitoring system for wirelessly transmitting a vital sign of a patient collected by the PMS to a sub-monitoring device, thereby enabling the integrated management of various groups of PMS information in one place. will be.

As shown in FIG. 1 (a block diagram schematically showing the appearance of a conventional patient monitoring system), a patient monitoring system named PMS (Pertinent Monitoring System) 10 is a biosignal signal of a patient managed in a bed B. (Vital Sign) is collected and transmitted to the Central Monitoring System (30), so that the medical staff can effectively manage a large number of patients while checking the biometric information that is being output to the Central Monitoring System (30) do.

PMS 10 is shown in Figure 2 (image showing the appearance of the PMS equipment), the patient's specific biometrics with the basic biometric information of the patient, such as ECG, HR, SpO2, Resp, IBP, NIBP, CO2 from the patient Vital Wave Sign is provided for monitoring. Here, Vital Wave Sign is important bio information for the medical staff to accurately determine the patient's condition.

Since the PMS 10 is individually connected to each patient, the PMS 10 corresponding to the number of patients should be configured for monitoring the patients, and the central monitoring device 30 communicates with the plurality of PMS 10 while being specific. The biometric information transmitted from the PMS 10 should be able to be processed separately from other PMS. That is, the data communication path between the PMS 10 and the central monitoring device 30 is required to trust that the transmission information of the PMS 10 must be transmitted to the central monitoring device 30 correctly.

To this end, conventionally, the communication medium between the PMS 10 and the central monitoring device 30 is wired. That is, by allowing the biometric information of the patient collected by the specific PMS 10 to be directly transmitted to the central monitoring device 30 through a wired cable, to prevent confusion about the communication channel between the PMS 10 and the central monitoring device 30. It is.

However, the conventional communication method of the PMS 10 and the central monitoring device 30 limits the mobility of the PMS 10 itself, while the target patient of the PMS 10 is located within a range adjacent to the central monitoring device 30. There was a limitation that had to be made, which resulted in inefficiency in concentrating the staff's range of activities into the narrow range.

In order to compensate for such a conventional problem, a communication structure for wirelessly communicating between the PMS 10 and the central monitoring device 30 has been actively studied.

However, a frequency range of a certain range is required for wireless data communication between the PMS 10 and the central monitoring device 30. However, since most of the frequency bands are already preoccupied with various wireless communication systems, the dedicated communication frequency bands of the PMS 10 and the central monitoring device 30 that can be used for medical treatment are inevitably limited. Of course, since the limitation of the frequency band is to reduce the number of communication channels between the central monitoring device 30 and the PMS 10, the number of PMS 10 that can be connected to the central monitoring device 30 is also limited. As a result, in the situation where the number of patients that can be managed as much as the number of available PMS 10 is determined, in the conventional patient monitoring system based on wireless communication, the number of patients that can be managed through PMS 10 is based on wired communication. It was inevitably limited compared to Esau.

On the other hand, in order to realize the wireless communication between the PMS 10 and the central monitoring device 30, it was inevitable to replace the equipment constituting the conventional wired PMS 10 and the central monitoring device 30. Of course, such a system replacement is a significant economic burden to the medical institution, the problem was another problem to be solved in addition to the problems occurring in the above-described wireless communication method.

For reference, the withdrawal number '20', which is not described, refers to a 'gateway' for mediating communication between the PMS 10 and the central processing unit 30.

Accordingly, the present invention was created to solve the above problems, and it is possible to freely select a channel in a limited frequency band without large modifications to the existing system environment consisting of a PMS and a central monitoring device. In addition, it is possible to aim at a stable wireless data communication environment even when channel information such as channel size is changed, and to solve the problem of providing a medical monitoring system for a medical wireless telecommunication method that can effectively manage and manage bio signals of patients. do.

Means for solving the above problems,

A sensor for collecting a biological signal of the patient; A memory for storing a protocol, a data processor configured to receive a biosignal of a sensor and configure a frame format including the biosignal according to a processing standard of the protocol, a modem for modulating a digital signal configured with the frameformat, and a digital A converter for converting the modulated frame format, which is a signal, into an analog signal, a control unit for transmitting channel information to a PLL controlling a local oscillation frequency of the VCO, and a control unit for receiving a selection signal for adjusting the number of channels in a transmission frequency band. A communication device including a channel setting switch for transmitting a signal, and a mixer for merging the local oscillation frequency of the VCO and the analog signal of the converter, converting the analog signal into an RF signal for transmission, and processing the wireless transmission through an antenna.

A mixer for receiving and converting the RF signal and filtering the analog signal including the frame format, a converter for converting the analog signal to a digital signal, a modem for demodulating the digital signal, a memory for storing the protocol; And a communication device including a data processing unit for analyzing the frame format of the demodulated digital signal according to the processing criteria of the protocol to confirm the biosignal.

A central monitoring device comprising an output module for receiving information on the bio-signal transmitted from the sub-monitoring device and outputs it through the output means:

The patient monitoring system of a medical wireless telecommunication method comprising a.

Through the above means, it is easy to adjust the channel by the administrator's channel setting switch operation without changing the environment of the existing system composed of PMS and central monitoring device. Since it can be easily carried out, the number of PMS communicating with the central monitoring device can be adjusted, and the number of patients managed by the medical staff through the sub-monitoring device can be flexibly adjusted even in a limited frequency band.

In addition, since the communication medium between the PMS and the sub-monitoring device is wireless, the restriction on the installation position of the PMS is minimized.

In addition, the means is made of a removable card type, such as a PCI slot of the computer, there is an effect that can be applied immediately to the conventional wireline-based patient monitoring system.

1 is a block diagram schematically showing the appearance of a conventional patient monitoring system,
2 is an image showing a state of the PMS equipment,
Figure 3 is a block diagram schematically showing the appearance of the patient monitoring system according to the present invention,
4 is a block diagram showing a state of a communication device according to the present invention installed in a PMS,
5 is a view schematically illustrating a connection between a channel setting switch and a controller according to the present invention;
6 is a block diagram showing a state of a communication device according to the present invention installed in the sub-monitoring device.

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

Figure 3 is a block diagram schematically showing the appearance of the patient monitoring system according to the present invention, will be described with reference to this.

Patient monitoring system according to the present invention is made by combining one or more PMS (10) for wireless communication via the communication device (100, 100 ') as a sub-monitoring device (35).

The PMS 10 and the sub-monitoring device 35 communicate wirelessly through the communication devices 100 and 100 'according to the present invention, which will be described below.

Figure 4 is a block diagram showing the appearance of a communication device according to the present invention, Figure 5 is a view schematically showing the connection of the channel setting switch and the control unit according to the present invention, Figure 6 is installed in the sub-monitoring device A block diagram illustrating a communication device according to the present invention will be described with reference to the drawing.

First, the communication apparatuses 100 and 100 'of the present invention may be installed in the PMS 10 and the sub-monitoring apparatus 35, respectively, as shown in Figs. In this case, the communication device 100 installed in the PMS 10 has a function of wirelessly transmitting biometric information about the biosignal of the patient collected by the sensor 11 of the PMS 10 to the submonitoring device 35. The communication device 100 ′ installed in the monitoring device 35 has a function of receiving and transmitting the biometric information transmitted from the PMS 10 to the sub-monitoring device 35. Therefore, the configurations of the communication devices 100 and 100 'installed in the PMS 10 and the sub-monitoring device 35 to transmit or receive the biometric information are inevitably similar.

Subsequently, the present invention provides a WMTS protocol for constructing a telemetry central monitoring system based on a wireless medical telemetry service (WMTS) for wirelessly connecting a plurality of PMSs 10 and sub-monitoring devices 35. Defined.

The defined WMTS protocol basically contains complex biosignal data collected from the patient, such as ECG, SpO2, Resp, IBP (3ch), NIBP (3ch), Temperature, ECG Wave, SpO2 Wave provided by the PMS 10. do.

The PMS 10 collects a patient's biosignal using a known and common sensor 11, converts the patient's biometric signal to the WMTS protocol, and wirelessly transmits the patient's information to the submonitoring device 35. Here, the WMTS protocol is basically provided in a frame format in which PID (Patient ID) information and corresponding patient's vital signs are sequentially arranged starting with a start bit and transmitted to the sub-monitoring device 35. do. The biometric information of the collected and transmitted patients is output to the monitor of the sub-monitoring device 35, and the medical staff can immediately respond to the biometric information of the patients to be output to the monitor.

Meanwhile, the communication apparatuses 100 and 100 'of the present invention may perform bidirectional communication between the PMS 10 and the sub-monitoring apparatus 35. For this purpose, another implementation of the configuration in addition to the inclusion of the RF switch 160 is performed. An example can be given. This will be described in detail while specifically describing the communication devices 100 and 100 'of the present invention.

The communication device 100, 100 ′ of the present invention includes an interface 110 for mediating data between the communication device 100, 100 ′, the PMS 10, and the sub-monitoring device 35, and wireless data for biometric information. A transceiver 120 for processing, a modem 130 for signal modulation and demodulation, a mixer 140 for frequency synthesis, a converter 150 for mutual conversion between analog and digital signals, RF switch 160, which allows the communication device 100, 100 'to function as a wireless transmission and reception function, a band filter 170 for converting and filtering a quadrature signal from a received signal, and bio information. An antenna 180 to transmit and receive analog signals and a power supply 190 for driving the communication devices 100 and 100 'are further included.

Here, the power supply 190 is to supply the electrical energy required for driving the communication device (100, 100 '), as mentioned above, is supplied with 12V or 9V through a PCI slot or a separate DC Jack, It is supplied to the whole circuit after DC 5V conversion through regulator (not shown). In addition, the antenna 180 may be a WHIP antenna used in the 610MHz band, it is also possible to use the RF switch 160 to share the antenna 180 and the band filter 170 (BPF, Band Pass Filter).

Detailed description of the components of the communication devices 100 and 100 'disclosed above will be described in detail below in the order of processing of signals including biometric information, and the sequence is a submonitoring apparatus for biometric information collected by the PMS 10. The process of transmitting to (35) is assumed.

The sensor 11 of the PMS 10 collects various biological signals of the patient, and the communication device 100 receives them and converts them in accordance with the WMTS protocol. To this end, the biosignal of the PMS 10 is transmitted to the transceiver 120 through the interface 110.

Transceiver 120 according to the present invention can be applied to the module for high-speed wireless communication of the O-QPSK modulation method that performs the function of transmitting and receiving biometric information at a transmission rate of 250kbps in the WMTS frequency band of 608MHz ~ 614MHz. For reference, an application (Firmware) installed and executed in the transceiver 120 determines the size of the frequency per channel. In the embodiment according to the present invention, as mentioned above, the frequency size and transmission rate of one channel may be 1 MHz. It was set to 250kbps. However, by changing the application or installing a new application, it is possible to adjust the frequency size and transmission rate of one channel, and if there is such adjustment, the administrator adjusts the channel setting switch 124 of the communication device 100 The transmission channel of the biometric information can be easily changed. This will be described later.

The transceiver 120 includes a memory 121 for storing an application program and data, a data processor 122 for performing wireless transmission of biometric information, and channel information for wireless transmission of biometric information. And a channel setting switch 124 for selecting a channel set in a predetermined frequency band by a manager's operation. In addition, the transceiver 120 is not shown, but auxiliary circuits such as timers and peripherals such as the UART and the I / O pins for general use is of course auxiliary, which is a person of ordinary skill in the art (hereinafter ' Since it is obvious to those skilled in the art, the description thereof is omitted here.

Subsequently, the data processing unit 122 and the control unit 123 process the biometric information according to the data stored in the memory 121. Accordingly, the WMTS protocol may be defined and stored in the memory 121 to control one or more operations selected from the data processor 122 or the controller 123. For reference, the memory 121 may be an EEPROM.

Subsequently, the biometric information transmitted to the communication device 100 through the interface 110 is processed by the data processor 122 according to the information (WMTS protocol) stored in the memory 121, and then used for the modulation and demodulation of the signal. The controller 130 transmits the channel information to the PLL 120a for adjusting a frequency band and a channel for wireless communication of the processed biometric information.

Here, the PLL (120a; phase locked loop) refers to a phase locked loop, which is a frequency negative feedback circuit configured to maintain a constant frequency of an output signal, and includes an input signal, a reference frequency, an output signal, and a frequency. Is an electronic circuit that matches.

As noted. The PLL 120a detects the phase difference between the input signal and the output signal and controls the VCO (Voltage Controlled Oscillator) to continuously circulate until the transmission signal matches the reference frequency. It is a negative feedback circuit (fixed feedback) that fixes the frequency in a way.

On the other hand, the VCO 120b serving as an integrator is used to draw a frequency source required in a conventional RF system. At this time, the output frequency is affected by the surroundings, and when the circuit, the surrounding equipment, the temperature and the weather are affected, the frequency fluctuates minutely and goes to another frequency. If this happens, the RF system will not operate normally.

Frequency stability is very important in modern wireless communication systems that divide and divide frequencies. Therefore, in order to accurately process a signal in various mixing and amplification processes by the mixer 140, the frequency must be output correctly from the VCO 120b. Accordingly, the PLL 120a accurately controls the VCO 120b according to the frequency band and channel adjustment information transmitted from the controller 123.

Since the operations of the PLL 120a, the VCO 120b, and the mixer 140 are well-known and public technologies in the RF system field, which is a wireless communication technology, detailed descriptions of signal interworking relationships and hardware structures of the above components are omitted.

The channel setting switch 124 of the transceiver 120 is mounted on a conventional circuit board and connected to the control unit 123 via a wire line (L). The channel setting switch 124 is provided with a button 124a which can be directly operated by an administrator. A binary input signal for controlling the operation of the controller 123 is generated through the manipulation of the button 124a.

More specifically, the channel setting switch 124 of the present embodiment is configured with four buttons 124a, and the manager operates the button 124a to turn on / off the electric signal transmitted to the control unit 123. Can be operated. The four buttons 124a manipulated in this figure indicate '1', '1', '1', and '0' in order, and the selection signal for the channel corresponding to the input binary value is biometric information. Is determined by the transmission channel.

In a simple example, the channel size is determined to be 1 MHz by an application program installed in the transceiver 120 within a range of 608 MHz to 614 MHz, which is a frequency band to be used by the communication apparatuses 100 and 100 ′ according to the present invention. When the selection signal of '1110 (binary number)' is input to the channel setting switch 124 by an operation of the manager, the controller 123 is a channel of 1 MHz unit consisting of 608 MHz, 609 MHz, 610 MHz, 611 MHz, 612 MHz, 613 MHz, and 614 MHz. The channel corresponding to the selection signal input to the channel setting switch 124 is determined as a transmission channel. Of course, the controller 123 controls the PLL 120a and the VCO 120b to drive with the determined transmission channel information, and finally, the VCO 120b transmits the LO (local oscillation frequency) to the mixer 140. Confirm the size.

Although the number of channels presented in this embodiment is 7 and the frequency band for each channel is 1 MHz, the PMS 10 is installed in the transceiver 120 according to the size (data size) of biometric information transmitted to the sub-monitoring device 35. The number of channels can be adjusted by modifying or newly installing an application, and the channel setting switch 124 can be easily changed by an administrator using the channel setting switch 124 in this adjusted state. have.

The biometric information, which is the data buffered by the data processor 122, is transmitted to the modem 130, and the modem 130 converts an analog signal through a converter after a signal such as spreading and pulse shaping on the biometric information. Output the biometric information signal. For reference, the data processor 122 may include a FIFO of a transmission / reception packet for biometric information, an AES for security, a CRC, and an associated control circuit for forming a frame format according to the WMTS protocol, and automatic CRC verification. And address decoding.

The bioinformation signal is upconverted by the mixer 140 and then converted and amplified into an RF signal for transmission, and then transmitted to the antenna.

The communication device 100 ′ installed in the sub-monitoring device 35 receives the biometric information transmitted from the PMS 10 in real time, and proceeds in the reverse order according to the processing procedure of the above-described biosignal.

The biosignal processing of the communication device 100 ′ installed in the sub-monitoring device 35 will be briefly described. The antenna 180 is filtered by the band filter 170 to receive only an RF signal of a specified frequency band. Subsequently, the received RF signal format biosignal is subjected to a conventional down-conversion, filtration and amplification process through the mixer 140, and is converted into a digital signal through the converter 150, and the disk 130 in the modem 130 A demodulation process of the signal such as reading is performed. The biometric information processed in this process is transferred to the data processor 122 of the transceiver 120. Of course, the data processor 122 analyzes the biometric information of the corresponding frame format according to the WMTS protocol, and the analyzed biometric information is a biosignal in a format that can be processed by the sub-monitoring device 35 through the interface 10. It is converted and delivered.

The sub-monitoring device 35 checks the received bio-signal and outputs it through an output means such as a monitor so that the medical staff can confirm it.

For reference, the communication apparatuses 100 and 100 'according to the present invention represented through the drawings have described the drawing symbols of the drawings as devices capable of transmitting and receiving RF signals including biometric information. However, the communication device 100, 100 ′ may be a communication device 100 installed in the PMS 10 and manufactured for transmission only, or a communication device 100 installed in the sub-monitoring device 35 and configured for reception only. It may be '). Therefore, in the following claims, in order to clearly distinguish the communication device 100 installed in the PMS 10 and the communication device 100 'installed in the sub-monitoring device 35, the memory constituting the communication device 100 ( 121, the mixer 140, the converter 150, the modem 130, and the data processor 122 describe the drawing symbol, and the memory, the mixer, the converter, the modem, and the data processor that constitute the communication device 100 '. Does not specify a withdrawal symbol.

The communication device 100, 100 'according to the present invention has a configuration such as the interface 110, the transceiver 120, the modem 130, the mixer 140, the converter 150, and the like on a conventional circuit board, It can be produced and produced in a card or board type that can be installed in the slot of the computer or server. Therefore, an application for operating the communication apparatuses 100 and 100 'of the present invention is installed in the submonitoring apparatus 35, and the communication apparatuses 100 and 100', which are hardware, are installed in the PMS 10 and the submonitoring apparatus 35. ), Each of the existing wired-based patient monitoring system can be easily changed to a wireless communication method.

Claims (4)

delete A sensor 11 for collecting a biological signal of the patient; A converter 150 for converting the digital format of the biological signal collected by the sensor 11 into an analog signal, a channel setting switch 124 for receiving a selection signal for a channel set in a transmission frequency band, and a VCO A control unit 123 for transmitting channel information including the selection signal to the PLL 120a controlling the local oscillation frequency of 120b, and wirelessly transmitting the analog signal to the local oscillation frequency generated according to the channel information. And a mixer (140) for converting the RF signal into a wireless communication apparatus (100) for wirelessly transmitting the RF signal. The PMS (10) comprising: receiving and converting the RF signal and including the frame format. A mixer for filtering into an analog signal, a converter for converting the analog signal into a digital signal, a modem for demodulating the digital signal, a memory for storing a protocol, and the demodulated digital signal. A medical wireless telecommunications patient comprising: a sub-monitoring device (35) comprising: a communication device (100 ') including a data processing unit for analyzing a frame format of a signal in accordance with processing standards of the protocol to identify a bio-signal In the monitoring system,
The channel setting switch 124 includes a button 124a for turning on / off an electric signal transmitted to the control unit 123, and the control unit 123 is in binary format inputted with the on / off of the electric signal. The patient monitoring system of the medical wireless telecommunication system, characterized in that for determining the channel of the selection signal of the included in the channel information. The method of claim 2,
At least one selected from the converter 150, the controller 123, the channel setting switch 124, and the mixer 140 may be mounted on one circuit board to form a card configured to communicate with each other via a wire line L. A patient monitoring system of a medical wireless telecommunication method, characterized in that. The method of claim 3, wherein
The power supply device 190 for supplying electrical energy for driving the converter 150, the control unit 123, the channel setting switch 124 or the mixer 140 is installed on the circuit board, the power supply device 190 The patient monitoring system of the medical wireless telecommunication method, characterized in that the PCI slot or DC Jack to be connected.

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