DE4437538A1 - System for the detection (measurement) and/or transmission of biological signals or vital functions - Google Patents

Abstract

A system is proposed for the detection and/or transmission of biological signals or vital functions, such as for example electrocardiogram signals, heart pulse rates etc. of patients, athletes or the like, comprising a sensor, a sensor transmitter for receiving and passing on the transmitter signal and a receiving station, in which the transmitter power of a transmitter located on a patient, athlete or the like is designed in such a manner that undisturbed telemetric transmission of the sensor signal to the receiving station (22) is possible at least in the region of buildings, sportsgrounds, stadiums or the like. During the simultaneous operation of a multiplicity of transmitters, which are not screened from one another, in the reception range of the receiving station (22), the transmitting frequencies of the transmitter are furthermore located in a non-overlapping frequency raster. <IMAGE>

Description

The invention relates to a system for the detection and / or Transmission of bio-signals or vital functions such as B. ECG signals, heart rate, etc. according to the generic term of Claim 1.

State of the art

Systems for the detection and / or transmission of Bio signals or vital functions such as B. ECG signals, Heart rate, etc. of patients, athletes or the like are from the Medical technology and sports science known. The Systems are used for self-monitoring of body signals above people. The systems are usually like this carried out so that the people can move freely, d. H. on the person or in the immediate vicinity of the person there is a display device as the receiving station z. B. in Shape of a wristwatch or a speedometer-like display a bicycle handlebar. The transfer of sensors to one Receiving station can be wired or wireless (telemetric) take place.

The telemetric transmission of signals is already over the published documents DE 42 15 549 A1 and DE 42 23 657 A1 known. In the systems described there, which in  essentially from a sensor, a sensor transmitter for Recording and transmission of the sensor signal and one Receiving station exist is only a small one Range of the sensor transmitter given. It is not possible the receiving station for external monitoring of the athlete or the patient at a greater distance from the athlete or To position the patient. Neither is it possible whole group of the named people with it telemetrically monitor or in the field of view of people to their Self-control an easy-to-read display unit to set up. The systems also do not allow long-term Archiving and evaluation of the body signals mentioned above.

Object and advantages of the invention

The invention has for its object the disadvantages of Improve the state of the art and a universal Possible application of the system to deal with complex Monitoring situations e.g. B. in sports, rehabilitation and Enable healthcare.

The object is solved by the features of claim 1.

In the subclaims are advantageous and expedient Developments of the system according to the invention specified.

The main idea of the invention is that system according to the invention a network-independent transmitter owns the on or in the area of patients, athletes or the like. is attached and by its weight and its The freedom of movement of the athlete or patient not restricted. The transmitter has a transmission power which also have an undisturbed transmission of the sensor signal longer distances allowed. When operating simultaneously a large number of unshielded transmitters in the Reception area of a receiving station are the  Transmission frequencies of the transmitters and, accordingly, the Receiving frequencies of the receivers are not one overlapping frequency grid. If the sensor signals one may not have a congruent course over time more than one transmitter (e.g. two transmitters) on one transmission frequency be placed. If necessary, this can be done by a corresponding Encoding the sensor signals the number of on a channel working transmitters can be further increased.

It is particularly preferred if the transmitter has an additional one in the area of the patient, athlete or the like Is transmitter, and the transmitter to record one from lower Distance (<2m) transmitted sensor signal, from a commercially available sensor with sensor transmitter, one Receive circuit or a sensor adaptation and one Owns amplifier.

In a simple embodiment of the invention it is advantageous that the receiving station for processing and Output of the bio signals or vital functions at least one Display organ with a microprocessor. The display organ (such as a large, easy-to-read LED display or LCD Display) can be in the patient's or athlete's field of vision be set up to give the athlete or patient a Self-control and performance adjustment to protect against to enable physical overload continuously. In addition, the monitoring process can in particular done by third parties.

It is particularly advantageous if the receiving station from interface one or more systems to a personal computer (PC), with Operating a large number of systems at the same time PC the bus system from interfaces to the PC a multiplexer includes. This gives you the option of continuous Logging of the transmitted signals using the PC  to make a long-term analysis for z. B. the To create training optimization.

You also have the option of a defined one Period several waveforms from the completed Training units for performance and comparative analysis to record.

Furthermore, it is advantageous for the identification of the individual transmitters each transmitter before transmission that Provides sensor signal with a transmitter identifier.

Ultimately, it is favorable if the receiving station for Display of individual signal limits acoustic and / or has optical organs for alarming. To this In this way, the athlete, patient or the like can be prevented. There is a risk of physically overloading yourself. The Programming of the limit values can be done via a special Limit programming device.

drawings

Different embodiments of system components of the Invention are indicating further advantages and Details shown in the drawings. Show it

Fig. 1 is a schematic block diagram of a sensor with line-bound transmission to an additional transmitter,

Fig. 2 is a schematic block diagram of a sensor with telemetric transmission to an additional transmitter,

Fig. 3 shows the schematic block diagram of a receiving station with display element and

Fig. 4 shows the schematic block diagram of a receiving station for a plurality of transmitters with multiplexer and PC.

Description of the embodiments

The embodiment of a sensor and an additional transmitter from FIG. 1 consists of a sensor with sensor transmitter 1 (such as an infrared sensor or an EKG electrode), a signal line 2 , a sensor adapter 3 , an amplifier 4 , a signal shaper 5 , a microprocessor 6 and an RF transmitter module 7 . The exemplary embodiment of a sensor with a sensor transmitter and additional transmitter from FIG. 2 is composed of a sensor with sensor transmitter 8 for the telemetric transmission of sensor signals to the receiving circuit 9 of the additional transmitter 10 , an amplifier 11 , a signal shaper 12 , a microprocessor 13 and an RF transmitter module 14 together.

The receive station of the system of FIG. 3 comprises an RF receiving module 15, a decoder 16, a microprocessor 17 with an interface 18, a display driver 19 as well as two LCD displays 20, 21. Finally, FIG. 4 shows a receiving station of the system according to the invention, which has "n" receiving units 22 , which are composed in detail of the RF receiver 15 , decoder 16 , microprocessor 17 and interface 18 modules already mentioned. For communication with a PC 24, the exemplary embodiment comprises a bus system 25 and a multiplexer 26 .

How the system works

The patient or athlete, for example, carries the sensor with sensor transmitter 8 in the heart area in the pulse detection, which transmits the pulse signal telemetrically to the additional transmitter 10 . The transmitter 10 is located at a convenient location on the patient's or athlete's clothing and transmits the signal in an HF-modulated manner to the receiving station 22 located at a greater distance. As an alternative, the line-connected sensor 1 (e.g. ear clip sensor) can be attached to the patient or athlete for pulse detection. The sensor signal is fed to the additional transmitter 10 via the signal line 2 .

The receiving station 22 has two LCD displays 20 , 21 which can be attached in the field of vision of the athlete or patient.

The transmitter 10 is a quartz-controlled narrow-band version (in Germany, for example, in the 434 MHz band) with a defined frequency grid, which ensures extremely reliable and interference-free operation, i.e. several, the number of which depends on the selected frequency grid, can be in the reception range of the Surveillance system located people are detected simultaneously. The recorded sensor value is amplified accordingly by an amplifier 4 , 11 after the adaptation circuit 3 or a reception circuit 9 . The signal shaper 5 , 12 generates a signal that can be used for the downstream microprocessor 6 , 13 located in the transmitter. The microprocessor 6 , 13 calculates an average value from a plurality of incoming sensor signals and carries out plausibility checks and generates the data protocol, which is fed to the RF transmitter module 7 , 14 . The data log contains the transmitter identification, the signal value identification (e.g. for heart rate or EKG signal), the signal value information and the system time. The transmission power can be adjusted to adapt to different areas of application. The RF reception module 15 of the reception station 22 receives the encoded data emitted by the RF transmission module 7 , 14 and forwards it to the decoder 16 . The decoded signals are processed by the microprocessor 17 . The microprocessor can initiate a minimum or maximum evaluation and trigger an alarm signal if the programmed limit values are exceeded or undershot. The sensor signal values are shown on the two LCD displays 20 , 21 via the display driver 19 . At the same time, data can be output to a PC 24 via the interface 18 (e.g. RS 232 interface).

In the case of a large number of simultaneously operated systems with a receiving unit 23 , the data can only be output on the PC 24 . The data are read into the PC 24 via the interfaces 18, the bus system 25 and the multiplexer 26 . With the help of the transmitter identification, the assignment to the respective transmitter takes place. The PC can easily record, save and display or output the incoming data in the form of tables, graphics and calculations in real time using a monitor or a connected printer.

Claims (6)

1. System for the detection and / or transmission of bio-signals or vital functions such. B. ECG signals, heart rate, etc. of patients, athletes or the like, consisting of a sensor, a sensor transmitter for receiving and transmitting the sensor signal and a receiving station, characterized in that the transmission power of an on or in the patient's area, athletes or the like. Transmitter ( 10 ) is designed such that there is an undisturbed telemetric transmission of the sensor signal to the receiving station ( 22 ) at least in the area of buildings, sports facilities, stadiums or the like, and wherein for the simultaneous operation of a large number of transmitters which are not shielded from one another ( 10 ) in the reception area of the receiving station ( 22 ) the transmission frequencies of the transmitters ( 10 ) are in a non-overlapping frequency grid. 2. System according to claim 1, characterized in that the transmitter is an additional on or in the area of the patient, athlete or the like. Transmitter located, and the transmitter ( 10 ) for receiving a sensor signal transmitted from a short distance, from a commercially available sensor with sensor transmitter ( 1 , 8 ), a receiving circuit ( 9 ) or a sensor adapter ( 3 ) and an amplifier ( 4 , 11 ). 3. System according to claim 1 or 2, characterized in that the receiving station ( 22 ) for processing and output of the biosignals or vital functions has at least one display element ( 20 ) with a microprocessor ( 17 ). 4. System according to claim 1, 2 or 3, characterized in that the receiving station ( 22 ) of one or more systems has one or more interfaces ( 18 ) to a personal computer ( 24 ), with the simultaneous operation of a plurality of systems on a PC ( 24 ) the bus system ( 25 ) of interfaces ( 18 ) to the PC ( 24 ) comprises a multiplexer ( 26 ). 5. System according to claim 1, 2, 3 or 4, characterized in that for the assignment of the transmitter ( 10 ) while operating a plurality of systems, the transmitter signal has a transmitter identifier. 6. System according to any one of the above claims, characterized in that the receiving station ( 22 ) for displaying individual signal limit values has acoustic and / or optical organs for alarming and a programming device for entering the limit values.