RU2175212C1 - Telemetric complex for controlling and diagnosing functional state of human organism - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has transmitting part and receiving part positioned on human body. The transmitting part has unit for taking physiological signals having electrodes for reading electric biopotentials connected in series to preliminary amplification unit, multiplexor unit, unit for encoding signals and infrared radiation unit. The receiving part has photoreceiving unit connected in series to unit for decoding signals, multiplexor unit and unit for forming output information signals. The unit for taking physiological signals additionally has electrodes and primary converters. The encoding and decoding units have time-to-impulse modulator unit and time-to-impulse demodulator unit, respectively. Logical control and synchronization circuit with quartz oscillator for stabilizing anchoring frequency. EFFECT: wide range of functional features; accelerated data acquisition and setting diagnosis process. 7 cl, 2 dwg

Description

 The invention relates to medical equipment, namely to devices for monitoring and diagnostics, and can be used for continuous monitoring of a person’s condition through a communication channel simultaneously according to several physiological parameters.

 A known physiological parameters monitoring system comprising a transmitting unit, consisting of a sensor and a high-frequency generator, with a transmitting antenna connected to the output of the transmitting unit, and a receiving unit containing a receiving antenna, a radio receiver, the output of which is connected to the receiving antenna, a demodulation unit and a registration unit.

 Patent RU 2089094 C1, cl. A 61 B 5/02, publ. 09/10/1997.

 The disadvantage of this device is that between the transmitting and receiving parts, communication is carried out using a radio signal. The radio signal is sensitive to electrical interference, in addition, the disadvantage of radio frequency telemetry is the interference of radio waves.

 Known telemetric complex for monitoring and diagnosing the functional state of a person, consisting of a transmitting part located on the human body, including the connected physiological signal pickup unit, containing electrodes for picking up electrical biopotentials, a preliminary amplification unit, a multiplexer, a signal coding unit and an infrared radiation unit, and a receiving part, including the connected photodetector, signal decoding unit, demultiplexer and output information generating unit signals.

Patent CH 675675 A5, CL A 61 B 5/04, publ. 10/31/1990
The use of infrared radiation to transmit medical control information in closed rooms for various purposes is a more promising form of wireless communication. The infrared wavelength is very short, so the near-field and fading effects are minimized. The frequency of infrared radiation is 10 ³ -10 ⁶ MHz, while the radio noise from various installations is in the frequency band from 1.5 • 10 ^-1 to 10 ^-3 MHz, i.e. out of infrared range.

 However, the disadvantage of this complex is that it monitors and diagnoses the functional state of a person only according to the electrocardiogram. The complex does not have the ability to monitor and diagnose other physiological parameters.

 The objective of the invention is directed to the creation of a telemetry device that provides monitoring and diagnostics for several simultaneously controlled physiological indicators from a common set of indicators.

 The technical result is to reduce the time for obtaining diagnostic data of various kinds of physiological conditions.

 To achieve a technical result in a telemetric complex for monitoring and diagnosing the functional state of a person, consisting of a transmitting part located on the human body, including a series-connected physiological signal pickup unit, containing electrodes for picking up electrical biopotentials, a preliminary amplification unit, a multiplexer, a signal coding unit and a unit infrared radiation, and the receiving part, including a series-connected photodetector node, a signal decoding unit alov, a demultiplexer and a unit for generating output information signals, a unit for picking up physiological signals additionally includes primary converters, and the units for encoding and decoding signals contain a time-pulse modulator and a demodulator, respectively, and a logic control and synchronization circuit is introduced in each of them for sequential processing of one different polling cycle kind of physiological signals, made with quartz stabilization of the reference frequency and with the ability to synchronize signals along the form emomu sinhropauzy interval with a duration greater than the maximum interval between pulses of information signals.

 In addition, in the complex, a multi-channel unit for picking up and converting physiological signals is connected to a multi-channel unit for pre-amplification in the transmitting part with the possibility of adjusting the frequency characteristics and gain of each channel, and switching elements are introduced into the logic control and synchronization circuits, respectively, increasing the frequency of channel polling for transmission physiological signals with a frequency spectrum in the high-frequency region, mainly electromyogram signals.

 In addition, in the complex, the photodetector assembly is a series of series-connected external photodetectors, each of which consists of three multidirectional photodiodes, a broadband amplifier and an open collector comparator to increase the number of photodetectors, while the first photodetector in a row is connected to the total load in the decoding unit signals.

 In addition, in the complex, a unit for alternately displaying output information signals in analog form on the screen of an electron-beam indicator was introduced into the receiver.

 In addition, the complex has an additional zero channel to eliminate the influence of the parasitic constant component and its low-frequency drift.

 In addition, in the complex, the signal coding unit contains a scale amplifier, a sample-storage unit, a time-pulse modulator, and an output pulse shaper connected in series.

 In addition, in the complex, the signal decoding unit includes a pulse shaper, a time-pulse modulator, a sampling-storage unit, and a level linking unit.

 The invention is illustrated by drawings, in which in FIG. 1 shows the transmitting part of the telemetric complex; in FIG. 2 shows the receiving part of the telemetric complex.

 The telemetric complex for monitoring and diagnosing the functional state of a person consists of a transmitting part and a receiving part located on the human body.

 The transmitting part includes a physiological signal acquisition unit 1, comprising electrodes 2 and primary transducers 3, a preliminary amplification unit 4, a multiplexer 5, a signal coding unit 6, an infrared emission unit 7 with LEDs and an electric power source 8.

 The signal encoding unit 6 includes a connected scale amplifier 9, a sampling and storage unit 10, a time-pulse modulator 11, an output pulse shaper 12, a logic control and synchronization circuit 13, and a crystal oscillator 14.

 The electrodes 2 provide the acquisition of ECG signals, electroencephalograms, electromyograms, electrooculograms, primary transducers 3 provide the transmission of kinetograms, venous arterial pulsograms, sphygmograms of the temporal, brachial, radial and femoral arteries, perimetric pneumogram and pulmonary ventilation.

 Additional blocks can be introduced into the receiving part of the complex, providing control of indicators that are not transmitted by infrared (IR) telemetry, for example, blood pressure indicators, rheoplethysmogram.

 The pre-amplification unit 4 is made six-channel. The power source 8 is autonomous. As a standalone power source 8 of the transmitting part, a built-in replaceable battery 9B is used.

 The physiological signal acquisition unit 1 is connected to a six-channel pre-amplification unit 4 in the transmitting part with the possibility of adjusting the frequency characteristics and gain of each channel.

 The receiving part includes a photodetecting unit 15, a signal decoding unit 16, a demultiplexer 17, an output information signal generating unit 18, a power supply converter 19, an output information alternating display unit 20 with an electron beam indicator 21.

 The power supply Converter 19 serves as a network noise filter and provides the formation and stabilization of the necessary voltages for powering all devices of the receiving part.

 The photodetector assembly contains a series of series-connected remote photodetectors. The number of remote photodetectors and their installation location are determined based on the specific configuration and volume of the room in which the complex is used. For a room of 600x350x300 cm, two remote photodetectors located on opposite, farthest walls of the room are enough. The total number of remote photodetectors can be brought up to 15. At the same time, they can also be placed in adjacent rooms separated by blank partitions. Each remote photodetector includes three multidirectional IR photodiodes 22, a broadband amplifier 23 and an open collector comparator 24 to increase the number of remote photodetectors. The first in a row remote photodetector is connected to the total load in the signal decoding unit 16.

 The signal decoding unit 16 includes a connected pulse shaper 25, a time-pulse demodulator 26, a sampling-storage unit 27, a level binding unit 28, a logic control and synchronization circuit 29.

 The complex has an additional zero channel (not shown) to eliminate the influence of the parasitic constant component and its low-frequency drift.

 Multiplexer 5 and demultiplexer 17 provide temporary channel separation. The signal encoding unit 6 and the signal decoding unit 16 implement a time-pulse signal encoding method. Logic control and synchronization circuits 13 and 29 are designed for sequential processing of various types of physiological signals in one polling cycle and are performed with quartz stabilization of the reference frequency and with the ability to synchronize signals along the generated interval with a sync pause duration longer than the maximum interval between information signal pulses.

 The complex works as follows.

 The electrodes 2 and the primary transducers 3 are mounted on the patient and fixed by known methods. Electrical signals from the electrodes 2 and the primary transducers 3 are fed to the pre-amplification unit 4, which provides their preliminary amplification through the corresponding six channels and the formation of the pass band of each channel. After preliminary amplification, the signals are fed to the inputs of the multiplexer 5, which provides temporary separation of channels. Through a large-scale amplifier 9 and a sampling and storage unit 10, the signals are fed to a time-pulse modulator 11. At the output of the time-pulse modulator 11, packets of six information pulses plus a zero pulse are formed. Pulse packets follow with a channel polling rate. The logic control and synchronization circuit 13 provides a pause for putting the sample-storage unit 10 into storage mode, generates a synchronization pause before the service pulse and starts the time-pulse modulator 11. The logic control and synchronization circuit 13 is clocked by the crystal oscillator 14. The output pulse generator 12 generates current pulses, passing through the LEDs of the infrared radiation unit 7.

 Pulses of infrared radiation are received by photodiodes of 22 remote photodetectors. Since a comparator with an open collector, that is, with a total load in the decoding unit, is introduced into each photodetector, the "OR" function is implemented at its input. An open collector circuit provides high noise immunity, since a pulse signal of the order of 10 V is transmitted through cable connections from one external photodetector to another and from them to the decoding unit 16. In the comparators 24, a response threshold is set to cut off the background noise inherent in a particular room. The node 16 decoding the signals performs the function of restoring the analog form of electrical signals of controlled physiological parameters. Shaper 25 pulses additionally generates clock pulses with a frequency equal to the repetition rate of packets of information pulses associated with the pulse corresponding to the zero channel. The logic control and synchronization circuit 29 generates control signals for a time-pulse demodulator 26, a sampling-storage unit 27 and a demultiplexer 17. To compensate for the DC component and its drift, the signal from the time-pulse demodulator 26 enters the sample-storage unit 27 and in parallel to the level linking unit 28 . The analog signals of the six information channels from the output of the demultiplexer 17 are received through the node 18 for generating the output information signals to the node 20 for alternately displaying the output information signals in analog form and then to the screen of the electron beam indicator 21. The outputs of the six information channels of the receiving part of the complex have normalized values physiological signals in analog form with a voltage of 0 to 6 V at a resistance of 1 kOhm.

 The complex provides a stable transmission of information from its transmitting part, located on the person being examined, to the receiving part of the complex in enclosed spaces of complex configuration. The mode of operation of the complex is determined taking into account the optimization of the relations between the infrared radiation power, the required range, the sensitivity of the photodetector assembly, the degree of protection against interference, and the parameters of the autonomous power supply of the transmitting part of the complex.

Claims (7)

 1. Telemetric complex for monitoring and diagnosing the functional state of a person, consisting of a transmitting part, designed to be located on the human body and including series-connected nodes for picking up physiological signals, containing electrodes for picking up electrical biopotentials, a pre-amplification unit, a multiplexer for temporary separation of channels, a unit encoding the signals and the infrared radiation unit, and the receiving part, including a series-connected photodetector node, the dec node signal conditioning, a demultiplexer for temporal separation of channels and a node for generating output information signals, characterized in that the signal coding unit of the transmitting part and the signal decoding unit of the receiving part are designed to implement time-pulse coding of signals with quartz stabilization of the reference frequency, the physiological signal pickup unit includes primary converters, the electrical signals of which are intended for arrival at the pre-amplification unit, while the unit is encoded anija signals is adapted to generate packets of information pulses at a frequency of interrogation signals, and decoding unit is configured to generate sync pulses with a repetition rate of said packets of information pulses and restoring the electrical signals monitored physiological parameters.  2. The complex according to claim 1, characterized in that the pre-amplification unit in the transmitting part is made multi-channel with the ability to adjust the frequency characteristics and gain of each channel, and the signal encoding unit and the signal decoding unit are configured to increase the channel polling frequency for transmitting physiological signals with a frequency spectrum in the field of high frequencies, mainly electromyogram signals.  3. The complex according to claim 1 or 2, characterized in that the photodetector assembly is a series of series-connected external photodetectors, each of which consists of three multidirectional photodiodes, a broadband amplifier and an open collector comparator to increase the number of photodetectors, the first one in a row of the photodetector is connected to the total load in the signal decoding unit.  4. The complex according to claim 1 or 2, characterized in that a node for alternately displaying the output information signals in analog form on the screen of the electron beam indicator is included in the receiving part.  5. The complex according to any one of claims 1 to 3, characterized in that it has an additional zero channel to eliminate the influence of the parasitic constant component and its low-frequency drift.  6. The complex according to any one of claims 1, 2 and 4, characterized in that the signal coding unit comprises a scale amplifier, a sampling-storage unit, a time-pulse modulator, an output pulse shaper, a crystal oscillator for clocking a logic control and synchronization circuit designed for the first block of sampling-storage in the storage mode, starting the time-pulse modulator and synchronizing the signals along the generated interval with a sync pause duration greater than the maximum interval between pulses of information signals for sequential processing in one cycle of polling various kinds of physiological signals.  7. The complex according to any one of claims 1, 2 and 4, characterized in that the signal decoding unit includes a pulse shaper, a time-pulse demodulator, a sampling-storage unit and a level linking unit.

Images