WO2022060242A1 - Pulse generator for a contact pulsimeter - Google Patents

Abstract

The group of inventions relates to a generator and a method for generating pulses for a contact pulsimeter. A pulse generator for a contact pulsimeter comprises a circuit board, a control unit, a power supply and a unit for receiving input data, which are all interconnected. Furthermore, the circuit board comprises: one communication channel that provides a connection between the control unit and the unit for receiving input data; one contact communication channel which is connectable to the contact pulsimeter; and a ground supply channel. The control unit is designed to be capable of generating outgoing voltage pulses having a frequency ƒ on the basis of data received from the unit for receiving input data, and capable of transmitting the generated outgoing pulses to the contact pulsimeter by means of the contact communication channel. The unit for receiving input data is designed to be capable of receiving data from external devices and transmitting the data to the control unit to increase the accuracy and reliability of determining a pulse by means of the contact pulsimeter.

Description

PULSE GENERATOR FOR CONTACT HEART HEART METER

Technical field:

[0001] The group of inventions relates to the field of electronics, in particular, to a method for generating pulses for a contact heart rate monitor and a pulse generator for a contact heart rate monitor.

State of the art:

[0002] Currently, there are many devices for measuring the pulse of a person. However, no device is known in the art that generates pulse-like pulses to simulate the behavior of the human heart.

Disclosure of the invention:

[0003] The technical problem to be solved by the claimed invention is to develop a method for generating pulses for a contact heart rate monitor and a device for its implementation, which provides the supply of voltage pulses read by contact heart rate monitors as a pulse set on the device, to simulate the behavior of the human heart.

[0004] The technical result of the claimed invention is the high reliability of the developed pulse generator, which, in turn, improves the accuracy and reliability of determining the pulse with a contact heart rate monitor.

[0005] To achieve this technical result, a pulse generator for a contact heart rate monitor is proposed, containing: a board, a control unit, a power source, an input data receiving unit interconnected, while the board contains at least one communication channel that provides connection of the control unit with input receiving block data, as well as at least one contact communication channel configured to connect to a contact heart rate monitor, and a GND power channel, moreover, the control unit is configured to generate outgoing voltage pulses with a frequency f based on data received from the input data receiving unit, and transmitting the generated outgoing pulses to the contact heart rate monitor via a contact communication channel, and the input data receiving unit is configured to receive data from external devices and transmit them to the control unit.

[0006] In one embodiment, the claimed invention may include a display connected to the board, while the board may contain communication channels that connect the control unit to the display. The display may be configured to display the data generated by the control unit.

[0007] The device may also include a voltage divider (voltage step down device) installed on the board. The voltage divider is connected to the control unit and is configured to attenuate the voltage amplitude of the pulses received from the control unit and transmit pulses with a weakened voltage amplitude to the contact pulsometer via the contact channel. The divider allows you to weaken the voltage to eliminate the likelihood of overheating and burning of the elements of the device. Thus, the presence of a divider in the device makes it possible to further improve the reliability of the device and, as a result, improve the accuracy and reliability of determining the pulse with a contact heart rate monitor. In addition, the divider also allows you to attenuate the amplitude of the voltage pulses to a level perceived by a specific heart rate monitor, if necessary.

[0008] The pulse generator board may contain one, but branched in two, contact channel or two contact channels A and B. The contact channel is a channel for receiving and / or transmitting analog signals or digital signals. Contact channels links A, B can receive and/or transmit either analog signals or digital ones.

[0009] Additionally, the frequency f simulates a human heartbeat in the range from 0 to 300 beats per minute.

[0010] Obviously, both the previous general description and the following detailed description are given by way of example only, as well as explanations and are not limitations of the present invention.

[0011] The technical result is also achieved in the method of generating pulses using the previously mentioned pulse generator, according to which the frequency value is sent to the input data receiving unit, after which the input data receiving unit transmits the received data to the control unit, which, in turn, generates an outgoing pulse voltage corresponding to the frequency , and transmits the generated outgoing pulse to the contact communication channel associated with the corresponding contacts of the heart rate monitor.

[0012] The input data receiving unit may be configured to receive data (frequency value) from heart rate monitors (eg, a fitness bracelet).

[0013] If there is a voltage divider in the design of the pulse generator, the control unit transmits the generated outgoing pulse to the voltage divider to lower it to a level perceived by the heart rate monitor, after which the pulse is transmitted by the voltage divider to the contact channel (or contact channels A and B) associated with the corresponding heart rate monitor contacts.

Brief description of drawings:

[0014] FIG. 1 is a schematic representation of a pulse generator for a contact heart rate monitor according to the first embodiment. Fig. 2 - schematic image of the pulse generator for the contact heart rate monitor according to the second version.

Implementation of the invention:

[0015] A schematic representation of a pulse generator 100 for a contact heart rate monitor 101 is shown in FIG. one . In the first embodiment, the pulse generator 100 includes a board 102, a display 103, a control unit 104, a voltage divider 105, an input data receiving unit 106, a power supply 110. In this case, the board 102 also contains at least one contact channel 109 of the GND power supply, at least at least one contact channel 107 of communication A and at least one contact channel 108 of communication B.

[0016] The board 102 is configured to accommodate a display 103, a control unit 104, a divider 105, and an input data receiving unit 106 interconnected. The board 102 contains communication channels that connect the control unit with the display, voltage divider and input data receiving unit. The board 102 contains at least one GND contact channel 109 for connection to the power source 110. Contact channels 107 A and 108 V are configured to connect to a contact heart rate monitor 101. Contact channels 107, 108 of connection A and B are simultaneously channels for receiving and /or transmission of analog signals.

[0017] The display 103 is configured to display data generated by the control unit 104, such as an indication of the frequency of outgoing voltage pulses.

[0018] The control unit 104 is configured to generate outgoing voltage pulses with a frequency f based on the data received from the input data receiving unit 106 and transmit the generated outgoing pulses to the voltage divider 105. In the context of this invention, the frequency f can simulate a human heartbeat in the range from 0 to 300 beats per minute. Also, the control unit 104 can be performed with the possibility of transmitting via the contact channels 107, 108 of communication A and B a predetermined analog signal for the contact heart rate monitor 101 .

[0019] The voltage divider 105 is configured to attenuate the voltage amplitude of the pulses received from the control unit 104 and transmit pulses with a weakened voltage amplitude to the contact heart rate monitor 101 through the mentioned contact channels 107 A and 108 V.

[0020] The input data receiving unit 106 is configured to receive data from external devices and transmit them to the control unit 104 . Block 106 may be in the form of, for example, USB, LAN, Ethernet ports, or may be in the form of a Bluetooth, wi-fi, etc. wireless interface.

[0021 ] In the second embodiment, the pulse generator 100 includes a board 102, a control unit 104 and an input data receiving unit 106, a power supply 110. In this case, the board 102 also contains one GND power contact channel 109 for connection to the power supply 110, and one contact channel 107 of communication A.

[0022] The board 102 is configured to accommodate a control unit 104 and an input data receiving unit 106 interconnected. The board 102 contains communication channels that connect the control unit with the input data receiving unit. The contact channel 107 A is branched in two to enable connection to the contacts of the contact heart rate monitor 101. The contact channel 107 A is a channel for receiving and/or transmitting digital signals.

[0023] The control unit 104 is configured to generate outgoing voltage pulses with a frequency f based on data received from the input data receiving unit 106, and transmit the generated outgoing pulses through the communication channel 107 A to the contacts of the heart rate monitor 101. In the context of this invention, the frequency f can simulate a human heartbeat in the range from 0 to 300 beats per minute. [0024] The input data receiving unit 106 is configured to receive data from external devices and transmit them to the control unit 104 . Block 106 may be in the form of, for example, USB, LAN, Ethernet ports, or may be in the form of a Bluetooth, wi-fi, etc. wireless interface.

[0025] The developed generator of pulse-like pulses can be used in sports simulators for non-contact reception of data characterizing the pulse rate of a person, from, for example, heart rate monitors (fitness bracelet, etc.) and generating outgoing voltage pulses in frequency coinciding with the pulse rate recorded by the heart rate monitor , in order to further transfer the generated voltage pulses to a contact heart rate monitor to display a person's pulse on a monitor (for example, a monitor built into a treadmill or other simulator). The use of the present invention will allow measuring a person's pulse to further display its value on the monitor of the simulator with high accuracy and at the same time exclude tactile contact of a person directly with a contact heart rate monitor built into the simulator, which can be inconvenient when performing physical exercises.

Thus, the developed device is characterized by high reliability of operation (accurate generation of pulse-like pulses according to specified values and their transmission to a contact heart rate monitor), which, in turn, provides an increase in the accuracy and reliability of determining the pulse by a contact heart rate monitor.

[0026] While the invention has been shown and described with reference to certain embodiments, those skilled in the art will appreciate that various changes and modifications can be made therein without departing from the actual scope of the invention.

Claims

7 Utility Model Formula

1. A pulse generator for a contact heart rate monitor, comprising:

- a board, a control unit, a power source, an input data receiving unit interconnected, while the board contains at least one communication channel that provides connection of the control unit with the input data receiving unit, as well as at least one contact communication channel made with the ability to connect to a contact heart rate monitor, and a GND power supply channel;

- a control unit configured to generate outgoing voltage pulses with a frequency f based on data received from the input data receiving unit and transmit the generated outgoing pulses to a contact heart rate monitor via a contact communication channel;

- an input data receiving unit configured to receive data from external devices and transmit them to the control unit.

2. The pulse generator according to claim 1, characterized in that the frequency f imitates a human heartbeat in the range from 0 to 300 beats per minute.

3. The pulse generator according to claim 1, characterized in that the contact communication channel is a channel for receiving and / or transmitting analog signals or digital signals.

4. The pulse generator according to claim 1, characterized in that the board contains two contact communication channels or one contact communication channel branched in two.

5. The pulse generator according to claim 1, characterized in that the control unit is connected to a device that lowers the voltage and is configured to attenuate the voltage amplitude of the pulses received from the control unit and transmit pulses with a weakened voltage amplitude to a contact heart rate monitor through a contact channel. 8

6. The method of generating pulses according to claim 1, characterized in that the frequency value is sent to the input data receiving unit, after which the input data receiving unit transmits the received data to the control unit, which, in turn, generates an outgoing voltage pulse corresponding to the frequency , and transmits the generated outgoing pulse to the contact communication channel associated with the corresponding contacts of the heart rate monitor.