WO2022007129A1

WO2022007129A1 - Temperature measurement control system applying hair recognition

Info

Publication number: WO2022007129A1
Application number: PCT/CN2020/109759
Authority: WO
Inventors: 胡飞青
Original assignee: 胡飞青
Priority date: 2020-07-07
Filing date: 2020-08-18
Publication date: 2022-01-13
Also published as: CN111896145A

Abstract

A temperature measurement control system applying hair recognition, comprising: a temperature measurement executing mechanism, provided within a forehead thermometer, and used for executing a forehead temperature measurement operation when a temperature measurement valid instruction is received; a temperature measurement button, provided below a thermometer barrel of the forehead thermometer, and used for issuing a temperature measurement trigger instruction when pressed manually; a miniature imaging mechanism, provided on the thermometer barrel of the forehead thermometer, electrically connected to the temperature measurement button, and used for implementing an imaging action with respect to the environment in front of the thermometer barrel of the forehead thermometer when the temperature measurement trigger instruction is received, thus acquiring an image from the front of the thermometer barrel. The temperature measurement control system applying hair recognition operates intelligently and measures effectively. Based on a comparison between the area occupied by the hairs and the area occupied by the skin in front of the thermometer barrel of the thermometer, no forehead temperature measurement operation is executed when an excess amount of hairs is present, thus avoiding the acquisition of an invalid forehead temperature value.

Description

Temperature measurement control system using hair body recognition

technical field

The invention relates to the field of physiological parameter detection, in particular to a temperature measurement control system applying hair body recognition.

Background technique

As the heat load increases, the human body will produce a series of thermophysiological responses: increased heart rate, increased core temperature, increased skin temperature, and increased sweat metabolism. Different thermal environment intensity has different degrees of thermophysiological response. The degree of these thermophysiological responses reveals the thermal load of the thermal environment in which the human body is located. Therefore, it is an effective method to control the thermal stress on the human body according to the physiological response of the human body. In the process of work, one or more physiological response values of the human body are measured to control the thermal stress of the human body under a certain level, thereby ensuring the work efficiency and work safety of the staff.

For example, body temperature is one of the most important parameters of the human body. The human body maintains a relatively constant body temperature by acquiring food, while also gaining or losing heat from the environment through convection, radiation, and evaporation of sweat. The physiological function of the human body determines that the body temperature must be maintained approximately constant in order to ensure the normal functions of the human body. Therefore, the physiological response of the human body always strives to maintain a relatively stable temperature of the vital organs of the human body. Commonly referred to as human body temperature, including core temperature, skin temperature and the average temperature of the entire human body.

The core temperature of the human body represents the temperature inside the human body, so it is also called the internal temperature, that is, the body temperature in daily life. Humans and higher animals have a constant body temperature, which changes significantly due to changes in the external environment or different human activities.

The peripheral tissue of the human body is the surface layer, including the temperature of the skin, subcutaneous tissue and muscle, which is called the surface layer temperature. The temperature of the outermost layer of the human body is called the skin temperature, also known as the body surface temperature. Because the skin is on the surface of the body, the heat dissipation conditions are good, so compared with the core temperature, the skin temperature is generally lower than the core temperature.

SUMMARY OF THE INVENTION

The present invention has at least the following two important invention points:

(1) Based on the comparison of the area occupied by the hair in front of the barrel of the temperature measuring gun and the area occupied by the skin, when there is too much hair, the forehead temperature measurement operation is not performed to avoid obtaining invalid forehead temperature values;

(2) Use a targeted identification mechanism to identify the area occupied by hair and skin in front of the barrel of the thermometer to provide key parameters for subsequent forehead temperature measurement.

According to an aspect of the present invention, there is provided a temperature measurement control system applying hair body recognition, the system comprising:

The temperature measurement actuator is set in the forehead temperature gun, and is used to perform the forehead temperature measurement operation when receiving a valid temperature measurement instruction;

The temperature measurement button is set under the barrel of the forehead temperature gun, and is used to issue a temperature measurement trigger command under manual pressure;

The miniature imaging mechanism is arranged on the barrel of the forehead thermometer and is electrically connected to the temperature measurement button, and is used for imaging the environment in front of the barrel of the forehead thermometer when the temperature measurement trigger command is received. action to get an image of the front of the barrel;

an equalization processing device, connected to the micro imaging mechanism, for performing histogram equalization processing on the received image of the front of the barrel to obtain a corresponding equalized image;

a first identification mechanism, connected to the equalization processing device, and configured to use the pixels whose brightness values fall within the preset hair brightness upper limit threshold and the preset hair brightness lower threshold threshold in the equalization image as hair pixels;

A second identification mechanism, connected to the equalization processing device, configured to use the image area in the equalized image that matches the skin color imaging feature as a skin imaging area to obtain each skin image in the equalized image area;

A quantity analysis device, which is respectively connected with the first identification mechanism and the second identification mechanism, is used for accumulating the number of hair pixels in the equalization processed image as the first identification number, and is also used for forming the skin The pixels of the imaging area are used as skin pixels to accumulate the number of skin pixels in the equalized image as the second identification number;

A proportional analysis device, which is respectively connected to the temperature measurement actuator and the quantity analysis device, and is used to issue a temperature measurement valid when the ratio of the second identification number divided by the first identification number is greater than a preset ratio threshold instruction.

The temperature measurement control system applying hair body identification of the present invention is intelligent in operation and effective in measurement. Because it can be based on the comparison of the area occupied by the hair in front of the barrel of the temperature measuring gun and the area occupied by the skin, when there is too much hair, the forehead temperature measurement operation is not performed, thereby avoiding obtaining invalid forehead temperature values.

detailed description

The embodiments of the temperature measurement control system applying hair body identification of the present invention will be described in detail below.

Body temperature monitoring is the use of body temperature monitors to check the body temperature of different parts. Sites are the nasopharynx, tympanic cavity, lower esophagus, heart and rectum. The temperature of each part can indirectly represent the temperature of an organ. For example, the temperature of the nasopharynx and tympanic cavity is similar to that of the brain. The lower esophagus temperature represents the heart temperature. Rectal temperature, which indicates the body temperature in the inner center of the body.

The monitoring of temperature in each part has its own specific significance: monitoring the temperature of the lower esophagus can prevent the occurrence of severe arrhythmia; the temperature of the nasopharynx and tympanic cavity can indicate the safe time limit of the central nervous system for hypoxia after circulation blockage; rectal temperature Indicates a safe body temperature for interrupting rewarming during rewarming. Therefore, it is best to select several sites for body temperature monitoring at the same time at low temperature. Generally, the range of the body temperature monitor is 0 to 50°C, the error is about ±0.5°C, and there are 5 to 10 temperature measuring probes, which can meet the clinical requirements.

However, when a temperature measuring gun is used to measure the temperature of the forehead of the human body, if the area occupied by the scattered hair on the forehead of the human body is too wide, it is easy to cause serious errors in the temperature measurement results.

In order to overcome the above deficiencies, the present invention builds a temperature measurement control system applying hair identification, which can effectively solve the corresponding technical problems.

According to the embodiment of the present invention, the temperature measurement control system applying hair body recognition includes:

Next, the specific structure of the temperature measurement control system applying hair body recognition of the present invention will be further described.

In the temperature measurement control system using hair identification:

The ratio analysis device is further configured to issue a temperature measurement invalid instruction when the ratio of the second identification number divided by the first identification number is less than or equal to the preset ratio threshold.

In the temperature measurement control system using hair identification:

The temperature measurement actuator is further configured to stop performing the forehead temperature measurement operation when receiving an invalid temperature measurement instruction.

In the temperature measurement control system using hair body recognition, it also includes:

A wireless router, respectively establishing wireless communication connections with the quantity analysis device and the ratio analysis device through a wireless communication network.

In the temperature measurement control system using hair identification:

The quantity analysis device and the ratio analysis device are respectively implemented by using different types of SOC chips;

Wherein, the quantity analysis device and the ratio analysis device are integrated on the same printed circuit board.

A temperature sensing device is connected to the quantity analysis device and the ratio analysis device respectively, and is used for detecting the shell temperature of the quantity analysis device and the ratio analysis device respectively.

a flash controller, located on one side of the miniature imaging mechanism, for controlling the opening and closing of the flash based on real-time ambient brightness;

Wherein, controlling the opening and closing of the flash based on the real-time ambient brightness includes: when the real-time ambient brightness is less than or equal to a preset brightness threshold, turning on the flash.

In the temperature measurement control system using hair identification:

The flash controller controlling the opening and closing of the flash based on the real-time ambient brightness includes: when the real-time ambient brightness is greater than a preset brightness threshold, turning off the flash.

In the temperature measurement control system using hair identification:

The flash controller controlling the opening and closing of the flash based on the real-time ambient brightness includes: when the real-time ambient brightness is less than or equal to a preset brightness threshold, turning on the flash and adjusting the flash brightness of the flash according to the real-time ambient brightness;

Wherein, turning on the flash and adjusting the flash brightness of the flash according to the real-time ambient brightness includes: the lower the real-time ambient brightness is, the higher the flash brightness of the flash.

The GPS positioning device, which is set on the side of the quantity analysis device, is used to provide the current GPS position of the quantity analysis device.

In addition, the predecessor of GPS is a Meridian satellite positioning system (Transit) developed by the US military. It was developed in 1958 and officially put into use in 1964. The system works with a star network of 5 to 6 satellites, circumnavigates the Earth up to 13 times a day, and cannot give altitude information and is not satisfactory in terms of positioning accuracy. However, the Meridian system enabled the R&D department to gain initial experience in satellite positioning, and verified the feasibility of positioning by the satellite system, paving the way for the development of GPS. Because satellite positioning has shown great advantages in navigation and the meridian system has a huge defect in the navigation of submarines and ships. The U.S. Navy, Army, Air Force, and civilian sector all feel the urgent need for a new satellite navigation system.

To this end, the U.S. Naval Research Laboratory (NRL) proposed a global positioning network plan called Tinmation with 12 to 18 satellites at an altitude of 10,000 km, and launched a test satellite in 1967, 1969 and 1974. The atomic clock timing system, which is the basis for precise GPS positioning, was initially tested on these satellites. The U.S. Air Force proposed the 621-B plan to form 3 to 4 constellations with 4 to 5 satellites per constellation. Except for 1 of these satellites, the rest use inclined orbits with a period of 24 hours. The plan broadcasts satellite ranging signals based on pseudo-random codes (PRNs), which are powerful enough to detect when the signal density is less than 1% of the ambient noise. The successful use of pseudo-random code is an important basis for the success of GPS. The Navy's plan is mainly for low-dynamic 2D positioning of ships, and the Air Force's plan is for high-dynamic services, but the system is too complex. Since the simultaneous development of two systems will cause huge costs and both programs are designed to provide global positioning, the US Department of Defense combined the two into one in 1973, and the satellite navigation and positioning joint led by the Department of Defense Under the leadership of the Planning Office (JPO), the office will also be set up in the Air Force Space Office in Los Angeles. The agency has a large membership, including representatives from the U.S. Army, Navy, Marine Corps, Department of Transportation, Defense Cartography Agency, NATO, and Australia.

The original GPS program was born under the leadership of the United States' Joint Planning Agency, which placed 24 satellites in three orbits at 120 degrees to each other. With 8 satellites in each orbit, 6 to 9 satellites can be observed from any point on Earth. In this way, the coarse code accuracy can reach 100m, and the fine code accuracy is 10m. Due to budget compression, the GPS program had to reduce the number of satellite launches and instead distribute 18 satellites in six orbits at 60 degrees to each other. However, this solution made the satellite reliability not guaranteed. The last revision was made in 1988: 21 working stars and 3 spare stars work in 6 orbits at 60 degrees to each other. This is also how GPS satellites work.

GPS navigation system is a radio navigation and positioning system based on 24 positioning artificial satellites in the world, which provides three-dimensional position, three-dimensional speed and other information to all parts of the world all-weather. It consists of three parts, one is the ground control part, which consists of the main control station, the ground antenna, the monitoring station and the communication auxiliary system. The second is the space part, which consists of 24 satellites distributed in 6 orbital planes. The third part is the user device, which consists of a GPS receiver and a satellite antenna. Civilian positioning accuracy can reach within 10 meters.

It should be understood that, although the present invention has been disclosed above with preferred embodiments, the above embodiments are not intended to limit the present invention. For any person skilled in the art, without departing from the scope of the technical solution of the present invention, many possible changes and modifications can be made to the technical solution of the present invention by using the technical content disclosed above, or modified to equivalent changes, etc. effective example. Therefore, any simple modifications, equivalent changes and modifications made to the above embodiments according to the technical essence of the present invention without departing from the content of the technical solutions of the present invention still fall within the protection scope of the technical solutions of the present invention.

Claims

A temperature measurement control system using hair body identification, characterized in that it includes:

The temperature measurement actuator is set in the forehead temperature gun, and is used to perform the forehead temperature measurement operation when receiving a valid temperature measurement instruction;

The temperature measurement button is set under the barrel of the forehead temperature gun, and is used to issue a temperature measurement trigger command under manual pressure;

The miniature imaging mechanism is arranged on the barrel of the forehead thermometer and is electrically connected to the temperature measurement button, and is used for imaging the environment in front of the barrel of the forehead thermometer when the temperature measurement trigger command is received. action to get an image of the front of the barrel;

an equalization processing device, connected to the micro imaging mechanism, for performing histogram equalization processing on the received image of the front of the barrel to obtain a corresponding equalized image;

a first identification mechanism, connected to the equalization processing device, and configured to use the pixels whose brightness values fall within the preset hair brightness upper limit threshold and the preset hair brightness lower threshold threshold in the equalization image as hair pixels;

A second identification mechanism, connected to the equalization processing device, configured to use the image area in the equalized image that matches the skin color imaging feature as a skin imaging area to obtain each skin image in the equalized image area;

A quantity analysis device, which is respectively connected with the first identification mechanism and the second identification mechanism, is used for accumulating the number of hair pixels in the equalization processed image as the first identification number, and is also used for forming the skin The pixels of the imaging area are used as skin pixels to accumulate the number of skin pixels in the equalized image as the second identification number;

A proportional analysis device, which is respectively connected to the temperature measurement actuator and the quantity analysis device, and is used to issue a temperature measurement valid when the ratio of the second identification number divided by the first identification number is greater than a preset ratio threshold instruction.
The temperature measurement control system applying hair body identification as claimed in claim 1, characterized in that:

The ratio analysis device is further configured to issue a temperature measurement invalid instruction when the ratio of the second identification number divided by the first identification number is less than or equal to the preset ratio threshold.
The temperature measurement control system applying hair body identification as claimed in claim 2, wherein:

The temperature measurement actuator is further configured to stop performing the forehead temperature measurement operation when receiving an invalid temperature measurement instruction.
The temperature measurement control system applying hair body recognition according to claim 3, wherein the system further comprises:

A wireless router, respectively establishing wireless communication connections with the quantity analysis device and the ratio analysis device through a wireless communication network.
The temperature measurement control system applying hair body identification as claimed in claim 4, characterized in that:

The quantity analysis device and the ratio analysis device are respectively implemented by using different types of SOC chips;

Wherein, the quantity analysis device and the ratio analysis device are integrated on the same printed circuit board.
The temperature measurement control system applying hair body identification according to claim 5, wherein the system further comprises:

A temperature sensing device is connected to the quantity analysis device and the ratio analysis device respectively, and is used for detecting the shell temperature of the quantity analysis device and the ratio analysis device respectively.
The temperature measurement control system applying hair body recognition according to claim 6, wherein the system further comprises:

a flash controller, located on one side of the miniature imaging mechanism, for controlling the opening and closing of the flash based on real-time ambient brightness;

Wherein, controlling the opening and closing of the flash based on the real-time ambient brightness includes: when the real-time ambient brightness is less than or equal to a preset brightness threshold, turning on the flash.
The temperature measurement control system applying hair body identification as claimed in claim 7, wherein:

The flash controller controlling the opening and closing of the flash based on the real-time ambient brightness includes: when the real-time ambient brightness is greater than a preset brightness threshold, turning off the flash.
The temperature measurement control system applying hair body identification as claimed in claim 8, wherein:

The flash controller controlling the opening and closing of the flash based on the real-time ambient brightness includes: when the real-time ambient brightness is less than or equal to a preset brightness threshold, turning on the flash and adjusting the flash brightness of the flash according to the real-time ambient brightness;

Wherein, turning on the flash and adjusting the flash brightness of the flash according to the real-time ambient brightness includes: the lower the real-time ambient brightness is, the higher the flash brightness of the flash.
The temperature measurement control system applying hair body identification according to claim 9, wherein the system further comprises:

The GPS positioning device is set on the side of the quantity analysis device to provide the current GPS position of the quantity analysis device.