IPC분류정보
국가/구분 |
United States(US) Patent
공개
|
국제특허분류(IPC7판) |
|
출원번호 |
17252821
(2019-06-06)
|
공개번호 |
20210186337
(2021-06-24)
|
우선권정보 |
JP-2018-121861 (2018-06-27) |
국제출원번호 |
PCT/JP2019/022568
(2019-06-06)
|
발명자
/ 주소 |
- Matsunaga, Daichi
- Tanaka, Yujiro
- Seyama, Michiko
|
출원인 / 주소 |
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
0 |
초록
▼
An in-vivo temperature measurement device includes a plurality of thermal resistors, temperature sensors for measuring an epidermis temperature of a living body, and temperature sensors for measuring an upper surface temperature that are provided at both ends of the thermal resistors, respectively,
An in-vivo temperature measurement device includes a plurality of thermal resistors, temperature sensors for measuring an epidermis temperature of a living body, and temperature sensors for measuring an upper surface temperature that are provided at both ends of the thermal resistors, respectively, a memory that stores an estimation model of the core temperature of the living body that takes into consideration a non-thermal equilibrium state of the living body, and thermal resistance values of the thermal resistors, and an arithmetic circuit that estimates, based on the plurality of temperatures measured by the temperature sensors and the temperature sensors, the core temperature of the living body using the estimation model and the thermal resistance values, and the thermal resistance values are different from one another.
대표청구항
▼
1.-5. (canceled) 6. An in-vivo temperature measurement device comprising: a plurality of thermal resistors;a plurality of first temperature sensors at a first end of the plurality of thermal resistors configured to face a living body;a plurality of second temperature sensors provided at a second end
1.-5. (canceled) 6. An in-vivo temperature measurement device comprising: a plurality of thermal resistors;a plurality of first temperature sensors at a first end of the plurality of thermal resistors configured to face a living body;a plurality of second temperature sensors provided at a second end of the plurality of thermal resistors opposite the first end;a memory configured to store an estimation model of a core temperature of a living body according to a non-thermal equilibrium state of the living body and thermal resistance values of the plurality of thermal resistors; andan arithmetic circuit configured to estimate the core temperature of the living body based on the estimation model, the thermal resistance values, and a plurality of temperatures measured by the plurality of first temperature sensors and the plurality of second temperature sensors;wherein the first temperature sensors are configured to measure a first temperature indicating an epidermis temperature of the living body;wherein the second temperature sensors configured to measure a second temperature at a position away from the living body; andwherein the thermal resistance values of the plurality of thermal resistors are different from one another. 7. The in-vivo temperature measurement device according to claim 6, wherein the arithmetic circuit includes: a time counter configured to count measurement times at which the plurality of first temperature sensors and the plurality of second temperature sensors measure the plurality of temperatures; andan estimation circuit configured to, based on the plurality of temperatures measured by the first temperature sensors and the second temperature sensors at the measurement times, estimate the core temperature of the living body using the estimation model and the thermal resistance values of the thermal resistors; andwherein the arithmetic circuit is configured to generate time-series data associating the measurement times and the core temperature. 8. The in-vivo temperature measurement device according to claim 6, wherein the plurality of thermal resistors comprise three thermal resistors. 9. The in-vivo temperature measurement device according to claim 8, wherein the estimation model is represented by a following expression: TC=T1(TS2′TS3-TS3′TS2)+RS1RS2T2(TS3′TS1-TS1′TS3)+RS1RS3T3(TS1′TS2-TS2′TS1)T1(TS2′-TS3′)+RS1RS2T2(TS3′-TS1′)+RS1RS3T3(TS1′-TS2′), wherein TC indicates the core temperature at a measurement time t, RSi (i=1, 2, 3) indicates a corresponding thermal resistance value of each of the plurality of thermal resistors, TSi (i=1, 2, 3) indicates a corresponding first temperature measured by each of the plurality of first temperature sensors, Ti=(TSi(t)−TUi(t)), TUi (i=1, 2, 3) indicates a corresponding second temperature measured by each of the plurality of second temperature sensors, and TSi′=dTSi(t)/dt. 10. The in-vivo temperature measurement device according to claim 6 further comprising a communication circuit configured to transmit the core temperature estimated by the arithmetic circuit. 11. The in-vivo temperature measurement device according to claim 6, wherein thicknesses of the plurality of thermal resistors are different from one another. 12. An in-vivo temperature measurement method comprising: measuring a plurality of temperatures with first temperature sensors and second temperature sensors, wherein the first temperature sensors are provided at a first end of a plurality of thermal resistors, wherein the second temperature sensors are provided at a second end of the plurality of thermal resistors opposite the first end, and wherein the first temperature sensors are positioned facing a living body; andestimating, using an estimation model of a core temperature based on a non-thermal equilibrium state of the living body and thermal resistance values of the thermal resistors, the core temperature of the living body based on the plurality of temperatures;wherein the first temperature sensors measure a first temperature indicating an epidermis temperature of the living body;wherein the second temperature sensors measure a second temperature at a position away from the living body; andwherein the thermal resistance values of the plurality of thermal resistors are different from one another. 13. The method according to claim 12, wherein estimating the core temperature of the living body comprises: counting measurement times at which the first temperature sensors and the second temperature sensors measure the plurality of temperatures; andbased on the plurality of temperatures measured by the first temperature sensors and the second temperature sensors at the measurement times, estimating the core temperature of the living body using the estimation model and the thermal resistance values of the thermal resistors; andgenerating time-series data associating the measurement times and the core temperature. 14. The method according to claim 12, wherein the plurality of thermal resistors comprise three thermal resistors. 15. The method according to claim 14, wherein the estimation model is represented by a following expression: TC=T1(TS2′TS3-TS3′TS2)+RS1RS2T2(TS3′TS1-TS1′TS3)+RS1RS3T3(TS1′TS2-TS2′TS1)T1(TS2′-TS3′)+RS1RS2T2(TS3′-TS1′)+RS1RS3T3(TS1′-TS2′), wherein TC indicates the core temperature at a measurement time t, RSi (i=1, 2, 3) indicates a corresponding thermal resistance value of each of the plurality of thermal resistors, TSi (i=1, 2, 3) indicates a corresponding first temperature measured by each of the first temperature sensors, Ti=(TSi(t)−TUi(t)), TUi (i=1, 2, 3) indicates a corresponding second temperature measured by each of the second temperature sensors, and TSi′=dTSi(t)/dt. 16. The method according to claim 12 further comprising reading the thermal resistance values from the plurality of thermal resistors. 17. The method according to claim 12, wherein the second temperature sensors measure the second temperature at an upper surface of the plurality of thermal resistors.
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