CN204807232U - Temperature measuring system - Google Patents
Temperature measuring system Download PDFInfo
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- CN204807232U CN204807232U CN201520303493.6U CN201520303493U CN204807232U CN 204807232 U CN204807232 U CN 204807232U CN 201520303493 U CN201520303493 U CN 201520303493U CN 204807232 U CN204807232 U CN 204807232U
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Abstract
The utility model provides a temperature measuring system, this temperature measuring system of includes: the laser generator for a laser shines the measured body in order producing the optoacoustic signal that two at least different wavelength of is provided, optoacoustic signal probe sets up near the measured body for detect the intensity of the produced optoacoustic signal of inflation that heaies up behind the laser energy that the measured body absorbs two at least different wavelength respectively, the treater for the temperature of measured body is acquireed according to the intensity of the optoacoustic signal that detects. The problem of current optoacoustic temperature temperature measurement system because of using single wavelength laser survey to receive system, environment, dbjective state easily and measuring the technique that the angle influences is solved. This temperature measuring system can carry out non -contact to the target and measure, has advantages such as precision height, good reliability.
Description
Technical field
The utility model relates to technical field of temperature measurement.Specifically, a kind of temperature measurement system is related to.
Background technology
Temperature, as the fundamental physical quantity describing the cold and hot degree of object, in the fields such as physics, geology, chemistry, atmospheric science and biology, has extremely important effect.
The method of current measuring tempeature mainly comprises: contact and contactless two kinds.Wherein contact mainly comprises: adopt the expansion such as alcohol or mercury thermometry; Adopt the thermoelectricity occasionally electricity thermometry of thermal resistance engaged test temperature and ultrasonic temperature measurement etc.These method general test device structures are simple, accuracy is high, but limited to measurement range, are mainly used in low-temperature measurement, also cannot meet the needs of some needs non-cpntact measurement condition.Contactlessly mainly utilize heat radiation to carry out the radiation thermometry of thermometric at present, the method without the need to contacting testee, reaction velocity is fast, but is subject to the impact of the external factor such as measurement environment, distance, measuring error is large.In addition, also carried out the method that methods such as utilizing magnetics, frequency and CT carries out non-invasive measurement temperature both at home and abroad, but these method general test equipment are huge, expensive, real-time is poor, are unfavorable for popularizing.
Photoacoustic imaging is that the one that development in recent years is got up can't harm medical imaging procedure, it combines the high-resolution of optical imagery and the depth characteristic of ultrasonic imaging, can provide tissue and the functional imaging of high resolving power and high contrast.There are some researches show that the temperature of photoacoustic signal and measured target itself has close contacting at present, therefore, can be used to carry out temperature sensing.
But, what current optoacoustic temperature measuring equipment used is all that Single wavelength is measured, easily affect by system, environment, dbjective state and taking measurement of an angle etc., especially in labyrinth, photoacoustce signal intensity not increases with temperature linearity, and the change of output intensity in addition, under appearing in condition of different temperatures, the phenomenon that the target light acoustic signal intensity detected is identical, causes and cannot judge temperature or cause resultant error large.
Utility model content
For this reason, technical problem to be solved in the utility model is that existing optoacoustic temperature measuring equipment only uses the laser measurement of a wavelength once, its measurement result be subject to the precision of measuring system, measurement environment, measuring state impact thus cause measuring accuracy not high, thus a kind of laser of multiple different wave length that utilizes is proposed to measure measured body temperature to reduce measuring error, to improve the temperature measurement system of measuring accuracy.
For solving the problems of the technologies described above, the utility model provides following technical scheme:
A kind of temperature measurement system, comprising:
Laser generator, for providing the laser of at least two different wave lengths to irradiate measured body to produce photoacoustic signal;
Photoacoustic signal detector, is arranged near measured body, the intensity of the photoacoustic signal that the expansion that heats up absorb the laser energy of at least two different wave lengths for detecting measured body respectively after produces;
Processor, for obtaining the temperature of measured body according to the intensity of detected photoacoustic signal.
Preferably, also comprise:
Impulse ejection receiver, for receiving the intensity of the photoacoustic signal that photoacoustic signal detector detects and carrying out amplification process;
Signal sampler, the photoacoustce signal intensity received for paired pulses transceiver carries out sampling processing, and the signal after sampling processing is input to processor.
Preferably, also comprise:
Beam splitter, the laser for being sent by laser generator is divided into two bundles, and wherein a beam splitting laser is for irradiating measured body to produce photoacoustic signal;
Laser energy meter, for detecting the light intensity of another beam splitting laser, and is transferred to processor, to obtain the laser intensity that laser generator sends.
Preferably, laser generator is the tuning pulsed laser of multi-wavelength or is formed by the single pulse laser of multiple different wave length by optical fiber is integrated or is made up of the semiconductor laser of multiple different wave length.
Preferably, photoacoustic signal detector is single ultrasonic probe or array ultrasonic probe or nautical receiving set or focused transducer or clinical Ultrasonic-B probe.
Technique scheme of the present utility model has the following advantages compared to existing technology:
The temperature measurement system that the utility model provides, its laser generator can provide the short-pulse laser of multiple different wave length to irradiate measured body respectively, correspondingly repeatedly obtain the photoacoustce signal intensity of measured body, finally determine the temperature of measured body according to the corresponding relation of the plurality of laser wavelength of incidence and photoacoustce signal intensity or its position in wavelength-photoacoustce signal intensity coordinate system.This temperature measurement system can reduce because of the degree of accuracy of measuring error, measuring system and incident laser light intensity, optical maser wavelength, thermometric distance, takes measurement of an angle, comprise the measuring error that the environmental factor such as air-flow and impurity brings in addition, improve the thermometric degree of accuracy of optoacoustic and stability, and extend the scope of application of non-contact type temperature measurement method further.In addition, this temperature measurement system can realize the non-cpntact measurement of temperature, and without the need to contacting measured body, reaction velocity is fast.
Accompanying drawing explanation
Fig. 1 is the structural representation of the temperature measurement system of the utility model embodiment.
Embodiment
In order to make those skilled in the art person understand content of the present utility model better, below in conjunction with drawings and Examples, technical scheme provided by the utility model is described in further detail.
As shown in Figure 1, present embodiments provide a kind of temperature measurement system, comprising:
Laser generator 1, for providing the short-pulse laser of at least two different wave lengths to irradiate measured body to produce photoacoustic signal, this laser generator 1 is the tuning pulsed laser of multi-wavelength (OPO laser instrument), its laser wavelength range provided is mainly at ruddiness and near infrared region 680nm ~ 1200nm, also can be made up of by optical fiber is integrated the single pulse laser of multiple different wave length, can also be made up of the semiconductor laser of multiple different wave length;
Photoacoustic signal detector 3, be arranged near measured body, the intensity of the photoacoustic signal that the expansion that heats up absorb the laser energy of different wave length for detecting measured body respectively after produces, this photoacoustic signal detector 3 is ultrasonic transducer, its central frequency range, between 1MHz ~ 60MHz, specifically can be single ultrasonic probe or array ultrasonic probe or nautical receiving set or focused transducer or clinical Ultrasonic-B probe;
Processor 7, for obtaining the temperature of measured body according to the intensity of detected photoacoustic signal, also can be used for the optical maser wavelength and the light intensity that control laser generator 1 output simultaneously.
The temperature measurement system that the present embodiment provides can realize the non-cpntact measurement of temperature, without the need to contacting measured body, reaction velocity is fast, and this temperature measurement system can provide the short-pulse laser of multiple different wave length to irradiate measured body, and correspondingly obtain the photoacoustic signal that multiple measured body sends.Namely carry out the temperature of repetitive measurement measured body by changing laser wavelength of incidence, the factor such as can reduce measuring system, environment, dbjective state and take measurement of an angle on the impact of measurement result, thus improves thermometric accuracy.
Processor 7 in the present embodiment is by running a series of instruction, and the photoacoustce signal intensity come detected by photoacoustic signal detector 3 obtains measured body temperature, thus makes this temperature measurement system finally obtain the temperature of measured body.
Preferably, the temperature measurement system that the present embodiment provides also comprises:
Impulse ejection receiver 4, for receiving the intensity of the photoacoustic signal that photoacoustic signal detector 3 detects and carrying out amplification process;
Signal sampler 5, the photoacoustce signal intensity received for paired pulses transceiver 4 carries out sampling processing, and the signal after sampling processing is input to processor 7.
Impulse ejection receiver 4 is mainly used in the electric signal that photoacoustic signal detector 3 conversion is come being carried out amplify process, and to make, follow-up signal sampler 5 can accurately be sampled, the simulating signal that impulse ejection receiver 4 exports can be converted to digital signal and draw measured body temperature to facilitate the computing of processor 7 by signal sampler 5.
Preferably, the temperature measurement system that the present embodiment provides also comprises:
Beam splitter 2, laser for being sent by laser generator 1 is divided into two bundles, and this beam splitter 2 accurately can control the light intensity of each beam splitting laser, wherein a beam splitting laser is for irradiating measured body to produce photoacoustic signal, and the light intensity of this beam splitting laser is 90% of the laser intensity that laser generator 1 sends;
Laser energy meter 8, for the laser intensity that the light intensity detecting another beam splitting laser sends to obtain laser generator 1, the laser energy that real-time monitoring exports, this laser energy meter 8 is connected with processor 7 light intensity of this beam splitting laser of its Real-time Obtaining is transferred to processor 7.
Beam splitter in the temperature measurement system that the present embodiment provides and laser energy meter can the laser intensities that send of the laser generator of Real-time Obtaining when at every turn measuring, and by its input processor, when calculating measured body temperature, can the thermometric error that brings of modifying factor incident intensity instability, improve measuring accuracy further.
Preferably, the temperature measurement system that the present embodiment provides also can comprise:
Alignment clamp 9, accurately projects measured body for the short-pulse laser sent by laser generator 1, and this alignment clamp 9 can be collimation lens;
Oscillograph 6, received pulse transceiver 4 carries out the photoacoustic signal after amplifying process, and shows in real time.
The temperature measurement system utilizing this embodiment to provide, to carry out thermometric method, comprises the following steps:
First, laser generator 1 provides the laser of at least two different wave lengths to irradiate measured body respectively.Five wavelength such as can be adopted to be respectively 700,750,800,850, the laser of 900nm irradiates measured body respectively.Certainly, when accuracy requirement is not high, the laser of two or three or four different wave lengths also only can be selected to irradiate measured body respectively, for the occasion that accuracy requirement is higher, the different wave length laser of more than five also can be selected to irradiate measured body;
Then, the intensity of the photoacoustic signal that intensification expansion produces after photoacoustic signal detector 3 detects the laser energy of measured body absorption at least two different wave lengths respectively.Such as, when the laser of employing five different wave lengths irradiates, the intensity of photoacoustic signal expanding and produce that to heat up after measured body absorbs the laser energy of these five different wave lengths can be detected respectively, if utilize the different wave length laser of other numbers to irradiate measured body, then the intensity of the photoacoustic signal that the measured body detecting corresponding number produces because of absorbing laser energy;
Finally, processor 7 obtains the temperature of measured body according to the intensity of detected photoacoustic signal.
The temperature measurement system utilizing the present embodiment to provide is to carry out thermometric method for noncontact device formula thermometry, and irradiate measured body respectively by the short-pulse laser of multiple different wave length, repeatedly obtain the photoacoustce signal intensity of measured body, finally determine the temperature of measured body according to the corresponding relation of the plurality of laser wavelength of incidence and photoacoustce signal intensity.This measuring method can reduce because of the degree of accuracy of measuring error, measuring system and incident laser light intensity, optical maser wavelength, thermometric distance, takes measurement of an angle, comprise the measuring error that the environmental factor such as air-flow and impurity brings in addition, improve the thermometric degree of accuracy of optoacoustic and stability, and extend the scope of application of non-contact photoacoustic thermometry further.
Above-mentioned processor 7 can be as follows according to the specific implementation process of the temperature of detected photoacoustce signal intensity acquisition measured body:
First, the initial measured temperature of the measured body of the intensity difference correspondence of the photoacoustic signal detected by being obtained by optoacoustic-temperature correspondence table, wherein this optoacoustic-temperature correspondence table is that the Changing Pattern by obtaining measured body intensity temperature of the photoacoustic signal of generation under different wave length laser irradiates in advance obtains;
Then, determine the temperature of measured body according to above-mentioned measured body at the initial measured temperature being irradiated the rear photoacoustce signal intensity produced measured body corresponding respectively by the laser of at least two different wave lengths, specifically can adopt averaging method or weighted method etc.
Above-mentioned two steps can show the initial measured temperature that obtain corresponding to detected photoacoustce signal intensity by the optoacoustic of existing standard of comparison-temperature correspondence, are then determined the measuring tempeature of measured body by the method such as to average.So can reduce measuring error, improve measuring accuracy.During prior acquisition optoacoustic-temperature correspondence table, traditional contact type temperature measuring method can be utilized to obtain measured body temperature accurately.
Particularly, obtain above by optoacoustic-temperature correspondence table detected by the detailed process of initial measured temperature of the corresponding respectively measured body of the intensity of photoacoustic signal can be:
When the intensity of detected photoacoustic signal is present in optoacoustic-temperature correspondence table, directly according to the initial measured temperature of the intensity determination measured body of detected photoacoustic signal;
And when the intensity of detected photoacoustic signal is not present in optoacoustic-temperature correspondence table, determined the initial measured temperature of measured body by linear fit method or method of interpolation etc., to improve temperature measurement accuracy.
Temperature interval in above-mentioned optoacoustic-temperature correspondence table is 1 DEG C, to ensure after the photoacoustce signal intensity that the laser energy that measured body absorbs multiple different wave length produces being detected respectively, and can not more than 1 DEG C according to its error during photoacoustce signal intensity determination measured body temperature.
In addition, processor 7 also can be as follows according to the specific implementation process of the temperature of the intensity acquisition measured body of detected photoacoustic signal:
First, the coordinate system that to set up with wavelength be horizontal ordinate, photoacoustce signal intensity is ordinate;
Then, photoacoustce signal intensity corresponding at least two different wave length laser is marked respectively in coordinate system, corresponding formation at least two different labeled points, such as, when utilizing the laser of five different wave lengths to irradiate measured body, five corresponding five photoacoustce signal intensities of different wave length, so just have five to mark point in coordinate system;
Finally, according to the temperature of at least two different labeled points position acquisition measured body in a coordinate system, when the laser of use five different wave lengths irradiates measured body, just obtain the temperature of measured body according to five mark point positions in a coordinate system.
When the temperature measurement system utilizing the present embodiment to provide is to carry out temperature survey, obtain the intensity of photoacoustic signal corresponding to different wave length laser at photoacoustic signal detector 3 after, the position of intensity in wavelength-photoacoustce signal intensity coordinate system of the direct photoacoustic signal corresponding according to different wave length laser of processor 7 obtains measured body temperature, even utilize the method to determine that the temperature of measured body considers same temperature measurement system, the light intensity that its laser generator is launched also has certain fluctuating and the detection sensitivity of photoacoustic signal detector neither be invariable, and photoacoustce signal intensity is subject to Emission Lasers light intensity, angle, the performance impact of measured body and photoacoustic signal detector, therefore directly compare photoacoustce signal intensity and likely cause larger error.And utilize photoacoustce signal intensity corresponding to different wave length laser position in a coordinate system to compare to be one relatively, effectively can remove the impact of system and external factor, improve measuring accuracy.
Above-mentioned processor 7 obtains the temperature of measured body specific implementation process according to the intensity of detected photoacoustic signal is specially adapted to the laser irradiation measured body that laser generator 1 at least provides three different wave lengths, the situation of the intensity of at least three photoacoustic signals that intensification expansion produces after photoacoustic signal detector 3 detects the laser energy of measured body absorption at least three different wave lengths respectively.
Particularly, the detailed process of the temperature of above-mentioned basis at least two different labeled points position acquisition measured body is in a coordinate system as follows:
First, obtain the slope often between adjacent two marks point, such as, 700 are respectively when utilizing five wavelength, 750, 800, 850, when 900nm laser irradiates measured body, namely the slope k 21 between mark point in coordinate system corresponding to 700nm wavelength and the point of the mark corresponding to 750nm wavelength is obtained respectively, mark point corresponding to 750nm wavelength and the slope k 22 between the point of the mark corresponding to 800nm wavelength, mark point corresponding to 800nm wavelength and the slope k 23 between the point of the mark corresponding to 850nm wavelength, mark point corresponding to 850nm wavelength and the slope k 24 between the point of the mark corresponding to 900nm wavelength,
Then, obtain the difference of the slope between adjacent two mark points and the slope between the photoacoustce signal intensity corresponding to corresponding two wavelength lasers under the different temperatures obtained in advance respectively, be respectively 700 when utilizing five wavelength, 750,800,850,900nm laser is when irradiating measured body, by above-mentioned slope k 21 with this measured body obtained in advance at temperature T
1under the photoacoustce signal intensity corresponding to corresponding two wavelength lasers (700nm wavelength laser and 750nm wavelength laser) between slope compared with obtain its difference C
11, by above-mentioned slope k 22 with this measured body obtained in advance at temperature T
1under the photoacoustce signal intensity corresponding to corresponding two wavelength lasers (750nm wavelength laser and 800nm wavelength laser) between slope compared with obtain its difference C
12, by above-mentioned slope k 23 with this measured body obtained in advance at temperature T
1under the photoacoustce signal intensity corresponding to corresponding two wavelength lasers (800nm wavelength laser and 850nm wavelength laser) between slope compared with obtain its difference C
13, by above-mentioned slope k 24 with this measured body obtained in advance at temperature T
1under the photoacoustce signal intensity corresponding to corresponding two wavelength lasers (850nm wavelength laser and 900nm wavelength laser) between slope compared with obtain its difference C
14, and obtain temperature T respectively
2under above-mentioned difference C
21, C
22, C
23, C
24, and temperature T
nunder above-mentioned difference C
n1, C
n2, C
n3, C
n4.
Finally, when the slope between each adjacent two marks point is minimum to the absolute value sum variance that is minimum or each slope difference of the difference of the slope between corresponding two wavelength at a certain temperature obtained in advance, then using the temperature of this temperature as measured body.Such as, when using the laser of above-mentioned five different wave lengths to irradiate measured body, calculate absolute value sum or the variance of said n group difference respectively, as discovery temperature T
iunder above-mentioned difference C
i1, C
i2, C
i3, C
i4absolute value sum or variance and other temperature under the absolute value sum of difference or variance when being in a ratio of minimum, then by temperature T
ias the temperature of measured body.
During slope between above-mentioned this measured body of prior acquisition photoacoustce signal intensity corresponding to corresponding two wavelength lasers at different temperatures, its temperature interval is 1 DEG C, even also can be 0.5 degree Celsius, to reduce thermometric error as far as possible, improve measuring accuracy.
When the temperature measurement system utilizing the present embodiment to provide carries out temperature survey, the photoacoustce signal intensity corresponding to laser of at least three different wave lengths detected at photoacoustic signal detector 3 after, wavelength set up by processor 7 is horizontal ordinate, photoacoustce signal intensity is the coordinate system of ordinate and obtains often adjacent two slopes marked between point, and compared with slope between the photoacoustce signal intensity corresponding with identical two wavelength of the standard obtained in advance, determine the temperature of measured body, this compare be one relatively, effectively can remove system and the impact of external factor on the impact of photoacoustce signal intensity thus on measurement result, the thermometric accuracy of further raising.When obtaining the slope between photoacoustce signal intensity corresponding to above-mentioned different optical maser wavelength in advance, when keeping measured body temperature-resistant, the laser of different wave length irradiates measured body, record the photoacoustce signal intensity that this wavelength laser inspires, the wavelength interval of the laser of this different wave length is 5nm.
The detailed process of the above-mentioned temperature according to different labeled point position acquisition measured body in a coordinate system also can be:
First, obtain at least three different labeled points fitting a straight line degree in a coordinate system, namely judge whether this at least two different labeled points position is in a coordinate system roughly be on same straight line, such as, be respectively 700 when utilizing five wavelength, 750,800,850, the laser of 900nm is when irradiating measured body, then judge that mark that these five wavelength are corresponding is respectively put position in a coordinate system and whether is roughly on same straight line by fitting a straight line degree.
Then, when at least two different labeled points fitting a straight line degree is in a coordinate system greater than predetermined threshold value, namely when each mark point position in a coordinate system is roughly on same straight line, then carry out linear fit, and obtain the intersection point of the slope of fitting a straight line and itself and coordinate axis, and the temperature of measured body will be determined compared with its fitting a straight line corresponding at different temperatures with the measured body obtained in advance.Here, the predetermined threshold value of fitting a straight line degree can be arranged flexibly according to actual measurement situation, such as, can be 0.9, be preferably 0.95, is further preferably 0.98, is 0.99 when accuracy requirement is very high.Such as, when utilizing the laser of above-mentioned five different wave lengths to irradiate measured body, if when the mark point position in a coordinate system of the photoacoustce signal intensity corresponding to the laser of these five different wave lengths is roughly on same straight line, then carry out linear fit, obtain the intersection point (0 of the slope k 25 of fitting a straight line and itself and axis of ordinates, a2), and by this slope k 25 and intersection point (0, a2) with the measured body obtained in advance at different temperatures different optical maser wavelength compare with coordinate axis intersection point with the slope of the fitting a straight line of corresponding photoacoustce signal intensity, and using slope difference and intersection point difference all minimum corresponding to temperature as the temperature of measured body.
When at least two different labeled points fitting a straight line degree is in a coordinate system less than predetermined threshold value, namely when at least two different labeled point positions in a coordinate system are not on same straight line substantially, then linear fit goes out multiple fitting a straight line and will determine the temperature of measured body compared with multiple fitting a straight line slopes corresponding at different temperatures with the measured body obtained in advance respectively for the multiple slopes simulated, when the laser of use five different wave lengths irradiates measured body, when photoacoustce signal intensity corresponding to it mark point position in a coordinate system is not on same straight line substantially, according to fitting a straight line degree, mark point is simulated two or more straight lines.Such as, according to fitting a straight line degree can judge wavelength be 750,800,850, mark point corresponding to the laser of 900nm can fit to straight line, its slope is k27; Wavelength can fit to straight line for 700 and the mark point corresponding to the laser of 750nm, its slope is k26, compared with two fitting a straight line slopes corresponding at different temperatures with the measured body obtained in advance respectively by two of these two fitting a straight lines slope k 26, k27.If the difference of two fitting a straight line slopes that slope k 26, k27 are corresponding with a certain temperature obtained in advance is all minimum, so the temperature of measured body is this temperature.
With above-mentioned acquisition often adjacent two mark a little between slope and obtain compared with the slope difference between its with the respective wavelength obtained in advance, when the incident laser of different wave length is abundant, after simulating one or more fitting a straight line by fitting a straight line, carry out again slope ratio comparatively time relatively simple, therefore can obtain measured body temperature accurately quickly.
Above-mentioned processor 7 obtains two kinds of methods of measured body temperature according to detected photoacoustce signal intensity, can select according to actual needs wherein a kind of mode to obtain measured body temperature, also the temperature of wherein a kind of method acquisition can be utilized to go the measured body temperature verifying that another kind of method obtains, the data processing error when the photoacoustce signal intensity corresponding according to different wave length laser obtains measured body temperature can be reduced thus, thus improve the degree of accuracy of the measured body temperature obtained.
Obviously, above-described embodiment is only for clearly example being described, and the restriction not to embodiment.For those of ordinary skill in the field, can also make other changes in different forms on the basis of the above description.Here exhaustive without the need to also giving all embodiments.And thus the apparent change of extending out or variation be still among the protection domain of the invention.
Claims (5)
1. a temperature measurement system, is characterized in that, comprising:
Laser generator, for providing the laser of at least two different wave lengths to irradiate described measured body to produce photoacoustic signal;
Photoacoustic signal detector, is arranged near described measured body, for detect respectively described measured body absorb described at least two different wave lengths laser energy after to heat up the intensity of photoacoustic signal expanding and produce;
Processor, for obtaining the temperature of described measured body according to the intensity of detected described photoacoustic signal.
2. temperature measurement system as claimed in claim 1, is characterized in that, also comprise:
Impulse ejection receiver, for receiving the intensity of the photoacoustic signal that described photoacoustic signal detector detects and carrying out amplification process;
Signal sampler, carries out sampling processing for the photoacoustce signal intensity received described impulse ejection receiver, and the signal after sampling processing is input to described processor.
3. temperature measurement system as claimed in claim 1 or 2, is characterized in that, also comprise:
Beam splitter, the laser for being sent by described laser generator is divided into two bundles, and wherein a beam splitting laser is for irradiating described measured body to produce photoacoustic signal;
Laser energy meter, for detecting the light intensity of another beam splitting laser, and is transferred to described processor, to obtain the laser intensity that described laser generator sends.
4. temperature measurement system as claimed in claim 1, it is characterized in that, described laser generator is the tuning pulsed laser of multi-wavelength or is formed by the single pulse laser of multiple different wave length by optical fiber is integrated or is made up of the semiconductor laser of multiple different wave length.
5. the temperature measurement system as described in claim 1 or 2 or 4, is characterized in that, described photoacoustic signal detector is single ultrasonic probe or array ultrasonic probe or nautical receiving set or focused transducer or clinical Ultrasonic-B probe.
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105181169A (en) * | 2015-05-12 | 2015-12-23 | 中国科学院苏州生物医学工程技术研究所 | Temperature measuring method and system and temperature obtaining device |
| CN113598943A (en) * | 2021-08-09 | 2021-11-05 | 深圳市脉度科技有限公司 | Surgical instrument and measurement method |
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2015
- 2015-05-12 CN CN201520303493.6U patent/CN204807232U/en active Active
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105181169A (en) * | 2015-05-12 | 2015-12-23 | 中国科学院苏州生物医学工程技术研究所 | Temperature measuring method and system and temperature obtaining device |
| CN105181169B (en) * | 2015-05-12 | 2019-01-15 | 中国科学院苏州生物医学工程技术研究所 | Thermometry, temperature measurement system and temperature acquisition device |
| CN113598943A (en) * | 2021-08-09 | 2021-11-05 | 深圳市脉度科技有限公司 | Surgical instrument and measurement method |
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