CN204666538U - A kind of blood glucose measuring device based on millimeter wave - Google Patents

Abstract

The utility model relates to a kind of blood glucose measuring device based on millimeter wave, collects millimeter wave spectral information, obtains corresponding blood glucose value, comprise millimeter wave transceiving unit, millimeter wave detection unit, signal processing unit, output unit according to spectral data.In measuring process, adopt multi-frequency millimeter wave antenna array, the millimeter wave of described multi-frequency millimeter wave antenna array generation different frequency, make in millimeter wave noninvasive dynamics monitoring process, reduce the impact of external factor, what obtain under different frequency is blood sugar measured, and the precision and stability of device measuring is improved.

Description

A kind of blood glucose measuring device based on millimeter wave

Technical field

The utility model relates to a kind of blood glucose measuring device, particularly relates to a kind of Woundless blood sugar measurement mechanism based on millimeter wave.

Background technology

The method of traditional detection blood sugar is that puncture extraction blood is undertaken by biochemical analysis in body, this have the blood sugar test technology of wound to can be used for hospital clinical diagnosis and family health care health care, but due to needs blood drawing, there is the risk that survey frequency is limited, easily cause discomfort, even infect in this technology, make troubles to diabetic, therefore, the research carrying out novel noninvasive dynamics monitoring technology very tool is of great significance.Current Noninvasive Blood Glucose Detection Methods mainly contains polarimetry, optoacoustic method, Raman spectroscopy, light-scattering coefficient method, infra-red sepectrometry etc.

Polarimetry utilizes glucose to have stable polarized light property, and predict human blood glucose concentration by the deflection angle measuring transmitted light (or reflected light), the shortcoming of the method is that deflection angle is less, measures difficulty large, and simultaneously because be measure human eye, patient not easily receives.The photoacoustic signal that photoacoustic spectroscopy method utilizes near-infrared laser pulse and tissue interaction to produce, the content of certain composition of organization internal is detected by the relation between the amplitude of photoacoustic signal and absorption coefficient, the method is comparatively responsive to the change of organization internal structure, thus higher to the requirement of detecting device.Laser Raman spectrometry is the principle according to can there is Raman scattering when laser action is in glucose, utilize Raman spectrum analysis to obtain the concentration of glucose, due to absorption and the scattering effect of biological tissue, this input, by the large molecule serious interference of other biological, is still in the starting stage to In vivo study.Light-scattering coefficient method is a kind of novel optics Non-invasive detection technology, and it is the scattered reflection light that detection space is differentiated, and calculates tissue simplification scattering coefficient, obtains the situation of change of component content in body by following the trail of the change simplifying scattering coefficient.Infra-red sepectrometry is also the principle of the concentration by calculating composition to be measured after Infrared Spectrum Technology process, remain at present choose at measuring condition, measuring point is selected, extract the critical problems such as faint semiochemical method in overlapped spectra needs to solve.Prior art also has the research of the non-invasive blood sugar instrument adopting millimeter wave, but due in millimeter wave measurement process, other factors for measurement impact greatly.

Utility model content

The technical matters that the utility model solves is: build a kind of Woundless blood sugar measurement mechanism based on millimeter wave, overcomes prior art external factor to the technical matters measuring impact.

The technical solution of the utility model is: provide a kind of blood glucose measuring device based on millimeter wave, comprise millimeter wave transceiving unit, millimeter wave detection unit, signal processing unit, output unit, described millimeter wave transceiving unit comprises millimeter wave generation module, millimeter wave receiver module, described millimeter wave detection unit connects described millimeter wave generation module and described millimeter wave receiver module, described millimeter wave generation module through described millimeter wave detection unit to blood generation millimeter-wave signal to be measured, described millimeter wave detection unit is sent to described millimeter wave receiver module and receives after receiving millimeter-wave signal, described millimeter wave generation module occurrence frequency is 1GHz to 100GHz, the millimeter-wave signal that described signal processing unit receives according to described millimeter wave receiver module carries out signal conversion processes, described output unit exports blood sugar measured according to the process of described signal processing unit.

Further technical scheme of the present utility model is: described millimeter wave detection unit be in millimeter wave transceiving antenna, concentric cable, waveguide transmission line any one.

Further technical scheme of the present utility model is: described millimeter wave generation antenna is multi-frequency millimeter wave antenna array, the millimeter wave of described multi-frequency millimeter wave antenna array generation different frequency.

Further technical scheme of the present utility model is: the millimeter wave of each antenna generation different frequency in described multi-frequency millimeter wave antenna array.

Further technical scheme of the present utility model is: the millimeter-wave signal that described signal processing unit receives according to described millimeter wave receiver module obtains dielectric property value.

Further technical scheme of the present utility model is: described signal processing unit obtains amplitude and the phase offset of millimeter-wave signal according to the millimeter-wave signal that described millimeter wave receiver module receives.

Further technical scheme of the present utility model is: also comprise the duty detecting sensor be arranged on described millimeter wave detection unit.

Further technical scheme of the present utility model is: also comprise correction module, and described correction module corrects according to the information of described duty detecting sensor sensing.

Further technical scheme of the present utility model is: the blood sugar of described millimeter wave detection unit interval multi collect blood different frequency to be measured absorbs information.

Further technical scheme of the present utility model is: described millimeter wave transceiving antenna comprises millimeter wave generation antenna and millimeter wave receiving antenna, described millimeter wave generation antenna is millimeter wave transmitting antenna array, described millimeter wave receiving antenna is millimeter wave receiving antenna array, and the single millimeter wave emitting antenna in described millimeter wave generation aerial array and the single millimeter wave receiving antenna in described millimeter wave receiving antenna array successively interval are arranged.

Technique effect of the present utility model is: build a kind of blood glucose measuring device based on millimeter wave, comprise millimeter wave transceiving unit, millimeter wave detection unit, signal processing unit, output unit, described millimeter wave transceiving unit comprises millimeter wave generation module, millimeter wave receiver module, described millimeter wave detection unit connects described millimeter wave generation module and described millimeter wave receiver module, described millimeter wave generation module through described millimeter wave detection unit to blood generation millimeter-wave signal to be measured, described millimeter wave detection unit is sent to described millimeter wave receiver module and receives after receiving millimeter-wave signal, described millimeter wave generation module occurrence frequency is 1GHz to 100GHz, the millimeter-wave signal that described signal processing unit receives according to described millimeter wave receiver module carries out signal conversion processes, described output unit exports blood sugar measured according to the process of described signal processing unit.Blood glucose measuring device based on millimeter wave of the present utility model, collects millimeter wave spectral information, obtains corresponding blood glucose value according to spectral data.In measuring process, adopt multi-frequency millimeter wave antenna array, the millimeter wave of described multi-frequency millimeter wave antenna array generation different frequency, make in millimeter wave noninvasive dynamics monitoring process, reduce the impact of external factor, what obtain under different frequency is blood sugar measured, and the precision and stability of device measuring is improved.

Accompanying drawing explanation

Fig. 1 is structural representation of the present utility model.

Fig. 2 is coaxial probe circuit diagram of the present utility model.

Fig. 3 is that the utility model MOE and MADALINE integrates neural net method schematic diagram.

Embodiment

Below in conjunction with specific embodiment, technical solutions of the utility model are further illustrated.

As shown in Figure 1, embodiment of the present utility model is: build a kind of blood glucose measuring device based on millimeter wave, comprise millimeter wave transceiving unit 1, millimeter wave detection unit 2, signal processing unit 3, output unit 4, described millimeter wave transceiving unit 1 comprises millimeter wave generation module 11, millimeter wave receiver module 12, described millimeter wave detection unit 2 connects described millimeter wave generation module 11 and described millimeter wave receiver module 12, described millimeter wave generation module 11 through described millimeter wave detection unit 2 to blood generation millimeter-wave signal to be measured, be sent to described millimeter wave receiver module 12 after described millimeter wave detection unit 2 receives millimeter-wave signal to receive.Described millimeter wave generation module 11 occurrence frequency is 1GHz to 100GHz, the millimeter-wave signal that described signal processing unit 3 receives according to described millimeter wave receiver module 12 carries out signal conversion processes, and described output unit 4 exports blood sugar measured according to the process of described signal processing unit 3.Described millimeter wave detection unit 2 be in millimeter wave transceiving antenna, concentric cable, waveguide transmission line any one.

In specific embodiment, described millimeter wave detection unit comprises 2 millimeter wave emitting antennas 21, millimeter wave receiving antenna 22, described millimeter wave emitting antenna 21 connects described millimeter wave generation module 11, described millimeter wave receiving antenna 22 connects described millimeter wave receiver module 12, there is millimeter-wave signal through described millimeter wave emitting antenna 21 to region to be measured in described millimeter wave generation module 11, described millimeter wave receiving antenna 21 receives and received by described millimeter wave receiver module 12 after the millimeter-wave signal of area blood to be measured.

As shown in Figure 1, specific implementation process of the present utility model is: described millimeter wave generation module 11 occurrence frequency is 1GHz to 100GHz, described millimeter wave generation antenna 21 is millimeter wave antenna array, described millimeter wave antenna array generation millimeter wave, utilizes the millimeter wave of a branch of certain frequency to pass human body parts angiosomes.The blood sugar that described millimeter wave receiving antenna 22 interval gathers tissue different frequency several times absorbs information to respective passage, produces electric signal, realizes opto-electronic conversion, complete the sampling of described millimeter wave receiving antenna.The electric signal that each passage photosensor arrays produces delivers to described signal processing unit 3, in described signal processing unit 3, be sent to that hyperchannel prime amplifier carries out amplifying, filtering, Integral Processing, signal is made to reach amplitude and the signal to noise ratio (S/N ratio) of detection identification, the transformation of simulating signal to digital signal is realized again by A/D converter, digital signal after conversion delivers to the process that microprocessor carries out array signal, finally exports blood glucose value.Wave spectrum absorption/reflection characteristic special is separately had based on various material, utilize the wave spectrum absorption/reflection characteristic of blood sugar, just other material informations in its spectral information and blood can be made a distinction, simultaneously, blood sugar solution is in the special frequency channel of millimeter wave, there is certain absorbing window and reflection windows, show in these wavelength band, by the measurement to the reflectance spectrum/absorption spectrum of millimeter wave after blood sugar, under certain frequency can being obtained by statistical method, the corresponding relation of its echoed signal and blood sugar, obtains blood glucose value by corresponding relation.Also can be more responsive to dielectric property according to its absorption coefficient/reflection coefficient, therefore, finally can be passed through algorithm and perform the blood glucose concentration value drawing its correspondence.The art of this patent scheme is in order to overcome the difficult problem existed in millimeter wave noninvasive dynamics monitoring, make the embodiment human blood glucose concentration that faint spectroscopic signal change energy is correct, devise multi-frequency millimeter wave blood-sugar detection sensor array, the frequency separation measured is decided to be 1GHz-100GHz, specific frequency is segmented to each sensor in sensor array, again through the information of each sensor of detection model algorithm fusion, the precision and stability of millimeter wave noninvasive dynamics monitoring is made to be improved like this.

As shown in Figure 1, preferred implementation of the present utility model is: described millimeter wave generation module 11 occurrence frequency is 1GHz to 100GHz, described millimeter wave generation antenna 21 is multi-frequency millimeter wave antenna array, the millimeter wave of described multi-frequency millimeter wave antenna array generation different frequency, utilizes the millimeter wave of a branch of certain frequency to pass human body parts angiosomes.The blood sugar that described millimeter wave receiving antenna 22 interval gathers tissue different frequency several times absorbs information to respective passage, produces electric signal, realizes opto-electronic conversion, complete the sampling of described millimeter wave receiving antenna.In specific embodiment, the millimeter wave of each antenna generation different frequency in described multi-frequency millimeter wave antenna array.The design of millimeter wave transmitting antenna array is according to detection model, and each sensor passage accepts the glucose wave spectrum reflected signal of different frequency scope.In order to reduce the effect of other factors affecting blood sugar test in human body, the multi-frequency millimeter wave transmitting antenna array of design, the glucose absorption wave spectrum of different frequency scope is repeatedly detected with the sensor of multiple different frequency, message complementary sense, then through Array Signal Processing, draw blood glucose value more accurate than single-frequency millimeter wave transmitting antenna array, meanwhile, work also can be stablized than single-frequency millimeter wave transmitting antenna array.

As shown in Figure 1, preferred implementation of the present utility model is: described signal processing unit 3 obtains amplitude and the phase offset of millimeter-wave signal according to the millimeter-wave signal that described millimeter wave receiver module 12 receives.Described signal processing unit 3 determines the blood glucose value in region to be measured according to the millimeter-wave signal amplitude of acquisition and the corresponding relation of phase offset and blood sugar.Because the amplitude of millimeter-wave signal and phase offset and blood sugar have corresponding relation, by the measurement of real-time mass data, set up the amplitude of millimeter-wave signal and the homologous thread figure of phase offset and blood sugar, by the corresponding relation of curve map, obtain the blood glucose value of its correspondence according to real-time measurement values.

As shown in Figure 1, preferred implementation of the present utility model is: also comprise the duty detecting sensor 23 be arranged on described millimeter wave detection unit 2.In order to consider the change of the measuring accuracy that the factors such as the drift of response during millimeter wave detection cell operation and temperature variation cause, stablize on the basis of millimeter wave wave source at employing constant-current circuit, millimeter wave detection unit is provided with duty detecting sensor 23, the duty drift that temperature, sample variation etc. cause is controlled, duty is calibrated, monitors compensation, work with making sensor stabilization.The time that array is measured at every turn is about 5s, and the interval time of measuring during monitoring can set.Described signal processing unit 3 also comprises correction module 41, and described correction module corrects according to the information of described duty detecting sensor sensing 23.

As shown in Figure 1, preferred implementation of the present utility model is: described millimeter wave detection unit 2 interval gathers the millimeter wave echoed signal of region to be measured different frequency, the millimeter wave echoed signal of region to be measured different frequency is gathered by interval, complete the collection repeatedly blood sugar in region to be measured being absorbed to information, the blood glucose value in region to be measured is obtained by obtaining its mean value, more accurate like this.

As shown in Figure 1, preferred implementation of the present utility model is: described millimeter wave emitting antenna 21 is millimeter wave transmitting antenna array, described millimeter wave receiving antenna 22 is millimeter wave receiving antenna array, and the single millimeter wave emitting antenna in described millimeter wave transmitting antenna array and the single millimeter wave receiving antenna in described millimeter wave receiving antenna array successively interval are arranged.Arranged by the interval successively of single millimeter wave emitting antenna and single millimeter wave receiving antenna, echoed signal can be obtained more easily.

Specific implementation process is as follows:

Preferred implementation of the present utility model is: described signal processing unit obtains the dielectric property value of blood to be measured according to the millimeter-wave signal that described millimeter wave receiver module receives, and then obtains the blood sugar measured of blood to be measured according to the dielectric property value of blood to be measured.What adopt in the measuring process of non-invasive blood sugar instrument is that coaxial probe is measured, and the equivalent electrical circuit of its dielectric constant measurement principle as shown in Figure 2.

As shown in Figure 2, for the mould electricity energy storage that disappears in beginning place's coaxial cable, for the initial energy storage of coaxial circuit, be the beginning place be diffused in stray capacitance in outside measured medium, represent the output rating relevant with circuit, represent dielectric property value, then the Linear Double capacitor model of upper figure can be expressed as:

By distortion:

Wherein: represent dielectric property value, angular frequency, represent reflection coefficient, represent reflection radian.

The method that described signal processing unit 3 adopts Mixture of expert algorithm and Madaline linear neural net to integrate is to process the signal of millimeter wave receiving antenna.

Data message between the human normal scope that Madaline Linear Network reception MOE transmits and GG, according to blood sugar test model, accuracy of detection, carry out linear proximity by dielectric property value W, calculate the blood glucose concentration value A of corresponding precision.Namely

Wherein weights W and parameter b obtain for benchmark carries out convergence computing with network least error quadratic sum, specifically using the GG of some different blood sugar concentration that obtains as the input of network, the same time is carried out successive iteration by the accurate blood glucose value of blood sample concentration as output accordingly and optimizes weights W, b until convergence can obtain.

As shown in Figure 1, Figure 3, because blood sugar is relevant with some physical factors of people itself, in order to obtain more accurate blood glucose value, need to correct some factors.In order to extract corresponding blood sugar concentration information from wave spectrum, obtain sufficiently high signal to noise ratio (S/N ratio), to pick out faint glucose absorption signal from wave spectrum, measuring accuracy and the non-linear all reasonable method integrated by Mixture of expert algorithm (Mixture of Expert, MOE) and Madaline linear neural net is adopted to process array signal.

Mixture of expert algorithm can the comprehensive blood sugar spectral information of extraction comparison exactly, by Madaline linear neural net linear approximation methods, and the demarcation of process high precision blood glucose concentration value and display.Its algorithm is specific as follows:

Setting input parameter is , four elements be respectively body parameter, represent sex, wherein, men's 1 represents, female is 0 expression; represent human body correction factor; represent amount of exercise correction factor; represent the instrumental correction factor.Four built-in elements initialization is carried out according to the various factors of influence in detection model.The interference of the overlap of the wave spectrum of blood sugar in each channel wavelength and other factors except blood sugar can be eliminated, as the difference according to factor correction individualities such as age, height, body weight, can blood glucose information be made as far as possible accurate.

Each correction parameter m test input parameter linear sums add constant term , that is:

The output of blood sugar ripple absorption parameter GG accurately records correction parameter by n sensor summation, simultaneously each variable has a corresponding dielectric property value , its relation is as follows:

Dielectric property value with parameter relevant, its expression formula is:

, wherein .

Technique effect of the present utility model is: build a kind of blood glucose measuring device based on millimeter wave, comprise millimeter wave transceiving unit 1, millimeter wave detection unit 2, signal processing unit 3, output unit 4, described millimeter wave transceiving unit 1 comprises millimeter wave generation module 11, millimeter wave receiver module 12, described millimeter wave detection unit 2 connects described millimeter wave generation module 11 and described millimeter wave receiver module 12, described millimeter wave generation module 11 through described millimeter wave detection unit 2 to blood generation millimeter-wave signal to be measured, be sent to described millimeter wave receiver module 12 after described millimeter wave detection unit 2 receives millimeter-wave signal to receive.Described millimeter wave generation module 11 occurrence frequency is 1GHz to 100GHz, the millimeter-wave signal that described signal processing unit 3 receives according to described millimeter wave receiver module 12 carries out signal conversion processes, and described output unit 4 exports blood sugar measured according to the process of described signal processing unit 3.Blood glucose measuring device based on millimeter wave of the present utility model, collects millimeter wave spectral information, obtains corresponding blood glucose value according to spectral data.In measuring process, adopt.This method multi-frequency millimeter wave antenna array, the millimeter wave of described multi-frequency millimeter wave antenna array generation different frequency, make in millimeter wave noninvasive dynamics monitoring process, reduce the impact of external factor, what obtain under different frequency is blood sugar measured, and the precision and stability of device measuring is improved.

Above content is in conjunction with concrete preferred implementation further detailed description of the utility model, can not assert that concrete enforcement of the present utility model is confined to these explanations.For the utility model person of an ordinary skill in the technical field, without departing from the concept of the premise utility, some simple deduction or replace can also be made, all should be considered as belonging to protection domain of the present utility model.

Claims (10)

1. the blood glucose measuring device based on millimeter wave, it is characterized in that, comprise millimeter wave transceiving unit, millimeter wave detection unit, signal processing unit, output unit, described millimeter wave transceiving unit comprises millimeter wave generation module, millimeter wave receiver module, described millimeter wave detection unit connects described millimeter wave generation module and described millimeter wave receiver module, described millimeter wave generation module through described millimeter wave detection unit to blood generation millimeter-wave signal to be measured, described millimeter wave detection unit is sent to described millimeter wave receiver module and receives after receiving millimeter-wave signal, described millimeter wave generation module occurrence frequency is 1GHz to 100GHz, the millimeter-wave signal that described signal processing unit receives according to described millimeter wave receiver module carries out signal conversion processes, described output unit exports blood sugar measured according to the process of described signal processing unit.

2., according to claim 1 based on the blood glucose measuring device of millimeter wave, it is characterized in that, described millimeter wave detection unit be in millimeter wave transceiving antenna, concentric cable, waveguide transmission line any one.

3. according to claim 2 based on the blood glucose measuring device of millimeter wave, it is characterized in that, described millimeter wave generation antenna is multi-frequency millimeter wave antenna array, the millimeter wave of described multi-frequency millimeter wave antenna array generation different frequency.

4. according to claim 3 based on the blood glucose measuring device of millimeter wave, it is characterized in that, the millimeter wave of each antenna generation different frequency in described multi-frequency millimeter wave antenna array.

5. according to claim 1 based on the blood glucose measuring device of millimeter wave, it is characterized in that, the millimeter-wave signal that described signal processing unit receives according to described millimeter wave receiver module obtains dielectric property value.

6. according to claim 1 based on the blood glucose measuring device of millimeter wave, it is characterized in that, described signal processing unit obtains amplitude and the phase offset of millimeter-wave signal according to the millimeter-wave signal that described millimeter wave receiver module receives.

7. according to claim 1 based on the blood glucose measuring device of millimeter wave, it is characterized in that, also comprise the duty detecting sensor be arranged on described millimeter wave detection unit.

8. according to claim 7 based on the blood glucose measuring device of millimeter wave, it is characterized in that, also comprise correction module, described correction module corrects according to the information of described duty detecting sensor sensing.

9. according to claim 1 based on the blood glucose measuring device of millimeter wave, it is characterized in that, the blood sugar of described millimeter wave detection unit interval multi collect blood different frequency to be measured absorbs information.

10. according to claim 2 based on the blood glucose measuring device of millimeter wave, it is characterized in that, described millimeter wave transceiving antenna comprises millimeter wave generation antenna and millimeter wave receiving antenna, described millimeter wave generation antenna is millimeter wave transmitting antenna array, described millimeter wave receiving antenna is millimeter wave receiving antenna array, and the single millimeter wave emitting antenna in described millimeter wave generation aerial array and the single millimeter wave receiving antenna in described millimeter wave receiving antenna array successively interval are arranged.