WO2006043774A1

WO2006043774A1 - Apparatus for measuring blood sugar level using radio wave and method of the same

Info

Publication number: WO2006043774A1
Application number: PCT/KR2005/003471
Authority: WO
Inventors: Kie-Jin Lee; Jong-Cheol Kim; Song-Hui Kim; Kyong-Son Yu; Hyung-Keun Yoo
Original assignee: Industry-University Cooperation Foundation Sogang University; Nexgtelecom Co., Ltd.
Priority date: 2004-10-19
Filing date: 2005-10-19
Publication date: 2006-04-27
Also published as: KR100777085B1; KR20060034565A

Abstract

Provided are an apparatus and a method for measuring a blood sugar level using a microwave. A microwave generator generates a microwave having a frequency wit hin a predetermined range. A sensor determines a mode of the microwave as one of a TE mode, a TM mode, and a TEM mode, radiates the microwave to an object to be m easured, and detects the microwave reflected from the object. An analyzer measures variations in a resonance frequency and a reflectance of the microwave detected by the sensor. A central processing unit controls the microwave generator to determine a fr equency of the microwave and generates visual data of a quantitative variation in a bloo d sugar level measured from the object based on the variations in the resonance freque ncy and the reflectance of the microwave. An image output unit outputs the visual dat a generated by the central processing unit.

Description

APPARATUS FOR MEASURING BLOOD SUGAR LEVEL USING RADIO WAVE AND METHOD OF THE SAME

TECHNICAL FIELD

The present invention relates to an apparatus and a method for measuring a bio od sugar level using microwaves, and more particularly, to an apparatus and a method f or measuring a blood sugar level in a non-blood-gathering way using microwaves.

BACKGROUND ART

A blood sugar level measuring apparatus includes a blood sugar measurer and a test sheet that can be easily obtained in a pharmacy. FIG. 1 is a photographic view ill ustrating a conventional blood sugar level measuring apparatus for measuring a blood s ugar level from blood taken from a patient. A blood sugar level measurer is an apparat us for measuring a blood sugar level through blood-gathering. Thus, a blood sugar lev el can easily be checked to manage glycosuria using such a blood sugar level measure r. However, a blood sugar level measurer must gather blood, be disinfected to prevent a blood-gathering portion from being infected, and use a needle to gather the blood. Thus, such a blood sugar measurer is unsanitary. Besides the blood sugar level meas urer, there is a blood sugar level measuring apparatus using a biosensor. A dextrose sensor manufactured in 1962 by Dr. Clark using a method of adhering a film to which gl ucose oxidase is fixed to a surface of an oxide measuring electrode is regarded as the origin of biosensors. A dextrose sensor is defined as a biochemical sensor measuring a living thing or a material deriving from the living thing using an electric, chemical, or o ptical technique and is useful for measuring specific materials using a simple method. Biosensors are used as core parts for environment measuring apparatuses, medical me asuring apparatuses, measuring instruments, or the like, and applications of biosensors are expected to increase.

A smart tattoo has been developed to measure a blood sugar level through a vari ation in a mark tattooed on the body of a diabetic when a blood sugar level of the diabet ic is lowered to a dangerous level. Smart tattoos have been used in experiments on a nimals. If such an apparatus can be put to practical use, diabetics having depended o n an apparatus for measuring a blood sugar level by piercing a finger tip to take blood may determine times of medicating through seeing variations in colors of their tattoos.

A diabetic phone capable of measuring a blood sugar level using a cellular phone has been developed. However, this diabetic phone is similar to a conventional blood sugar level measurer in terms of blood-gathering

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a photographic view illustrating a conventional apparatus for measuring a blood sugar level from blood taken from a patient.

FIG. 2 is a block diagram of an apparatus for measuring a blood sugar level acco rding to an embodiment of the present invention.

FIG. 3A is a view illustrating a stack structure including a resonator and an anten na used in an apparatus for measuring a blood sugar level according to an embodiment of the present invention.

FIG. 3B is a view illustrating a detailed structure of the stack structure shown in F IG. 3A.

FIGS. 4A and 4B, respectively, are a perspective view and a cross-sectional view of a coupled structure of a patch type antenna and a stacked resonator used in an app aratus for measuring a blood sugar level according to an embodiment of the present inv ention. FIG. 5 is a graph illustrating a resonance frequency of a monotype planar stack d ielectric resonator including a patch antenna when an apparatus for measuring a blood sugar level does not approach a measured portion of a patient.

FIGS. 6A, 6B, and 6C are a perspective view, a side view, and a second side vie w, respectively, of a stack type resonator including a patch type antenna when an objec t with a blood sugar level to be measured is placed.

FIGS. 7A and 7B are a graph and a Smith chart, respectively, illustrating a reson ance frequency of a stack dielectric resonator having interacted with a measured portio n of a patient.

FIGS. 8A and 8B are a graph and a Smith chart, respectively, illustrating a reson ance frequency of a stack dielectric resonator having interacted with a larger measured portion than the measured portion of FIGS. 7A and 7B. FIG. 9 is a view illustrating a radiation pattern of a field radiated from an apparatu s for measuring a blood sugar level according to an embodiment of the present inventio n.

FIG. 10 is a perspective view illustrating strip lines of input and output ports coupl ed to a TE mode in an apparatus for measuring a blood sugar level according to an em bodiment of the present invention.

FIG. 11 is a graph illustrating a variation in a reflection coefficient with respect to a blood sugar level measured with respect to a glass having a permittivity of 6.

FIG. 12 is a flowchart of a method of measuring a blood sugar level using microw aves according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

TECHNICAL PROBLEM

The present invention provides an apparatus and a method for stably and precis ely measuring a blood sugar level using microwaves without taking blood from a diabeti c.

TECHNICAL SOLUTION According to an aspect of the present invention, there is provided an apparatus f or measuring a blood sugar level using a microwave, including: a microwave generator generating a microwave having a frequency within a predetermined range; a sensor det ermining a mode of the microwave as one of a TE mode, a TM mode, and a TEM mode , radiating the microwave to an object to be measured, and detecting the microwave refl ected from the object; an analyzer measuring variations in a resonance frequency and a reflectance of the microwave detected by the sensor; a central processing unit control ling the microwave generator to determine a frequency of the microwave and generatin g visual data of a quantitative variation in a blood sugar level measured from the object based on the variations in the resonance frequency and the reflectance of the microwav e; and an image output unit outputting the visual data generated by the central processi ng unit.

According to another aspect of the present invention, there is provided a method for measuring a blood sugar level using a microwave, including: generating a microwav e having a frequency within a predetermined range; determining a mode of the microwa ve as one of a TE mode, a TM mode, and a TEM mode, radiating the microwave to an object to be measured, and detecting the microwave reflected from the object; measuri ng variations in a resonance frequency and a reflectance of the detected microwave; an d generating visual data of a quantitative variation in a blood sugar level measured from the object based on the variations in the resonance frequency and the reflectance of t he microwave.

ADVANTAGEOUS EFFECTS

A blood sugar level measuring apparatus according to the present invention can stably and quickly measure a blood sugar level in a non-blood-gathering way. Also, t he blood sugar level measuring apparatus can measure a variation in the blood sugar I evel in real-time and be combined with a wire and wireless communication terminal so that a diabetic can be medically diagnosed by a doctor at a remote distance and consu It with the doctor about a method of ingesting food and drink and adjusting the body in real-time. As a result, the blood sugar level measuring apparatus can provide effectiv e medical services to diabetics.

BEST MODE

Hereinafter, an apparatus and a method for measuring a blood sugar level accor ding to a preferred embodiment of the present invention will be described in detail with r eference to the attached drawings.

FIG. 2 is a block diagram of a blood sugar level measuring apparatus 200 accord ing to an embodiment of the present invention. Referring to FIG. 2, the blood sugar Ie vel measuring apparatus 200 includes a microwave generator 210, a sensor 220, an an alyzer 230, a central processing unit (CPU) 240, and an image output unit 250.

The microwave generator 210 generates a microwave having a frequency betwe en a microwave band and a millimeter wave band. The frequency of the microwave ge nerated by the microwave generator 210 is determined according to a control signal inp ut from the CPU 240, and the microwave is provided to the sensor 220. The sensor 220 radiates the microwave to a portion of a patient to be measured and detects the microwave reflected from the portion of the patient. The sensor 220 in eludes a resonator 222, an antenna 224, and a probe 226. The resonator 222 forms a mode of the microwave input from the microwave generator 210. The microwave hav ing passed through the resonator 222 forms a TE mode, a TM mode, or a TEM mode. The antenna 224 emits the microwave having passed through the resonator 222 to the portion of the patient to be measured and receives the microwave reflected from the po rtion of the patient. The probe 226 radiates the microwave emitted through the antenn a 224 onto the portion of the patient to be measured and gathers the microwave reflect ed from the portion of the patient to be measured.

FIG. 3A is a perspective view of a stack structure 300 including a resonator and a n antenna used in an apparatus for measuring a blood sugar level according to an emb odiment of the present invention. Referring to FIG. 3A, the stack structure 300 include s a dielectric resonator 310 and a λ/4 microwave patch type antenna 320. The stack s tructure 300 may couple a signal or information received through the antenna 320 to a TM mode through a viahole of the dielectric resonator 310 to identify a characteristic an d a constant of a material. The dielectric resonator 310 includes a resonator 330 havin g a cylindrical shape, a high permittivity, and a high Q, and a dielectric substrate 340 en closing the resonator 330 and having a low permittivity. The dielectric substrate 340 is formed of a stack of three substrates in consideration of manufacturing purpose.

FIG. 3B is a detailed cross-sectional view of the stack structure shown in FIG. 3A . Referring to FIG. 3B, a lowermost layer 342 of the dielectric substrate 340 occupies a portion of a total thickness of the dielectric substrate 340, and a hole 350 having a pre determined diameter is formed in an intermediate layer 344 of the dielectric substrate 3

40 so as to insert the resonator 330 thereinto. The hole 350 may be formed so as not to completely penetrate the dielectric substrate 340. Input and output lines are formed at a topmost layer 346 of the dielectric substrate 340. The input line is formed of a str ip line formed of a metal pattern and applies the microwave generated by the microwav e generator 210 to the dielectric resonator 310. The output line interacts with the porti on of the patient to be measured and then applies the microwave received through the antenna 320 and advanced to the dielectric resonator 310 to the detector 230. An upp er surface of the topmost layer 346 of the dielectric substrate 340 is opposite to the res onator 330. The lowermost layer 342 of the dielectric substrate 340 is wholly covered with a metal pattern so as to be grounded. The intermediate layer 344 of the dielectric substrate 340 has the hole 350 having the same diameter as the lowermost layer 342 so that the resonator 330 completely penetrates the hole 350. Three viaholes are for med in appropriate positions of the intermediate layer 344 of the dielectric substrate 34 0, and first and second viaholes contact the strip line of the lowermost layer 342. Also, a third viahole is disposed opposite to the resonator 330 and connected to the antenn a 320.

The third viahole connected to the antenna 320 may penetrate the lowermost lay er 342 of the dielectric substrate 340 so as to adjust a coupling value, lnsides of the vi aholes are printed with conductive paste having metal powder to contact the strip line fo rmed of the same material so as to form a coupling loop together with the resonator 33 0. In the topmost layer 346 of the dielectric substrate 340, a hole may be formed so th at the resonator 330 is inserted thereinto. Also, the upper surface of the topmost layer 346 is wholly covered with a metal pattern so as to directly contact the antenna 320. The metal pattern of the upper surface of the topmost layer 346 operates as a ground o f the antenna 320 and prevents interference between the antenna 320 and the dielectri c resonator 310.

The antenna 320 is formed of a patch antenna type including a planar conductor based on the ground of the upper surface of the topmost layer 346 of the dielectric subs trate 340 or may be rectangular or circular. The antenna 320 applies a voltage betwee n a point above the antenna 320 and a point above the ground conductor so as to be s upplied with power. The ground conductor is generally planar and substantially paralle I with the antenna 320. A frequency of the antenna 320 may vary by varying a position of a feed point and adding a short circuit in the ground conductor. A strip line is form ed to allow the dielectric resonator 310 to be opposite to the resonator 330 so that four sides of the dielectric substrate 340 except portions of an end at which input and output ports are formed are covered with a metal pattern to be grounded. The input and out put ports are planes perpendicular to the strip line at an intermediate height of the diele ctric substrate 340 and completely separated from the metal pattern.

FIGS. 4A and 4B are a perspective view and a cross-sectional view, respectively, of a coupled structure 400 of a patch type antenna and a stack type resonator used in an apparatus for measuring a blood sugar level according to an embodiment of the pres ent invention. Referring to FIGS. 4A and 4B, the coupled structure 400 includes an an tenna 410 and a dielectric resonator 450. The antenna 410 is planar and includes a gro und conductor 415 and a first patch conductor 420 being planar and rectangular so as t o be substantially parallel with the ground conductor 415. The antenna 410 further incl udes a second patch conductor 425 that is circularly separated to achieve substantial ra diation so as to achieve a desired characteristic. A dielectric substrate 430 is interpos ed between the ground conductor 415 and the first patch conductor 420 or the second patch conductor 425. The antenna 410 has viaholes 475 penetrating first and second dielectric substrates 455 and 460 of the resonator 450 instead of a coaxial probe feedin g a microwave generally used in an existing patch antenna. The viaholes 475 are met allized with a metal foil including gold, silver, or copper.

The dielectric resonator 450 is formed below the antenna 410 so as to form a sin gle body together with the antenna 410 and forms a TE01 mode, a TM01 mode, and a TEM mode. The dielectric resonator 450 is formed on an upper surface of the first diele ctric substrate 455 that is a lower layer of the antenna 410 by metallizing a shield electr ode, operates as the ground conductor described with reference to FIGS. 3A and 3B, a nd prevents a microwave generated by the dielectric resonator 450 from being radiated to an upper end. The dielectric resonator 450 includes the first and second dielectric su bstrates 455 and 460, a third dielectric substrate 465, and a dielectric drum 470 produci ng a resonance frequency and having a high permittivity, a high Q value, and a disk or c ylindrical shape.

The first, second, and third dielectric substrates 455, 460, and 465 are stacked fo r efficiency of a manufacturing process, and a strip line connected to input and output p orts is metallized on an upper surface of the third dielectric substrate 465 with a metal f oil including gold, silver, or copper so as to be coupled to or perturb the dielectric drum 470. If the strip line connected to the input and output ports forms a plane pattern, the strip line may excite a TE mode. If the strip line is connected to the viahole 475 perpe ndicular to the second dielectric substrate 460, the strip line may excite a TM mode. If the strip line is appropriate for the viahole 475, the strip line may excite the TEM mode. As described above, the feeding line connected to the antenna 410 forms a similar st rip line and the viahole 475 suitable for each mode in the first, second, and third dielectr ic substrates 455, 460, and 465 forming the dielectric resonator 450 so as to sense an i nteraction between a portion of a patient to be measured and the antenna 410.

The analyzer 230 of FIG. 2 measures the resonance frequency of the microwave and a variation in a reflectivity detected by the sensor 220. Referring to FIG. 2, the an alyzer 230 includes a power mirror 232, a circuit network analyzer 234, and a spectrum analyzer 236. The power mirror 232 provides the circuit network analyzer 234 with the microwave reflected from the portion of the patient and having passed through the res onator 222. The circuit network analyzer 234 measures an intensity, a phase, a reflect ivity, a transmission rate, and a group delay value of the microwave. The spectrum an alyzer 236 measures a spectrum of an input signal.

The CPU 240 generates visual data of a quantitative variation in a blood sugar Ie vel measured from the portion of the patient to be measured based on the resonance fr equency of the microwave and the variation in the reflectivity measured by the analyzer 230. The CPU 240 also controls the microwave generator 210 according to a manipul ator to adjust the frequency of the microwave. The image output unit 250 outputs the visual data generated by the CPU 240. FIG. 5 is a graph illustrating a resonance frequency of a monotype planar stack d ielectric resonator including a patch antenna allowing a portion of a patient to be measu red not to approach a blood sugar level measuring apparatus according to an embodim ent of the present invention. Referring to FIG. 5, the resonance frequency of the mono type planar stack dielectric resonator is about 5.832 GHz. FIGS. 6A, 6B, and 6C are a perspective view, a first side view, and a second side view, respectively, of a stack type resonator including a patch type antenna when an o bject with a blood sugar level to be measured is placed.

Referring to FIGS. 6A through 6C, the stack type resonator is positioned under a portion of a patient from which a blood sugar level is to be measured, and a viahole is p ositioned perpendicular to the portion of the patient.

FIGS. 7A and 7B are a graph and a Smith chart, respectively, illustrating a reson ance frequency of a stack type resonator having interacted with a portion of a patient to be measured. Referring to FIGS. 7A and 7B, when an object with a blood sugar level t o be measured is placed, a resonance frequency of a monotype planar stack dielectric r esonator including a patch type antenna is about 5.829 GHz.

FIGS. 8A and 8B are a graph and a Smith chart, respectively, illustrating a reson ance frequency of a stack dielectric resonator having interacted with a portion larger tha n the portion of the patient to be measured shown in FIGS. 7A and 7B. Referring to Fl GS. 8A and 8B, an increase in a sample size affects a perturbation of a field caused by an interaction. Thus, a variation in the resonance frequency of the stack dielectric res onator having TM mode coupling is increased.

FIG. 9 is a view illustrating a radiation pattern of a field radiated from a blood sug ar level measuring apparatus according to an embodiment of the present invention. FIG. 10 is a perspective view illustrating a strip line of input and output ports coup ling a TE mode in a blood sugar level measuring apparatus 1000 according to an embo diment of the present invention. Referring to FIG. 10, the blood sugar level measuring apparatus 1000 according to the present embodiment may analyze a reflection coefficie nt of a microwave to quantitatively measure a blood sugar level based on a variation in a reflectivity of a stack type dielectric resonator including a patch type antenna. A per mittivity of a blood sugar level in blood basically varies. Thus, the variation in the bloo d sugar may be measured through the variation in the permittivity, and a principle of the blood sugar level measuring apparatus 1000 will now be described. Here, a refractiv e index n is defined in Equation 1 :

wherein Fresnel's equation can be expressed in a dielectric of μ_i « //, » μ₀ as in Equati on 2:

_{r =}feU ₌ ⁿi^cosθ~ⁿt^cosΦ _r J^Λ ₌ n_t cosθ-n_icosφ

wherein θ denotes an incidence angle, φ denotes a projection angle, ι\_\ denotes a refra ctive index of an incident medium, and n_t denotes a refractive index of a transmitted me dium. If the incidence angle θ and the projection angle φ are "0," Equation 2 can be exp ressed as Equation 3:

₍₃₎

/I₁. Jl₁

wherein a reflectance R is defined in Equation 4: _R J_r cosθ_{r ^} I_{r =} y_rε_rEl l2

...(4) I₁ QOsO₁ I₁ V₁S₁E ^Jl0I₁ H '

wherein since an incident wave and a reflective wave are in the same medium,

an d are established. Equation 4 can be expressed under the above conditions in E quation 5:

As a result, if the incidence angle θ and the projection angle φ are "0," a classific ation of the reflectance R into vertical and horizontal components disappears, and R=R a -RQ • Here, a relationship between the reflectance R and a transmittance T satisfies Equation 6.

R +T = l ...(Q)

Accordingly, variations in a permittivity and a reflectance may be estimated accor ding to the variation in the permittivity as in Equation 5 above. Therefore, a blood sug ar level measuring apparatus according to the present invention can measure a reflecti on coefficient S11 corresponding to a reflectance to obtain a dielectric constant so as to measure a blood sugar level. Variations in the reflection coefficient S11 and a resona nee frequency with respect to the permittivity are shown in FIG. 11. Variations in a refl ection coefficient of a microwave and a resonance frequency with respect to a blood su gar level can be precisely estimated. FIG. 11 is a graph illustrating a variation in a refl ection coefficient of a glass having a permittivity of 6 with respect to a blood sugar level. Referring to FIG. 11 , the reflection coefficient decreases with an increase in the blood sugar level. Thus, the variation in the reflection coefficient is great with respect to the blood sugar level in a TM mode. A variation in the blood sugar level may be measure d through a variation in a resonance frequency using the reflection coefficient, and a ma gnitude of the reflection coefficient may be measured from the resonance frequency. Also, the variation in the reflection coefficient can be measured in a state of fixing the re flection coefficient, and a magnitude of the reflection coefficient may be measured from an arbitrary frequency to measure the variation in the blood sugar level. As a result, th e blood sugar level measuring apparatus according to an embodiment of the present in vention can measure a relative variation in a reference value of a blood sugar level to s ensitively measure a variation state of the blood sugar level. The blood sugar level measuring apparatus according to an embodiment of the p resent invention may be combined with a wire and wireless communication terminal sue h as a cellular phone, a personal digital assistant (PDA), a notebook computer, a perso nal computer (PC), or the like. The blood sugar level measuring apparatus measures a blood sugar level of a human body using a microwave without gathering blood and tra nsmits the blood sugar level to a diagnostic system connected through a network theret o using a communication function of a communication terminal. A doctor checks a stat e of a diabetic based on the blood sugar level output from the diagnostic system equipp ed in a hospital to diagnose the diabetic's case and prescribe medicine to the diabetic.

FIG. 12 is a flowchart of a method of measuring a blood sugar level using a micro wave according to an embodiment of the present invention. Referring to FIG. 12, in o peration S1200, the microwave generator 210 generates a microwave having a frequen cy within a predetermined range under the control of the CPU 240. In operation S121

0, the sensor 220 determines a microwave mode of the microwave as a TE mode, a TM mode, or a TEM mode and then radiates the microwave to an object to be measured. In operation S1220, the sensor 220 detects the microwave reflected from the object to be measured. In operation S1230, the analyzer 230 measures variations in a resonan ce frequency and a reflectance of the detected microwave. In operation S1240, the C PU 240 generates visual data of a quantitative variation in a blood sugar level measure d from the object based on the variations in the resonance frequency and the reflectanc e of the measured microwave. In operation S1250, the image output unit 250 outputs the visual data generated by the CPU 240.

The invention can also be embodied as computer readable codes on a computer readable recording medium. The computer readable recording medium is any data sto rage device that can store data which can be thereafter read by a computer system. E xamples of the computer readable recording medium include read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tapes, floppy disks, optical data storage devices, and carrier waves (such as data transmission through the Internet). T he computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distri buted fashion.

While the present invention has been particularly shown and described with refer ence to exemplary embodiments thereof, it will be understood by those of ordinary skill i n the art that various changes in form and details may be made therein without departin g from the spirit and scope of the present invention as defined by the following claims.

INDUSTRIAL APPLICABILITY As described above, in an apparatus and a method for measuring a blood sugar I evel using a microwave according to the present invention, the blood sugar level can be stably and quickly measured in a non-blood-gathering way. Also, the blood sugar lev el measuring apparatus can measure a variation in the blood sugar level in real-time an d be combined with a wire and wireless communication terminal so that a diabetic can b e medically diagnosed by a doctor at a remote distance and consult with the doctor abo ut a method of ingesting food and drink and adjusting the body in real-time. As a resul t, the blood sugar level measuring apparatus can provide effective medical treatment to diabetics. Also, a sensor of the blood sugar level measuring apparatus can be realize d as a stack type dielectric resonator including a patch antenna to constantly obtain a st able and high performance regardless of an outer environment and outer conditions. I n addition, the stack type dielectric resonator including the patch antenna can be separ ated as one sensor so as to be separated from a CPU processing data and connected t o a transmitting and receiving terminal by wire and wireless means. Thus, mobility of t he sensor can be improved. Moreover, the patch antenna of the blood sugar level me asuring apparatus according to the present invention can be replaced with a suitable m etal and dielectric probe. Furthermore, a mode of the stack type dielectric resonator in eluding the patch antenna can be a TE mode, a TM mode, or a combination of the TE mode and the TM mode. As a result, characteristic sensitivity of the blood sugar level can be increased.

Claims

1. An apparatus for measuring a blood sugar level using a microwave, the a pparatus comprising: a microwave generator generating a microwave having a frequency within a pred etermined range; a sensor determining a mode of the microwave as one of a TE mode, a TM mod e, and a TEM mode, radiating the microwave to an object to be measured, and detectin g the microwave reflected from the object; an analyzer measuring variations in a resonance frequency and a reflectance of t he microwave detected by the sensor; a central processing unit controlling the microwave generator to determine a freq uency of the microwave and generating visual data of a quantitative variation in a blood sugar level measured from the object based on the variations in the resonance frequen cy and the reflectance of the microwave; and an image output unit outputting the visual data generated by the central processi ng unit.

2. The apparatus of claim 1 , wherein the sensor comprises: a resonator forming the mode of the microwave input from the microwave genera tor; an antenna emitting the microwave having passed through the resonator to the o bject and receiving the microwave reflected from the object; and a probe radiating the microwave emitted through the antenna to the object and c ollecting the microwave reflected from the object.

3. The apparatus of claim 2, wherein the antenna and the resonator form a stack structure, wherein the stack structure couples a signal received through the anten na to the TM mode through a viahole formed in the resonator to measure a characteristi c and a material constant of the object.

4. The apparatus of claim 2, wherein the resonator comprises: a resonator having a high permittivity, a high Q, and a cylindrical shape; and a substrate enclosing the resonator and having a low permittivity.

5. The apparatus of claim 4, wherein the substrate comprises a plurality of I ayers, wherein at least one viahole is formed in one of the layers.

6. The apparatus of claim 5, wherein a plurality of viaholes are formed, wher ein first and second viaholes contact a strip line formed at a lower layer, and a third viah ole is connected to the antenna.

7. The apparatus of claim 6, wherein the third viahole connected to the ante nna penetrates a lowermost layer of the substrate.

8. The apparatus of claim 5, wherein an inside of the at least one viahole is printed with a conductive paste comprising metal powder to contact the strip line formed at the lower layer of the substrate so as to form a coupling loop together with the reson ator.

9. The apparatus of claim 4, wherein the substrate comprises a plurality of I ayers, wherein a metal pattern operating as a ground of the antenna and preventing int erference between the antenna and the resonator is formed on a surface of an upper Ia yer of the layers contacting the antenna.

10. The apparatus of claim 2, wherein: an input line applies the microwave generated by the microwave generator to the resonator; and an output line applies the microwave reflected from the object and received throu gh the antenna to the sensor through the resonator, wherein the input and output lines are formed on a surface on which the antenna contacts the resonator.

11. The apparatus of claim 2, wherein the antenna is a patch antenna comp rising a plane-shaped conductor.

12. The apparatus of claim 2, wherein the antenna comprises: a ground conductor contacting the resonator; a first patch conductor parallel with the ground conductor; at least one second patch conductor formed on an identical plane to the first pate h conductor and having a circular loop shape; and a dielectric substrate electrically insulating the ground conductor and the first and second patch conductors from one another.

13. The apparatus of claim 1 or 2, further comprising a communicator trans mitting the visual data generated by the central processing unit to a diagnostic system c onnected through a wire and wireless communication network.

14. A method for measuring a blood sugar level using a microwave, the met hod comprising: generating a microwave having a frequency within a predetermined range; determining a mode of the microwave as one of a TE mode, a TM mode, and a T EM mode, radiating the microwave to an object to be measured, and detecting the micr owave reflected from the object; measuring variations in a resonance frequency and a reflectance of the detected microwave; and generating visual data of a quantitative variation in a blood sugar level measured from the object based on the variations in the resonance frequency and the reflectance of the microwave.