CA2182193A1 - A passive sensor system using ultrasonic energy - Google Patents
A passive sensor system using ultrasonic energyInfo
- Publication number
- CA2182193A1 CA2182193A1 CA002182193A CA2182193A CA2182193A1 CA 2182193 A1 CA2182193 A1 CA 2182193A1 CA 002182193 A CA002182193 A CA 002182193A CA 2182193 A CA2182193 A CA 2182193A CA 2182193 A1 CA2182193 A1 CA 2182193A1
- Authority
- CA
- Canada
- Prior art keywords
- sensor
- vibratable
- vibration frequency
- physical variable
- membrane
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/0002—Remote monitoring of patients using telemetry, e.g. transmission of vital signals via a communication network
- A61B5/0031—Implanted circuitry
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01H—MEASUREMENT OF MECHANICAL VIBRATIONS OR ULTRASONIC, SONIC OR INFRASONIC WAVES
- G01H13/00—Measuring resonant frequency
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01V—GEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
- G01V1/00—Seismology; Seismic or acoustic prospecting or detecting
- G01V1/001—Acoustic presence detection
-
- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
- G10K11/02—Mechanical acoustic impedances; Impedance matching, e.g. by horns; Acoustic resonators
-
- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
- G10K13/00—Cones, diaphragms, or the like, for emitting or receiving sound in general
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/01—Measuring temperature of body parts ; Diagnostic temperature sensing, e.g. for malignant or inflamed tissue
Abstract
A passive sensor system (14) utilizing ultrasonic energy is disclosed. The passive sensor system includes at least one ultrasonically vibratable sensor (10) and an ultrasonic activation and detection system (20, 22, 24, 25). The sensor (10) has at least one vibration frequency which is a function of a physical variable to be sensed. The ultrasonic activation and detection system (20, 22, 24, 25) excites the sensor and detects the vibration frequency from which it determines a value of the physical variable. The sensor includes (see fig.2-4) a housing, a membrane which is attached to the housing and which is responsive to the physical variable, a vibratable beam attached to the housing at one end and a coupler, attached to the membrane and to a small portion of the vibratable beam, which bends the vibratable beam in response to movement of the membrane.
Description
2 1 ~ 2 1 ~ 3 PCIIUS95/0107~
A PASSIVE SENSOR SYSTEM USI~IG ULTRASONlC ENERGY
S FIELD OF THE INVENTION
- The present invention relates to passive sensors in general and to ultrasonic pai~iive sensors in particular.
BACKGROUND OF THE INVENTION
Passive sensors (for implanting into the human body or for mounting at some -^~c~cible location within a machine) are known in the art. These sensors are typically ele.~ o,ti~, providing an el~.,--.agr~tic signal when activated.
IS The prior art sensor system typically co.. l.l;~s a sensor, implanted into the m chin~ and an a~i~,~ti"g and Atot~ system. The sensor is typically an oscillq~ing circuit who~se vibration frequency changes in r~ se to the physical variable to be me~u,cd. The o~cillating circuit typically includes a cqp ^~tor and an in~luc~ot~ one of which is built to vary in accold~ce with the physical variable being l"e~u~ed. As a result, the vibration frequency 20 of the circuit is a fi~nction of the physical variable.
When the sensor is irradiated with el~tro~..a~etic energy from the activating system, some of the energy is absorbed by the oscillating circuit, depending on how close the inci~lent frequency or freql~ ncios are to the resonqnt rl~ue~ of the circuit (which, in turn, depend~i on the physical variable being measured). The change in the cl~,o.l,agnetic field due to the absorption of energy by the oscillating circuit is ~letecte~l by the ~etlorting system.
Electrom~n~tic sensors and systems . re described in the U.S. Patent 4,127,110 . nd in the article:
Carter C. Collins, "Miniature Passive P~ ule Transensorfor Implanting in the Eye", IEEE Transactions on Bio-Medical En~eineering. Vol. BME-14, No. 2, April 1967.
Unfortunately, within living tissue, the passive sensor is .ltotect~ble within arange no larger than 10 times the diameter of its antenna (pan of the oscillating circuit).
Funhermore, the sensor system is not operative within a conductive enclosure.
WO 95/20769 2 ~ 8 2 1 9 3 PcT/us9~/oln7~
..
SUMMARY OF THE PRESENT lNVENTlON
It is therefore an object of the present invention to provide a passive sensor ~;ystem which has none of the disadvantages listed hereinabove.
The present invention provides a passive sensor system lltili7i~ ultrasonic energy. The passive sensor includes a vibratable element vhose vibration frequency changes in response to physical variables (such as p~ u,e, tel.l~lat~e, etc.). The el~trrr ~1 activating and ~letecting system includes an ultrasorlic tr~n~-~ncer which tr~ncmitc an ultrasonic wave, having a range of L~-~ ncies, to the passive sensor which resonate~s in response only if the ultrasonic waves includes in it the current vibration frequency of the vibratable element.
Since the pre~sent invention utilizes ultrasonic waves, its range, at frequencies lower than 1 MHz, is s~ffiri~-nt for use in hull ans. Furth~o-nnore, the sensor is operative within con~ ctive enclosures.
In accor~ce with a preferred embo~limrnt of the present invention, the ull,dsonic activation and ~e~Pction system inrl~ PC a) an llltr~conir wave generator for gen~latillg an ~ r~-~ic wave having a desired L~, _ .~ band, b) an ull.~ ic tr~nc~lurer .sy.stem for ~ the ultrasonic wave and for receiving an ul1r~cQnic wave in ~nse and c) a r~ etectQr for .tetecting the vibration frequency of the sensor from the received ultrasonic wave.
Moreover, in accold~ce with a preferred embo~lim~nt of the present invention, the passive sensor has ex~t~tion and 1,~ ion ~r~e~ci~s. A~ tion~lly~ the sensor can have a reference vibration rr~l-~ncy.
In accold~ce with one embo~imPn' of the sensor, it inrl~l~ a) a housing, b) a membrane ttac~-~ to the housing and r~nc;~e to the physical variable, c) a vibratable beam ~tt--h~A to the holLsing at one end and d) a coupler, ~tt~rh~A to the membrane and to a small portion of the vibratable beam, which bends the vibratable beam in re~spon~se to movement of the membrane.
In accoldance with another embodiment of the sensor, the vibratable beam LC
at~acht d at two ends and the coupler divides the beam into two separate but coupled 30 vibratable beams vibratable at the excitation and tr~l.c,i~sion frequencies.
Moreover, in accor~nce with a further preferred embodiment of the present invention, the sensor includes a) a first cup shaped body having a flat base formed of a thin WO 95/20769 PCT'IUS95/01075 membrane vibratable at the excitation frequency and b) a second cup shaped body having a flat base tormed of a thick membrane vibratable at the tr~ncmiccion frequency. The f~t and second bodies are joined together so as to produce an encl~se~l space between them.
Finally, in accol iance with a still funher preferred em~im~ of the pre~sent S invention, the sensor system ir~ des a plurality of ~ co~ lly vibratable 5~nCorc each having a common input vibration frequency range and at least one output vibration frequency.
The ultra~sonic activation and detectio~ system trA~ C an l~ltr~ni~ wave having r~u~ncies within the input r,~ .cy range and detecLc the separate output vibration L~ ie.c.
wo ssno76s 2 1 8 2 l 9 3 P~/Usssl0l07~
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will be understood and al,l"eciated more fully from the following f1f ~ oA f~f~iption taken in conjul.~ lion with the drawings in which:Fig. 1 is a schematic illustration of an ull~ nic passive sensor system corLjllu~:(ed and o~ tive in accold~ce with a preferred embodiment of the present invention;
Fig. 2A is a s~ ic illustration of an passive sensor useful in the sensor system of Fig. I;
Fig. 2B is a s~ tic illustration of the sensor of Fig. 2A in the presence of 1 0 pl~ ~iulc, Fig. 2C is a schematic illustration of a sensor, sirnilar to that of Fig. 2A, which is sensitive to te.ll~c.dt~, Figs. 3A and 3B are schernatic il~ trDtions of an alternative sensor having two cu~,led vibrating beams and a reference beam, wh~leih Fig. 3A is a side view and Fig. 3B
15 is a top view taken along lines mB - mB of Flg. 3A;
Fig. 4A is a schematic ill~l,dtion of an ~lt~ ;ve two ~ ,~I,.~e sensor, Fig. 4B is a schematic ill~l,ation of a sensor. similar to that of Fig. 4A, which ic sen~sitive to r~ --ir~l _o ~;ti-U~; and Fig. S is a schematic illustration of a sensor system O~.dt~g with a plurality 20 of passive sensors.
, W095/20769 2 1 82 1 93 Pcr/usgs/o1o7~
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
Reference is now made to Fig. I which illustrates the ultrasonic sensor system of the present invention. The system comprises a passive sensor 10 and an cxternal ultrasonic S activation and ~letection system 14. The sensor 10 is implantable in an ultrasound cQInp~ible m~dium 12, such as the human body, or mountable on an inner wall of an enclosure.
The sensor 10 is any suitable sensor, examples of which are described hereinbelow with respect to Figs. 2 - 4, which ...rch~nicdlly vibrates in the presence of an ultrasonic wave, much as a tuning fork vibrates in the presence of a sonic wave. T~-lefole, 10 sensor 10 is lepr~ teA, S~ ,."~ir ~lly in Fig. 1. as a tuntng fork. The L~ n~ of vibration of sensor 10 is its current vibration rr~ue..cy which is a rw.~lion at least of the physica variable being sense~
The activation and ~1P~ti~n system 14 typically co.~-l..;.~s an ultrasonic generator 20, at least one ~ ".o..ic transducer 22, a fi~ucl.~r detector 24 and a data IS pr~cessor 25. The ul~ `ir generator 20 and tr~n~ rPr 22 c~ t~le the acti~ating el~ ,...~,.~ti and the ll;~n~l~-r~l 22, the L~eL~ ~IPtP~CtOr 24 and the data p~ ssor 2~ cQI~ .lPi the deteCI;n~ .. t~.
The g~ r P-r~tor 20, such as the non de~ ti~le testing unit, model m3 USDF, manufactured by Balteu Sonatest/Schlumberger of Milton Keynes, r~gl~ ge~ s an 20 ultrasonic wave to be ~.,.nc~ lPA by the ultrasonic transducer 22 to the sensor 10 via the Illcdi~ll 12. Typically, ultrasonic gel 26, located on an outer edge 28 of ~ A;~ 12, is utilized to couple the transducer 22 to the ~ A;I.... 12. Typically, the IlAn~ leA ultrasonic ~vave is co..-posed of a single fi~u~,~.~ or a range of frequencies.
The ~ ;c l~ J~cer 22, such as one part of the non~l~u~;ti.~e te~sting 25 unil, typically also ~ es ultrasonic ~vaves from the ~ 12. Some of these vaves are reflections of the t~Ar~C~ IeA ~vave; others are from sensor 10. In an ~lt~n~q~ive embo~lim~nt there are two ultrasonic t1AI~ 1S 22, one for t~A~ ;..g and one for receiving.
If the~ ultrasonic ~vaves have a frequency close or equivalent to the current vibration L~,ncy of the sensor 10, they will excite the sensor 10 to vibrate, in 30 effect, absorbing at least some of the tlAr.~...;llçrl wave at the current vibration frequency.
Thus. the waves received by transducer 22 include less of the current vibration frequency of sensor 10 than of other frequencies. In addition, the sensor 10 continues to vibrate even after W095/20769 21821~3 ~Cr/U595101~75 ransmi~Sion of ultrasonic waves has stopped. Thus. the transducer 22 continues to receive ultraconic waves and these are at the current vibration frequency of sensor 10.
The frequency detector 24. similar to the 8590A ~ Ulll analyær manufactured by Hewlett Packard Inc. of the U.S.A., analyzes the received ultrasonic waves S to determine which ll~u~,ncy has been absorbed by sensor 10 and/or at which frequency the ~en.~or 10 resonates when no longer excited by the tl~ cf~-~ic waves.
Data pr~ssor 25 converts the frequency ~et~....;. ~l by the frequency detector 24 into the value of the physical variable being l.,ea~u ed. The information needed for this conversion depP~lc on the actual structure of the sensor 10, as described in more detail 10 hereinbelow.
It will be ap~"~.ated that the system of the precent invention is implantable deep within living tissue or within a conductive .,~cl~.ue. The system o~lat S with l vibration rather than el~ resonance.
Reference is now made to Figs. 2A and 2B which ill..ctt~, a first embo~limPn~
of an exe.,~ y passive sensor, labeled 30, responsive to ~ . Figs. 2A and 2B illl~ctr~te the .censor 30 in Ihe absence and pl~nCe, f~:ti~rely, of p es~e.
Sensor 30 is ~ lly machined from silicon and typically c~lplJses a cup-shaped housing 32 having a recess 34, a vibratable beam 36, a mPmhrpr~. 38 and a coupler 40. The vibratable beam 36 is typically integrally attached to the }: ~cing 32 and çYtPn~C into rececs 34. The coupler 40 typically cQ~ P,~tc between membrane 38 and a far end 42 of beam 36. The coupler 40 is either integrally attached to the membrane 38 or the ~bratable beam 36.
As shown in Pig. 2B, ~ lane 38 typically bends into recess 34 in r~C~nse to l,r~ue &om the o~tcid~. ThLc causec co..~ 40, which is stiff, to presc on far end 42, 25 inducing beam 36 to bend and thus, ~tl~g it. As is known in the art, a strained be~n vibrate~s at a higher fi~._ncy than a non-strained beam. Thus, the higher the pr~ul~i on membrane 38, the higher the vibration frequency of beam 36. The specific relationship between ~r~u.~ and frequency of beam 36 dependc on the material of beam 36, iLs length and iLS cross-sc~t;..-~l area and to some extent to other factors, such a~s temperature and 30 viscosity of whatever ~ ll is within reces~s 34.
It is noted that, if the membrane was made of many materials or coated with other materiaLs, it would bend in re~sponse to other physical variable~s, such ac temperature.
WO 95t20769 PCI/US9510107:~
21821~3 For ~xampl~ Fig 2C illustrates a sensor responsiv~ to lemperature and Fig. 4B, lle:icrib~d h~reinbelow. illustrates a sensor responsive to chemical composition.
Reference is now briefly made to Fig. 2C. In this sensor. the membrane is made of two materials, 42 and 44, each having different th~ nql coefficiçntc. Exemplary materiaLs are silicon and silicon nitride. Since the materiaLs expand and contract at different rates, the membrane will buck~e as a function of the temperature.
Reference is now made to Figs. 3A and 3B which illustrate an ~lt~ tive emhodiment of the passive sensor which has different t~ ,ion and reception frequencies.
Funhermore, the sensor of Figs. 3A and 3B also has a reference rr~u.,ncy. Fig. 3A is a side view of the sensor, labeled 50, and Fig. 3B is a top view taken along lines mB - mB of Fig.
3A.
The sensor 50 is similar to sensor 30 (Fig. 2) in that it has a housing, labeled52, and a recess. Hc,~ , the vibratable el~ of sensor 50 is a full length beam 58.
Similar to sensor 30, sensor 50 also has a membrane 38 and a coupler 40. In thisemboAim~ n~ coupler 40 is c~ P~ to beam 58 somewhere other than at its middle so as to create two sep ~te but c~.lpl.o~ vibratable beams 60 and 62 which vibrate at different frequencies.
As ill .1.~t~ll in Fig. 3A, beam 60, defined as the length of beam 58 from a leh edge 64 of ~ 0~C;~ 52 to coupler 40, is longer than beam 62, defined as the length of beam 58 from a right edge 66 of housing 52 to coupler 40. Therefore, beam 60 vibrates at a lower frequency than beam 62.
In the presence of pr~ule, membrane 38 bends, pushing coupler 40 further into recess 54 and ~ , beam 58, ~ g both beams 60 and 62. When in C~ dtiOIl, thesensor system of the present invention excites sensor 50 with an ultrasonic wave whose range of frequencies is approximately the range of vibration frequencies of long beam 60. The long b~n 60 bccoll~cs excited and its excitation causes short beam 62 also to vibrate, but at its current vibration frequency.
Since the shon beam 62 typically has a vibration frequency range significantly different than that of the long beam 60~ the ultrasonic tr~nC~ucer 22 and frequency detector 24 need only be tuned, for reception purposes, to the frequency range of short beam 62.
Since only the short bearn 62 will be active in its frequency range, the signal to noise (S/N) rativ of the signal received by the transducer 22 will be high since there will be little or no WO 95/20769 2 1 ~3 2 PCI`/US9510107 noi~i~ ai~-xiated with the excitation frequency.
The sensor 50 can optionally aLso include a reference beam 68 (Fig. 3B), I(xale~l nexl to beam 58. Beam 68 is connecte-1 at both ends to housing 52 but is not conl~ecte~l to coupler 40. Therefore, the vibration frequency of beam 68 does not change with 5 pr~i~urt. Any changes of its vibration frequency must therefore be due to other causes, such a~ te."pe.dture, viscous damping, etc., which also affect the beam~s 60 and 62. The output of reference beam 68 is thus ..tili7~, by data processor 25, to correct the p~ c values determined from beams 60 and 62.
Reference is now briefly made to Fig. 4A which illustrates a further ~lt.on~ive 10 embodiment of the sensor formed of two silicon wafers 70 and 72. Typically, each wafer is formed into roughly a squared off zup shape and the two are bonded together so as to produce an enclosed spaoe 74. The base of each cup is flat, forming a membrane which can freely vibrate into spaoe 74. In order to l"u~;de the sensor of Pig. 4A with two different, cu..~lcd freqn~nci~.s the tl~ P~s of the m~mhr~noe, labeled 76 and 78, are dirr~cnt.
As in the cm~imp~t of Fig. 3A, the vibrating el/~ t with the lower vibration frequency, (i.e. thin membrane 78) receives the ul~ ir sigllal and the other membrane, thick m~ombr~ne 76, tl~ .-;le the reflected ul~ ic signal. The two ~,il,ldti,lg el~",~ t~s are co.,~le I via the sides of the wafers 70 and 72 and ~ugh whatever mcdiu", is placed into en~ spaoe 74.
A sensor similar to that shown in Fig. 4A can be used to ~ ch~.. i~l co",l,o6ilion. The resllltant sensor is illustrated in Fig. 4B to which reference is now made.
The thick rn~mbr~ne 76 of Fig. 4B is coated with a thin, soft, polymeric film 79 which absorbs gas phaee analytes. The anal~rtes add weight to film 79 and change its v~coel~ y.
As a result, the vibration frequency rhqn~.
Reference is now made to Fig. S which illustrates a sensor system having a plurality of passive sensors 80. The sensors 80 typically have at least two vibration frequencies, an input f~.ency fi and an output frequency foi, where, in the example of Fig.
5, i = I to 5. The input frequency can be identical for each sensor 80, or it can be within a predeterrnined range.
The output frequencies foi are typically designed to be in separate, non-overlapping frequency ranges such that each sensor is separately ~elect~ble for all values of the physical variable being l"e~u~,d. ln this ~ nl~r~ the value of the physical variable can ~. WO 95120769 PCI`/US95/0107~
21 ~21 ~3 be measured along a line, or within a region, at one time.
The s~ncor~ 80 can be formed of sensors similar to those shown in Figs. 3 and 4. For a set of sensors similar to those of Fig. 3, the lengths of each of the long bean~ are of a sirnilar length while the lengths of the shon beams are significantly different. For a set S of sensors similar to those of Pig. 4, the thin membranes of each are of a similar thi but the thiclcness of the thiclc membranes are different.
It will be ~plc~ted by ~.so~s sldlled in the an that the present invention is not limited to what has been particularly shown and described hereinabove. Rather the - scope of the present invention is deflned by the claims which follow
A PASSIVE SENSOR SYSTEM USI~IG ULTRASONlC ENERGY
S FIELD OF THE INVENTION
- The present invention relates to passive sensors in general and to ultrasonic pai~iive sensors in particular.
BACKGROUND OF THE INVENTION
Passive sensors (for implanting into the human body or for mounting at some -^~c~cible location within a machine) are known in the art. These sensors are typically ele.~ o,ti~, providing an el~.,--.agr~tic signal when activated.
IS The prior art sensor system typically co.. l.l;~s a sensor, implanted into the m chin~ and an a~i~,~ti"g and Atot~ system. The sensor is typically an oscillq~ing circuit who~se vibration frequency changes in r~ se to the physical variable to be me~u,cd. The o~cillating circuit typically includes a cqp ^~tor and an in~luc~ot~ one of which is built to vary in accold~ce with the physical variable being l"e~u~ed. As a result, the vibration frequency 20 of the circuit is a fi~nction of the physical variable.
When the sensor is irradiated with el~tro~..a~etic energy from the activating system, some of the energy is absorbed by the oscillating circuit, depending on how close the inci~lent frequency or freql~ ncios are to the resonqnt rl~ue~ of the circuit (which, in turn, depend~i on the physical variable being measured). The change in the cl~,o.l,agnetic field due to the absorption of energy by the oscillating circuit is ~letecte~l by the ~etlorting system.
Electrom~n~tic sensors and systems . re described in the U.S. Patent 4,127,110 . nd in the article:
Carter C. Collins, "Miniature Passive P~ ule Transensorfor Implanting in the Eye", IEEE Transactions on Bio-Medical En~eineering. Vol. BME-14, No. 2, April 1967.
Unfortunately, within living tissue, the passive sensor is .ltotect~ble within arange no larger than 10 times the diameter of its antenna (pan of the oscillating circuit).
Funhermore, the sensor system is not operative within a conductive enclosure.
WO 95/20769 2 ~ 8 2 1 9 3 PcT/us9~/oln7~
..
SUMMARY OF THE PRESENT lNVENTlON
It is therefore an object of the present invention to provide a passive sensor ~;ystem which has none of the disadvantages listed hereinabove.
The present invention provides a passive sensor system lltili7i~ ultrasonic energy. The passive sensor includes a vibratable element vhose vibration frequency changes in response to physical variables (such as p~ u,e, tel.l~lat~e, etc.). The el~trrr ~1 activating and ~letecting system includes an ultrasorlic tr~n~-~ncer which tr~ncmitc an ultrasonic wave, having a range of L~-~ ncies, to the passive sensor which resonate~s in response only if the ultrasonic waves includes in it the current vibration frequency of the vibratable element.
Since the pre~sent invention utilizes ultrasonic waves, its range, at frequencies lower than 1 MHz, is s~ffiri~-nt for use in hull ans. Furth~o-nnore, the sensor is operative within con~ ctive enclosures.
In accor~ce with a preferred embo~limrnt of the present invention, the ull,dsonic activation and ~e~Pction system inrl~ PC a) an llltr~conir wave generator for gen~latillg an ~ r~-~ic wave having a desired L~, _ .~ band, b) an ull.~ ic tr~nc~lurer .sy.stem for ~ the ultrasonic wave and for receiving an ul1r~cQnic wave in ~nse and c) a r~ etectQr for .tetecting the vibration frequency of the sensor from the received ultrasonic wave.
Moreover, in accold~ce with a preferred embo~lim~nt of the present invention, the passive sensor has ex~t~tion and 1,~ ion ~r~e~ci~s. A~ tion~lly~ the sensor can have a reference vibration rr~l-~ncy.
In accold~ce with one embo~imPn' of the sensor, it inrl~l~ a) a housing, b) a membrane ttac~-~ to the housing and r~nc;~e to the physical variable, c) a vibratable beam ~tt--h~A to the holLsing at one end and d) a coupler, ~tt~rh~A to the membrane and to a small portion of the vibratable beam, which bends the vibratable beam in re~spon~se to movement of the membrane.
In accoldance with another embodiment of the sensor, the vibratable beam LC
at~acht d at two ends and the coupler divides the beam into two separate but coupled 30 vibratable beams vibratable at the excitation and tr~l.c,i~sion frequencies.
Moreover, in accor~nce with a further preferred embodiment of the present invention, the sensor includes a) a first cup shaped body having a flat base formed of a thin WO 95/20769 PCT'IUS95/01075 membrane vibratable at the excitation frequency and b) a second cup shaped body having a flat base tormed of a thick membrane vibratable at the tr~ncmiccion frequency. The f~t and second bodies are joined together so as to produce an encl~se~l space between them.
Finally, in accol iance with a still funher preferred em~im~ of the pre~sent S invention, the sensor system ir~ des a plurality of ~ co~ lly vibratable 5~nCorc each having a common input vibration frequency range and at least one output vibration frequency.
The ultra~sonic activation and detectio~ system trA~ C an l~ltr~ni~ wave having r~u~ncies within the input r,~ .cy range and detecLc the separate output vibration L~ ie.c.
wo ssno76s 2 1 8 2 l 9 3 P~/Usssl0l07~
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will be understood and al,l"eciated more fully from the following f1f ~ oA f~f~iption taken in conjul.~ lion with the drawings in which:Fig. 1 is a schematic illustration of an ull~ nic passive sensor system corLjllu~:(ed and o~ tive in accold~ce with a preferred embodiment of the present invention;
Fig. 2A is a s~ ic illustration of an passive sensor useful in the sensor system of Fig. I;
Fig. 2B is a s~ tic illustration of the sensor of Fig. 2A in the presence of 1 0 pl~ ~iulc, Fig. 2C is a schematic illustration of a sensor, sirnilar to that of Fig. 2A, which is sensitive to te.ll~c.dt~, Figs. 3A and 3B are schernatic il~ trDtions of an alternative sensor having two cu~,led vibrating beams and a reference beam, wh~leih Fig. 3A is a side view and Fig. 3B
15 is a top view taken along lines mB - mB of Flg. 3A;
Fig. 4A is a schematic ill~l,dtion of an ~lt~ ;ve two ~ ,~I,.~e sensor, Fig. 4B is a schematic ill~l,ation of a sensor. similar to that of Fig. 4A, which ic sen~sitive to r~ --ir~l _o ~;ti-U~; and Fig. S is a schematic illustration of a sensor system O~.dt~g with a plurality 20 of passive sensors.
, W095/20769 2 1 82 1 93 Pcr/usgs/o1o7~
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
Reference is now made to Fig. I which illustrates the ultrasonic sensor system of the present invention. The system comprises a passive sensor 10 and an cxternal ultrasonic S activation and ~letection system 14. The sensor 10 is implantable in an ultrasound cQInp~ible m~dium 12, such as the human body, or mountable on an inner wall of an enclosure.
The sensor 10 is any suitable sensor, examples of which are described hereinbelow with respect to Figs. 2 - 4, which ...rch~nicdlly vibrates in the presence of an ultrasonic wave, much as a tuning fork vibrates in the presence of a sonic wave. T~-lefole, 10 sensor 10 is lepr~ teA, S~ ,."~ir ~lly in Fig. 1. as a tuntng fork. The L~ n~ of vibration of sensor 10 is its current vibration rr~ue..cy which is a rw.~lion at least of the physica variable being sense~
The activation and ~1P~ti~n system 14 typically co.~-l..;.~s an ultrasonic generator 20, at least one ~ ".o..ic transducer 22, a fi~ucl.~r detector 24 and a data IS pr~cessor 25. The ul~ `ir generator 20 and tr~n~ rPr 22 c~ t~le the acti~ating el~ ,...~,.~ti and the ll;~n~l~-r~l 22, the L~eL~ ~IPtP~CtOr 24 and the data p~ ssor 2~ cQI~ .lPi the deteCI;n~ .. t~.
The g~ r P-r~tor 20, such as the non de~ ti~le testing unit, model m3 USDF, manufactured by Balteu Sonatest/Schlumberger of Milton Keynes, r~gl~ ge~ s an 20 ultrasonic wave to be ~.,.nc~ lPA by the ultrasonic transducer 22 to the sensor 10 via the Illcdi~ll 12. Typically, ultrasonic gel 26, located on an outer edge 28 of ~ A;~ 12, is utilized to couple the transducer 22 to the ~ A;I.... 12. Typically, the IlAn~ leA ultrasonic ~vave is co..-posed of a single fi~u~,~.~ or a range of frequencies.
The ~ ;c l~ J~cer 22, such as one part of the non~l~u~;ti.~e te~sting 25 unil, typically also ~ es ultrasonic ~vaves from the ~ 12. Some of these vaves are reflections of the t~Ar~C~ IeA ~vave; others are from sensor 10. In an ~lt~n~q~ive embo~lim~nt there are two ultrasonic t1AI~ 1S 22, one for t~A~ ;..g and one for receiving.
If the~ ultrasonic ~vaves have a frequency close or equivalent to the current vibration L~,ncy of the sensor 10, they will excite the sensor 10 to vibrate, in 30 effect, absorbing at least some of the tlAr.~...;llçrl wave at the current vibration frequency.
Thus. the waves received by transducer 22 include less of the current vibration frequency of sensor 10 than of other frequencies. In addition, the sensor 10 continues to vibrate even after W095/20769 21821~3 ~Cr/U595101~75 ransmi~Sion of ultrasonic waves has stopped. Thus. the transducer 22 continues to receive ultraconic waves and these are at the current vibration frequency of sensor 10.
The frequency detector 24. similar to the 8590A ~ Ulll analyær manufactured by Hewlett Packard Inc. of the U.S.A., analyzes the received ultrasonic waves S to determine which ll~u~,ncy has been absorbed by sensor 10 and/or at which frequency the ~en.~or 10 resonates when no longer excited by the tl~ cf~-~ic waves.
Data pr~ssor 25 converts the frequency ~et~....;. ~l by the frequency detector 24 into the value of the physical variable being l.,ea~u ed. The information needed for this conversion depP~lc on the actual structure of the sensor 10, as described in more detail 10 hereinbelow.
It will be ap~"~.ated that the system of the precent invention is implantable deep within living tissue or within a conductive .,~cl~.ue. The system o~lat S with l vibration rather than el~ resonance.
Reference is now made to Figs. 2A and 2B which ill..ctt~, a first embo~limPn~
of an exe.,~ y passive sensor, labeled 30, responsive to ~ . Figs. 2A and 2B illl~ctr~te the .censor 30 in Ihe absence and pl~nCe, f~:ti~rely, of p es~e.
Sensor 30 is ~ lly machined from silicon and typically c~lplJses a cup-shaped housing 32 having a recess 34, a vibratable beam 36, a mPmhrpr~. 38 and a coupler 40. The vibratable beam 36 is typically integrally attached to the }: ~cing 32 and çYtPn~C into rececs 34. The coupler 40 typically cQ~ P,~tc between membrane 38 and a far end 42 of beam 36. The coupler 40 is either integrally attached to the membrane 38 or the ~bratable beam 36.
As shown in Pig. 2B, ~ lane 38 typically bends into recess 34 in r~C~nse to l,r~ue &om the o~tcid~. ThLc causec co..~ 40, which is stiff, to presc on far end 42, 25 inducing beam 36 to bend and thus, ~tl~g it. As is known in the art, a strained be~n vibrate~s at a higher fi~._ncy than a non-strained beam. Thus, the higher the pr~ul~i on membrane 38, the higher the vibration frequency of beam 36. The specific relationship between ~r~u.~ and frequency of beam 36 dependc on the material of beam 36, iLs length and iLS cross-sc~t;..-~l area and to some extent to other factors, such a~s temperature and 30 viscosity of whatever ~ ll is within reces~s 34.
It is noted that, if the membrane was made of many materials or coated with other materiaLs, it would bend in re~sponse to other physical variable~s, such ac temperature.
WO 95t20769 PCI/US9510107:~
21821~3 For ~xampl~ Fig 2C illustrates a sensor responsiv~ to lemperature and Fig. 4B, lle:icrib~d h~reinbelow. illustrates a sensor responsive to chemical composition.
Reference is now briefly made to Fig. 2C. In this sensor. the membrane is made of two materials, 42 and 44, each having different th~ nql coefficiçntc. Exemplary materiaLs are silicon and silicon nitride. Since the materiaLs expand and contract at different rates, the membrane will buck~e as a function of the temperature.
Reference is now made to Figs. 3A and 3B which illustrate an ~lt~ tive emhodiment of the passive sensor which has different t~ ,ion and reception frequencies.
Funhermore, the sensor of Figs. 3A and 3B also has a reference rr~u.,ncy. Fig. 3A is a side view of the sensor, labeled 50, and Fig. 3B is a top view taken along lines mB - mB of Fig.
3A.
The sensor 50 is similar to sensor 30 (Fig. 2) in that it has a housing, labeled52, and a recess. Hc,~ , the vibratable el~ of sensor 50 is a full length beam 58.
Similar to sensor 30, sensor 50 also has a membrane 38 and a coupler 40. In thisemboAim~ n~ coupler 40 is c~ P~ to beam 58 somewhere other than at its middle so as to create two sep ~te but c~.lpl.o~ vibratable beams 60 and 62 which vibrate at different frequencies.
As ill .1.~t~ll in Fig. 3A, beam 60, defined as the length of beam 58 from a leh edge 64 of ~ 0~C;~ 52 to coupler 40, is longer than beam 62, defined as the length of beam 58 from a right edge 66 of housing 52 to coupler 40. Therefore, beam 60 vibrates at a lower frequency than beam 62.
In the presence of pr~ule, membrane 38 bends, pushing coupler 40 further into recess 54 and ~ , beam 58, ~ g both beams 60 and 62. When in C~ dtiOIl, thesensor system of the present invention excites sensor 50 with an ultrasonic wave whose range of frequencies is approximately the range of vibration frequencies of long beam 60. The long b~n 60 bccoll~cs excited and its excitation causes short beam 62 also to vibrate, but at its current vibration frequency.
Since the shon beam 62 typically has a vibration frequency range significantly different than that of the long beam 60~ the ultrasonic tr~nC~ucer 22 and frequency detector 24 need only be tuned, for reception purposes, to the frequency range of short beam 62.
Since only the short bearn 62 will be active in its frequency range, the signal to noise (S/N) rativ of the signal received by the transducer 22 will be high since there will be little or no WO 95/20769 2 1 ~3 2 PCI`/US9510107 noi~i~ ai~-xiated with the excitation frequency.
The sensor 50 can optionally aLso include a reference beam 68 (Fig. 3B), I(xale~l nexl to beam 58. Beam 68 is connecte-1 at both ends to housing 52 but is not conl~ecte~l to coupler 40. Therefore, the vibration frequency of beam 68 does not change with 5 pr~i~urt. Any changes of its vibration frequency must therefore be due to other causes, such a~ te."pe.dture, viscous damping, etc., which also affect the beam~s 60 and 62. The output of reference beam 68 is thus ..tili7~, by data processor 25, to correct the p~ c values determined from beams 60 and 62.
Reference is now briefly made to Fig. 4A which illustrates a further ~lt.on~ive 10 embodiment of the sensor formed of two silicon wafers 70 and 72. Typically, each wafer is formed into roughly a squared off zup shape and the two are bonded together so as to produce an enclosed spaoe 74. The base of each cup is flat, forming a membrane which can freely vibrate into spaoe 74. In order to l"u~;de the sensor of Pig. 4A with two different, cu..~lcd freqn~nci~.s the tl~ P~s of the m~mhr~noe, labeled 76 and 78, are dirr~cnt.
As in the cm~imp~t of Fig. 3A, the vibrating el/~ t with the lower vibration frequency, (i.e. thin membrane 78) receives the ul~ ir sigllal and the other membrane, thick m~ombr~ne 76, tl~ .-;le the reflected ul~ ic signal. The two ~,il,ldti,lg el~",~ t~s are co.,~le I via the sides of the wafers 70 and 72 and ~ugh whatever mcdiu", is placed into en~ spaoe 74.
A sensor similar to that shown in Fig. 4A can be used to ~ ch~.. i~l co",l,o6ilion. The resllltant sensor is illustrated in Fig. 4B to which reference is now made.
The thick rn~mbr~ne 76 of Fig. 4B is coated with a thin, soft, polymeric film 79 which absorbs gas phaee analytes. The anal~rtes add weight to film 79 and change its v~coel~ y.
As a result, the vibration frequency rhqn~.
Reference is now made to Fig. S which illustrates a sensor system having a plurality of passive sensors 80. The sensors 80 typically have at least two vibration frequencies, an input f~.ency fi and an output frequency foi, where, in the example of Fig.
5, i = I to 5. The input frequency can be identical for each sensor 80, or it can be within a predeterrnined range.
The output frequencies foi are typically designed to be in separate, non-overlapping frequency ranges such that each sensor is separately ~elect~ble for all values of the physical variable being l"e~u~,d. ln this ~ nl~r~ the value of the physical variable can ~. WO 95120769 PCI`/US95/0107~
21 ~21 ~3 be measured along a line, or within a region, at one time.
The s~ncor~ 80 can be formed of sensors similar to those shown in Figs. 3 and 4. For a set of sensors similar to those of Fig. 3, the lengths of each of the long bean~ are of a sirnilar length while the lengths of the shon beams are significantly different. For a set S of sensors similar to those of Pig. 4, the thin membranes of each are of a similar thi but the thiclcness of the thiclc membranes are different.
It will be ~plc~ted by ~.so~s sldlled in the an that the present invention is not limited to what has been particularly shown and described hereinabove. Rather the - scope of the present invention is deflned by the claims which follow
Claims (13)
1. A passive sensor system utilizing energy, the system comprising:
at least one ultrasonically vibratable sensor having at least one vibration frequency, each vibration frequency is a function of a physical variable to be sensed; and an ultrasonic activation and detection system for exciting said sensor and for detecting said at least one vibration frequency thereby to determine a value of said physical variable.
at least one ultrasonically vibratable sensor having at least one vibration frequency, each vibration frequency is a function of a physical variable to be sensed; and an ultrasonic activation and detection system for exciting said sensor and for detecting said at least one vibration frequency thereby to determine a value of said physical variable.
2. A system according to claim 1 and wherein said ultrasonic activation and detection system comprises:
an ultrasonic wave generator for generating an ultrasonic wave having a desired frequency band;
a frequency detector for detecting said vibration frequency of said sensor from said received ultrasonic wave.
an ultrasonic wave generator for generating an ultrasonic wave having a desired frequency band;
a frequency detector for detecting said vibration frequency of said sensor from said received ultrasonic wave.
3. A system according to claim 2 and wherein said ultrasonic activation and detection system additionally comprises a data processor for converting said detected vibration frequency to said value of said physical variable.
4. A system according to claim 1 and wherein said passive sensor has excitation and transmission frequencies.
5. A system according to claim 4 and wherein said passive sensor also has a reference vibration frequency.
6. A system according to claim 1 and wherein said sensor comprises:
a housing;
a membrane attached to said housing and responsive to said physical variable;
a vibratable beam attached to said housing at one end; and a coupler, attached to said membrane and to a small portion of said vibratable beam, which bends said vibratable beam in response to movement of said membrane.
a housing;
a membrane attached to said housing and responsive to said physical variable;
a vibratable beam attached to said housing at one end; and a coupler, attached to said membrane and to a small portion of said vibratable beam, which bends said vibratable beam in response to movement of said membrane.
7. A system according to claim 4 and wherein said sensor comprises:
a housing;
a membrane attached to said housing and responsive to said physical variable;
a vibratable beam attached to said housing at two ends; and a coupler, attached to said membrane and to said vibratable beam at a location not close to a center of said vibratable beam thereby separating said vibratable beam into two separate but coupled vibratable beams vibratable at said excitation and transmission frequencies, which bends said vibratable beam in response to movement of said membrane.
a housing;
a membrane attached to said housing and responsive to said physical variable;
a vibratable beam attached to said housing at two ends; and a coupler, attached to said membrane and to said vibratable beam at a location not close to a center of said vibratable beam thereby separating said vibratable beam into two separate but coupled vibratable beams vibratable at said excitation and transmission frequencies, which bends said vibratable beam in response to movement of said membrane.
8. A system according to claim 5 and wherein said sensor also comprises a reference beam attached to said housing at two ends.
9. A system according to claim 7 and wherein said sensor also comprises a reference beam attached to said housing at two ends.
10. A system according to claim 4 and wherein said sensor comprises:
a first cup shaped body having a flat base formed of a thin membrane vibratable at said excitation frequency; and a second cup shaped body having a flat base formed of a thick membrane vibratable at said transmission frequency, wherein said first and second bodies are joined together so as to produce an enclosed space between them.
a first cup shaped body having a flat base formed of a thin membrane vibratable at said excitation frequency; and a second cup shaped body having a flat base formed of a thick membrane vibratable at said transmission frequency, wherein said first and second bodies are joined together so as to produce an enclosed space between them.
11. A passive sensor system utilizing ultrasonic energy, the system comprising:
a plurality of ultrasonically vibratable sensors each having a common input vibration frequency range and at least one output vibration frequency, wherein said vibration frequencies are a function of a physical variable to be sensed; and an ultrasonic activation and detection system for transmitting an ultrasonic wave having frequencies within said input frequency range, thereby to excite said sensors, and for detecting said output vibration frequencies thereby to determine a plurality of values of said physical variable.
a plurality of ultrasonically vibratable sensors each having a common input vibration frequency range and at least one output vibration frequency, wherein said vibration frequencies are a function of a physical variable to be sensed; and an ultrasonic activation and detection system for transmitting an ultrasonic wave having frequencies within said input frequency range, thereby to excite said sensors, and for detecting said output vibration frequencies thereby to determine a plurality of values of said physical variable.
12. A method of measuring a physical variable of a body, the method comprising the steps of:
activating, via an ultrasonic wave, a passive sensor located within the body andhaving a vibration frequency which is a function of said physical variable; and detecting said vibration frequency.
activating, via an ultrasonic wave, a passive sensor located within the body andhaving a vibration frequency which is a function of said physical variable; and detecting said vibration frequency.
13. A method of measuring a physical variable of a body, the method comprising the steps of:
transmitting an ultrasonic wave having a first range of vibration frequencies through said body thereby to activate a passive sensor located within said body, said passive sensor having an input vibration frequency within said first range and an output frequency outside of said first range, wherein both frequencies are functions of said physical variable;
and detecting said output vibration frequency.
transmitting an ultrasonic wave having a first range of vibration frequencies through said body thereby to activate a passive sensor located within said body, said passive sensor having an input vibration frequency within said first range and an output frequency outside of said first range, wherein both frequencies are functions of said physical variable;
and detecting said output vibration frequency.
Applications Claiming Priority (2)
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IL108470 | 1994-01-28 | ||
IL10847094A IL108470A (en) | 1994-01-28 | 1994-01-28 | Passive sensor system using ultrasonic energy |
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CA2182193A1 true CA2182193A1 (en) | 1995-08-03 |
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ID=11065744
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CA002182193A Abandoned CA2182193A1 (en) | 1994-01-28 | 1995-01-27 | A passive sensor system using ultrasonic energy |
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EP (1) | EP0741873B1 (en) |
JP (1) | JPH09508469A (en) |
AU (1) | AU695757B2 (en) |
CA (1) | CA2182193A1 (en) |
DE (1) | DE69509750T2 (en) |
ES (1) | ES2132637T3 (en) |
IL (1) | IL108470A (en) |
WO (1) | WO1995020769A1 (en) |
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1994
- 1994-01-28 IL IL10847094A patent/IL108470A/en not_active IP Right Cessation
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- 1995-01-27 WO PCT/US1995/001075 patent/WO1995020769A1/en active IP Right Grant
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WO1995020769A1 (en) | 1995-08-03 |
AU695757B2 (en) | 1998-08-20 |
DE69509750T2 (en) | 1999-12-23 |
ES2132637T3 (en) | 1999-08-16 |
US5619997A (en) | 1997-04-15 |
JPH09508469A (en) | 1997-08-26 |
EP0741873A1 (en) | 1996-11-13 |
EP0741873B1 (en) | 1999-05-19 |
IL108470A (en) | 1998-12-06 |
DE69509750D1 (en) | 1999-06-24 |
IL108470A0 (en) | 1994-04-12 |
AU1692195A (en) | 1995-08-15 |
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