JP4026030B2 - Ultrasonic touch panel - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an ultrasonic touch panel for detecting a position where a human finger or an object is in contact with a plate surface of a piezoelectric substrate provided with interdigital electrodes for input and output.
[0002]
[Prior art]
  A conventional touch panel using an ultrasonic method utilizes the fact that a surface acoustic wave is attenuated by exciting a surface acoustic wave on a non-piezoelectric plate and coming into contact with the non-piezoelectric plate. Examples of conventional methods for exciting a surface acoustic wave on a non-piezoelectric plate include a method of indirectly exciting with a wedge-shaped transducer using a bulk wave vibrator, a method of directly exciting with a piezoelectric thin film transducer, and the like. The wedge-shaped transducer is used for non-destructive inspection using ultrasonic waves, but is used only in a relatively low frequency range due to the problem of the working accuracy of the wedge angle. A piezoelectric thin film transducer is a method in which a piezoelectric thin film such as ZnO is vapor-deposited on a substrate and a surface acoustic wave is excited by an interdigital electrode, and is used as a high frequency device because it exhibits various transmission characteristics depending on the configuration of the interdigital electrode. There are problems in workability and mass productivity as well as in the VHF band. As described above, the conventional ultrasonic touch panel has problems in response time, sensitivity, durability, work accuracy, workability, mass productivity, ease of use, and the like, and the use frequency range is also limited. In addition, the conventional touch panel has to have a complicated signal processing method.
[0003]
[Problems to be solved by the invention]
  Conventional ultrasonic touch panels not only have problems in sensitivity, machining accuracy, workability, mass productivity, power consumption, etc., but also have problems in signal processing methods and circuit configurations.
  The object of the present invention is an ultrasonic wave excellent in processability, durability and mass productivity, low power consumption drive, short response time, simple signal processing, small circuit scale, and excellent usability It is to provide a touch panel.
[0004]
[Means for Solving the Problems]
  The ultrasonic touch panel according to claim 1 is a piezoelectric substrate, two ultrasonic transmission / reception means provided on one surface of the piezoelectric substrate, and information processing connected to the two ultrasonic transmission / reception means. The ultrasonic touch panel comprises a plurality of interdigital electrodes for input and interdigital electrodes for output corresponding to the interdigital electrodes for input, and the interdigital transducer for output. The crossing region of the electrode fingers of the electrode is one group R_i(I = 1) or N groups R_i(I = 1, 2,..., N) and the two groups R_iAnd R_{(I + 1)}(N-1) pieces Q sandwiched between_i{I = 1, 2,..., (N−1)}, each group R_iIs the two parts R_iaAnd R_ibAnd part R sandwiched between them_imAnd the part R_iaAnd R_ibThe direction of each electrode finger is parallel to the direction of the electrode finger of the input interdigital electrode, and the portion R_iaAnd R_ibEach electrode cycle length is equal to the electrode cycle length P of the input interdigital electrode, and the portion R_imOf the input interdigital transducer has an angle α with respect to the electrode finger of the interdigital electrode for input, and the portion R_imPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_RNIs equal to the product of the electrode period length P and cos α, and the portion R_imIn the electrode crossing width, the portion R_imCrossing width L in the direction of the electrode finger_RPAnd an intersection width L in a direction parallel to the electrode fingers of the interdigital transducer for input_RNAnd the intersection width L_RPIs the intersection width L_RNAnd secα, and equal to the product of half of the electrode period length P and cosecα, the portion Q_iOf the input interdigital electrode has an angle of ± β with respect to the electrode finger of the interdigital electrode for input, and the portion Q_iPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_QNIs equal to the product of the electrode period length P and cos β, and the portion Q_iThe electrode crossing width of_iCrossing width L in the direction of the electrode finger_QPAnd an intersection width L in a direction parallel to the electrode fingers of the interdigital transducer for input_QNAnd the intersection width L_QPIs the intersection width L_QNIs equal to the product of secβ and the part R_iaAnd R_ibEach electrode cross width and the cross width L_RNAnd the intersection width L_QNIs substantially equal to the electrode crossing width L of the input interdigital electrode, and the input interdigital electrode excites ultrasonic waves to the piezoelectric substrate when an electric signal is input, and the portion R_iaAnd R_ibConverts the ultrasonic wave into an electric signal E_iaAnd E_ib(I = 1, 2,..., N) respectively, and the electric signal E_iaAnd E_ibThe amplitude of the electric signal generated by synthesizing the two is zero, and the interdigital electrodes for input and output are formed on the portion R of the piezoelectric substrate._iaAnd R_ibUltrasonic wave propagation path Z corresponding to each_iaAnd Z_ib(I = 1, 2,..., N) and position F on the piezoelectric substrate_iaAnd F_ib(I = 1, 2,..., N) is the ultrasonic wave propagation path Z_iaAnd Z_ibAnd the output interdigital electrode corresponds to the position F._iaOr F_ibA finger or object comes into contact with the ultrasonic wave propagation path Z_iaOr Z_ibOnly when the electric signal E is interrupted._ibOr E_iaThe information processing unit outputs the position F_iaOne of F_XaThe position F_XaPosition F that is paired with_XbElectrical signal E corresponding to_XbIs detected from the output interdigital electrode or the position F is detected._XbThe position F_XaElectrical signal E corresponding to_XaIs detected from the output interdigital electrode.
[0005]
  The ultrasonic touch panel according to claim 2, wherein the intersection width L_QPThe electrode period length P is changed to the group R_iIs equal to the product of cosecβ and the value divided by twice the number N.
[0006]
  The ultrasonic touch panel according to claim 3 is a piezoelectric substrate, two ultrasonic transmission / reception means provided on one surface of the piezoelectric substrate, and information processing connected to the two ultrasonic transmission / reception means. The ultrasonic touch panel comprises a plurality of interdigital electrodes for input and interdigital electrodes for output corresponding to the interdigital electrodes for input. The crossing region of the electrode fingers of the electrode is an N portion A_i(I = 1, 2,..., N) and the two parts A_iAnd A_{(I + 1)}(N-1) parts B sandwiched between_i{I = 1, 2,... (N−1)}, and the intersection region of the electrode fingers of the output interdigital electrode has (N + 1) portions C_i{I = 1, 2,... (N + 1)} and the two parts C_iAnd C_{(I + 1)}N parts D sandwiched between_i(I = 1, 2,..., N) and the part A_iThe direction of the electrode finger is the portion C_iThe part B is parallel to the direction of the electrode fingers_iThe electrode finger is part A_iAnd the portion B_iPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_BNIs said part A_iAnd C_iIs equal to the product of the electrode period length P and cos β, and the portion B_iThe electrode crossing width of the part B_iCrossing width L in the direction of the electrode finger_BPAnd said part A_iWidth L in the direction parallel to the electrode fingers_BNAnd the intersection width L_BPIs the intersection width L_BNIs equal to the product of secβ and said part D_iThe electrode finger is part C_iThe portion D has an angle α with respect to the electrode fingers of_iPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_DNIs equal to the product of the electrode period length P and cos α, and the portion D_iThe electrode crossing width of the portion D_iCrossing width L in the direction of the electrode finger_DPAnd said part C_iWidth L in the direction parallel to the electrode fingers_DNAnd the intersection width L_DPIs the intersection width L_DNAnd secα, and equal to the product of half of the electrode period length P and cosecα, the portion A_iElectrode finger crossing width and the crossing width L_BNOf the part C_iElectrode finger crossing width and the crossing width L_DNThe interdigital electrode for input excites ultrasonic waves to the piezoelectric substrate by inputting an electric signal, and the interdigital electrode for output outputs the ultrasonic wave to N electrical signals E._ia(I = 1, 2,..., N) and N electrical signals E_ib(I = 1, 2,..., N) and the electric signal E_iaAnd E_ibThe amplitude of the electric signal generated by synthesizing the two is zero, and the interdigital electrodes for input and output are N ultrasonic propagation paths Z in the piezoelectric substrate._ia(I = 1, 2,..., N) and N ultrasonic propagation paths Z_ib(I = 1, 2,..., N) and the ultrasonic wave propagation path Z_iaIs said part A_iAnd C_iBetween the ultrasonic wave propagation path Z_ibIs said part A_iAnd C_{(I + 1)}The position F on the piezoelectric substrate_iaAnd F_ib(I = 1, 2,..., N) is the ultrasonic wave propagation path Z_iaAnd Z_ibAnd the output interdigital electrode corresponds to the position F._iaOr F_ibA finger or object comes into contact with the ultrasonic wave propagation path Z_iaOr Z_ibOnly when the electric signal E is interrupted._ibOr E_iaThe information processing unit outputs the position F_iaOne of F_XaThe position F_XaPosition F that is paired with_XbElectrical signal E corresponding to_XbIs detected from the output interdigital electrode or the position F is detected._XbThe position F_XaElectrical signal E corresponding to_XaIs detected from the output interdigital electrode.
[0007]
  The ultrasonic touch panel according to claim 4, wherein the intersection width L_BPThe electrode period length P is changed to the portion A._iIs equal to the product of cosecβ and the value divided by twice the number N.
[0008]
  The ultrasonic touch panel according to claim 5, wherein the information processing unit includes an amplifier and a signal processor, and an output end of the output interdigital electrode is connected to an input end of the input interdigital electrode and the input interdigital electrode. The electric signal E is connected to the input end of the signal processor._iaAnd E_ibIs the frequency f_iaAnd f_ibThe signal processor is in contact with the position F_XaThe electric signal E_XbFrequency f_XbThe position F is specified by detecting_XbThe electric signal E_XaFrequency f_XaIt is specified by detecting.
[0009]
  The ultrasonic touch panel according to claim 6, wherein each of the ultrasonic wave transmitting / receiving means includes two reference interdigital electrodes, one of the reference interdigital electrodes is used for input and the other is used for output. The directions of the electrode fingers of the two reference interdigital electrodes are parallel to each other, the information processing unit is composed of an amplifier, a phase comparator and a signal processor, and the output end of the other reference interdigital electrode is Via the amplifier, the reference interdigital electrodes and the input interdigital electrodes are connected to the input ends of the one and the input interdigital electrodes, and are connected to the input ends of the phase comparators. Is connected to the input end of the signal processor via the phase comparator, and the one of the reference interdigital electrodes excites an ultrasonic wave to the piezoelectric substrate by receiving an electric signal, and Kata reference interdigital transducer of the ultrasonic phase θ_baseThe electric signal E_iaAnd E_ibIs the phase θ_iaAnd θ_ibAnd the phase comparator has the phase θ_baseAnd the phase θ_iaOr θ_ibThe signal processor detects the difference between the position F_XaThe phase θ_baseAnd the electrical signal E_XbPhase θ_XbThe position F is specified based on the difference between_XbThe phase θ_baseAnd the electrical signal E_XaPhase θ_XaBased on the difference between
[0010]
  The ultrasonic touch panel according to claim 7, wherein the electrode cycle length P is larger than the thickness d of the piezoelectric substrate, and the interdigital transducer for input receives an electric signal having a frequency substantially corresponding to the electrode cycle length P. By being input, an elastic wave having a wavelength substantially equal to the electrode period length P is excited on the piezoelectric substrate.
[0011]
  The ultrasonic touch panel according to claim 8, wherein the electrode cycle length P has a value equal to or less than one-third of the thickness d of the piezoelectric substrate, and the interdigital electrodes for input are set to the electrode cycle length P. By inputting an electric signal having a substantially corresponding frequency, a surface acoustic wave having a wavelength substantially equal to the electrode period length P is excited in the vicinity of the surface of the one plate surface of the piezoelectric substrate.
[0012]
  The ultrasonic touch panel according to claim 9, wherein the piezoelectric substrate is made of a piezoelectric ceramic, and a direction of a polarization axis of the piezoelectric ceramic is parallel to a thickness direction of the piezoelectric ceramic.
[0013]
  The ultrasonic touch panel according to claim 10, wherein the ultrasonic wave propagation path Z in one of the ultrasonic wave transmitting / receiving means is provided._iaAnd Z_ibAnd the ultrasonic wave propagation path Z in the other ultrasonic wave transmitting / receiving means_iaAnd Z_ibAre orthogonal to each other.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
  The ultrasonic touch panel of the present invention includes a piezoelectric substrate, two ultrasonic wave transmitting / receiving means provided on one plate surface of the piezoelectric substrate, and an information processing unit connected to the two ultrasonic wave transmitting / receiving means. Each ultrasonic wave transmitting / receiving means comprises at least one set of input interdigital electrodes and an output interdigital electrode corresponding to the input interdigital electrodes.
[0015]
  In the first structure of the ultrasonic touch panel of the present invention, the input interdigital electrode has a regular structure. The intersection region of the electrode fingers of the output interdigital electrode is one group R_i(I = 1) only or N groups R_i(I = 1, 2,..., N) and two groups R_iAnd R_{(I + 1)}(N-1) pieces Q sandwiched between_i{I = 1, 2,... (N−1)}. Each group R_iIs the two parts R_iaAnd R_ibAnd part R sandwiched between them_imConsists of. Part R_iaAnd R_ibThe direction of each electrode finger is parallel to the direction of the electrode finger of the interdigital electrode for input, and the portion R_iaAnd R_ibEach electrode cycle length is equal to the electrode cycle length P of the input interdigital electrode. Part R_imAnd the electrode finger of the input interdigital electrode has an angle α with respect to the electrode finger of the input interdigital electrode, and the portion R_imPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_RNIs equal to the product of the electrode period length P and cos α. Part R_imThe electrode crossing width of the_imCrossing width L in the direction of the electrode finger_RPAnd the intersection width L in the direction parallel to the electrode fingers of the interdigital electrodes for input_RNThere are two types, intersection width L_RPIs the intersection width L_RNIs equal to the product of secα and the product of half of the electrode period length P and cosecα. Part Q_iThe electrode finger of FIG. 6 has an angle ± β with respect to the electrode finger of the interdigital electrode for input, and the portion Q_iPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_QNIs equal to the product of the electrode period length P and cos β. Part Q_iThe electrode crossing width of_iCrossing width L in the direction of the electrode finger_QPAnd the intersection width L in the direction parallel to the electrode fingers of the interdigital electrodes for input_QNThere are two types, intersection width L_QPIs the intersection width L_QNIs equal to the product of secβ. Furthermore, the intersection width L_QPRepresents the electrode period length P as group R_iIt is possible to take a value equal to the product of the value (P / 2N) divided by 2 times the number N of the above and cosecβ. Part R_iaAnd R_ibEach electrode cross width and cross width L_RNAnd intersection width L_QNIs substantially equal to the electrode crossing width L of the interdigital transducer for input.
[0016]
  In the first structure of the ultrasonic touch panel of the present invention, an ultrasonic signal can be excited on the piezoelectric substrate by inputting an electric signal to the interdigital electrodes for input. This ultrasonic wave is part R_iaAnd R_ibBy the electrical signal E_iaAnd E_ib(I = 1, 2,..., N) respectively. At this time, the electric signal E_iaAnd E_ibThe amplitude of the electric signal generated by synthesizing is zero. This is the intersection width L_RPIs the intersection width L_RNThis is due to being equal to the product of half of the electrode period length P and cosecα. The interdigital electrodes for input and output are formed on the piezoelectric substrate with a portion R_iaAnd R_ibUltrasonic wave propagation path Z corresponding to each_iaAnd Z_ib(I = 1, 2,..., N).That is, the elastic wave excited or received by the interdigital electrodes for input and output is considered to be in the direction orthogonal to the electrode fingers, and the width of the wave front of the elastic wave corresponds to the intersection width of the interdigital electrodes. Therefore, a portion R between the input and output interdigital electrodes is formed on the piezoelectric substrate. _ia And R _ib Ultrasonic wave propagation path Z corresponding to each _ia And Z _ib Will be formed. In this wayGroup R between the input and output interdigital electrodes_iThere are two times (2N) ultrasonic wave propagation paths of the number N.Accordingly, when contacting any position in the region between the input and output interdigital electrodes on the plate surface having the input and output interdigital electrodes of the piezoelectric substrate, or for inputting the piezoelectric substrate and When contacting any position of the portion corresponding to the region on the plate surface having no output interdigital electrode, the contact position is always the ultrasonic propagation path Z. _ia And Z _ib It will correspond to. In other words, the ultrasonic wave propagation path Z is always on one of the plate surfaces of the piezoelectric substrate. _ia And Z _ib Position F corresponding to each _ia And F _ib (I = 1, 2,..., N) exists.
  If the piezoelectric substrateEither one of the plate surfaceInPosition F _ia Or F _ib When a finger or object touches the position F_iaOr F_ibUltrasonic wave propagation path Z corresponding to each_iaOr Z_ibAt this time, the electric signal E_ibOr E_iaIs output from the output interdigital electrode.That is, the electric signal E _ib Or E _ia Only will appear as an output signal. In this wayThe information processing unit_iaOne of F_XaThe position F_XaPosition F that is paired with_XbElectrical signal E corresponding to_XbIs detected by being output from the interdigital electrode for output.That is, position F _Xa X in is one of i, for example if i = 2 then F _Xa = F _2a In this case, the position F _2a Position F that is paired with _2b Electrical signal E corresponding to _2b Is output from the output interdigital electrode, and the position F is thus obtained. _2a It is sensed that it touched.Similarly, the information processing unit_XbThe position F_XaElectrical signal E corresponding to_XaIs detected by being output from the interdigital electrode for output. In this way, the ultrasonic touch panel of the present invention has the position F of the touched piezoelectric substrate._iaOr F_ibCorresponding to the electrical signal E_ibOr E_iaCan be output.
[0017]
  In the second structure of the ultrasonic touch panel of the present invention, the intersection region of the electrode fingers of the interdigital electrodes for input has N portions A._i(I = 1, 2,..., N) and two parts A_iAnd A_{(I + 1)}(N-1) parts B sandwiched between_i{I = 1, 2,..., (N−1)}, and the intersection region of the electrode fingers of the output interdigital electrode is (N + 1) portions C_i{I = 1, 2,... (N + 1)} and two parts C_iAnd C_{(I + 1)}N parts D sandwiched between_i(I = 1, 2,..., N). Part A_iThe direction of the electrode finger is part C_iParallel to the direction of the electrode fingers. Part B_iThe electrode finger is part A_iWith an angle of -β with respect to the electrode fingers, and part B_iPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_BNIs part A_iAnd C_iIs equal to the product of the electrode period length P and cos β. Part B_iThe electrode crossing width of_iCrossing width L in the direction of the electrode finger_BPAnd part A_iWidth L in the direction parallel to the electrode fingers_BNThere are two types. Intersection width L_BPIs the intersection width L_BNIs equal to the product of secβ. Furthermore, the intersection width L_BPIs the electrode period length P as part A_iIt is possible to take a value equal to the product of the value (P / 2N) divided by 2 times the number N of the above and cosecβ. Part D_iThe electrode finger is part C_iWith an angle α to the electrode fingers of_iPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_DNIs equal to the product of the electrode period length P and cos α. Part D_iThe electrode crossing width of_iCrossing width L in the direction of the electrode finger_DPAnd part C_iWidth L in the direction parallel to the electrode fingers_DNThere are two types. Intersection width L_DPIs the intersection width L_DNIs equal to the product of secα and the product of half of the electrode period length P and cosecα. Part A_iElectrode finger cross width and cross width L_BNThe total of part C_iElectrode finger cross width and cross width L_DNIs approximately equal to the sum of
[0018]
  In the second structure of the ultrasonic touch panel of the present invention, an ultrasonic wave can be excited on the piezoelectric substrate by inputting an electric signal to the interdigital electrodes for input. This ultrasonic wave is generated by N electric signals E by an output interdigital electrode._ia(I = 1, 2,..., N) and N electrical signals E_ib(I = 1, 2,..., N). Electrical signal E_iaAnd E_ibThe amplitude of the electric signal generated by synthesizing is zero. This is the intersection width L_DPIs the intersection width L_DNThis is due to being equal to the product of half of the electrode period length P and cosecα. The interdigital electrodes for input and output are composed of N ultrasonic propagation paths Z on the piezoelectric substrate._ia(I = 1, 2,..., N) and N ultrasonic propagation paths Z_ib(I = 1, 2,..., N). That is, between the input and output interdigital electrodes, the portion A_iThere are two times (2N) of ultrasonic propagation paths, and the ultrasonic propagation path Z_iaIs part A_iAnd C_iBetween the ultrasonic propagation path Z_ibIs part A_iAnd C_{(I + 1)}Between.
  If the piezoelectric substrateEither one of the plate surfacePosition F at_iaOr F_ibWhen a finger or object touches (i = 1, 2,..., N), the position F_iaOr F_ibUltrasonic wave propagation path Z corresponding to each_iaOr Z_ibAt this time, the electric signal E_ibOr E_iaIs output from the output interdigital electrode.That is, the electric signal E _ib Or E _ia Only will appear as an output signal. In this wayThe information processing unit_iaOne of F_XaThe position F_XaPosition F that is paired with_XbElectrical signal E corresponding to_XbIs detected by being output from the interdigital electrode for output. Similarly, the information processing unit_XbThe position F_XaElectrical signal E corresponding to_XaIs detected by being output from the interdigital electrode for output. In this way, the ultrasonic touch panel of the present invention has the position F of the touched piezoelectric substrate._iaOr F_ibCorresponding to the electrical signal E_ibOr E_iaCan be output.
[0019]
  In the ultrasonic touch panel of the present invention, the touched position F_iaOr F_ibOutput electric signal E_ibOr E_iaEach frequency f_ibOr f_iaIt is possible to specify by. In this case, the information processing unit includes an amplifier and a signal processor. The output end of the output interdigital electrode is connected to the input end of the input interdigital electrode and the input end of the signal processor via an amplifier. The signal processor is in contact with the position F_XaThe electrical signal E_XbFrequency f_XbIt is specified by detecting. Similarly, the contact position F_XbThe electrical signal E_XaFrequency f_XaIt is specified by detecting.That is, position F _ia One of the positions F _Xa Position F _Xa X in is one of i, for example if i = 2 then F _Xa = F _2a In this case, the position F _2a Position F that is paired with _2b Output electrical signal E corresponding to _2b Frequency f _2b As a result, the position F is detected. _2a Is identified as having contacted. Similarly, position F _ib One of the positions F _Xb If i = 2, F _Xb = F _2b And position F _2b Position F that is paired with _2a Output electrical signal E corresponding to _2a Frequency f _2a As a result, the position F is detected. _2b Is identified as having contacted.
[0020]
  In the ultrasonic touch panel of the present invention, the touched position F_iaOr F_ibOutput electric signal E_ibOr E_iaEach phase θ_ibOr θ_iaAnd the reference phase θ_baseIt is possible to specify from the difference. In this case, the information processing unit comprises an amplifier, a phase comparator, and a signal processor, and each ultrasonic wave transmitting / receiving means includes two interdigital electrodes for reference, one of which is used for input and the other is used for output. It is done. The directions of the electrode fingers of the two reference interdigital electrodes are parallel to each other. The output end of the reference interdigital electrode for output is connected to the input end of each of the reference interdigital electrode and the input interdigital electrode via an amplifier, and the input end of the phase comparator. Connected to. The output end of the output interdigital electrode is connected to the input end of the signal processor via a phase comparator. When an electrical signal is input to the reference interdigital electrode for input, ultrasonic waves are excited on the piezoelectric substrate, and this ultrasonic wave is phase-shifted by the reference interdigital electrode for output._baseIt is converted into an electrical signal having IfPosition F _ib One ofPosition F_XbContact with, Electrical signal E _Xa Is output, Phase θ in the phase comparator_baseWhen, Electrical signal E _Xa Phase ofθ_XaAnd the difference (θ_base−θ_Xa) Is detected,Position F _ia One ofPosition F_XaContactAnd electrical signal E _Xb Is output, Phase θ in the phase comparator_baseWhen, Electrical signal E _Xb Phase θ _Xb And the difference (θ_base−θ _Xb ) Is detected. The signal processor is in contact with the position F_XaThe phase difference (θ_base−θ_Xb) To identify. Similarly, the contact position F_XbThe phase difference (θ_base−θ_Xa) To identify.In this way, if position F _ib One of the positions F _Xb Position F _Xb X in is one of i, for example if i = 2 then F _Xb = F _2b In this case, the position F _2b Position F that is paired with _2a Electrical signal E corresponding to _2a Is output in the phase comparator. _base And θ _2a And the difference (θ _base −θ _2a ) Is detected, and as a result, the position F _2b Is identified as having contacted. Similarly, position F _ia One of the positions F _Xa If i = 2, F _Xa = F _2a And position F _2a Position F that is paired with _2b Electrical signal E corresponding to _2b Is output in the phase comparator. _base And θ _2b And the difference (θ _base −θ _2b ) Is detected, and as a result, the position F _2a Is identified as having contacted.
[0021]
  In the ultrasonic touch panel of the present invention, a structure in which the electrode periodic length P is larger than the thickness d of the piezoelectric substrate is possible. In this case, the interdigital electrode for input can excite an elastic wave having a wavelength substantially equal to the electrode period length P to the piezoelectric substrate by inputting an electric signal having a frequency substantially corresponding to the electrode period length P. It becomes. In a device using such an elastic wave, the position F on one plate surface of the piezoelectric substrate is F._iaOr F_ibTouches the electrical signal E_ibOr E_iaOccurs.
[0022]
  In the ultrasonic touch panel of the present invention, a structure in which the electrode periodic length P has a value equal to or less than one third of the thickness d of the piezoelectric substrate is possible. In this case, the input interdigital electrode receives an electric signal having a frequency substantially corresponding to the electrode periodic length P, and therefore the electrode periodic length P and the surface of the plate surface of the piezoelectric substrate having the interdigital electrode It becomes possible to excite surface acoustic waves having substantially the same wavelength. In a device using such a surface acoustic wave, the position F on the plate surface of the piezoelectric substrate having the interdigital electrode._iaOr F_ibTouches the electrical signal E_ibOr E_iaOccurs.
[0023]
  The ultrasonic touch panel of the present invention employs a piezoelectric ceramic as a piezoelectric substrate, and adopts a structure in which the direction of the polarization axis of the piezoelectric ceramic is parallel to the direction of the thickness d, thereby facilitating design ease. Devices can be provided.
[0024]
  In the ultrasonic touch panel of the present invention, the ultrasonic wave propagation path Z in one ultrasonic wave transmitting / receiving means._iaAnd Z_ibAnd the ultrasonic wave propagation path Z in the other ultrasonic wave transmitting / receiving means_iaAnd Z_ibBy adopting a structure in which the two are orthogonal to each other, the contact position can be expressed by two-dimensional coordinates with the propagation paths orthogonal to each other as the X axis and the Y axis, respectively.
[0025]
【Example】
  FIG. 1 is a plan view showing a first embodiment of the ultrasonic touch panel of the present invention. This embodiment comprises a piezoelectric substrate 1, ultrasonic transmission / reception means X in the X-axis direction, ultrasonic transmission / reception means Y in the Y-axis direction, and an information processing unit Z. However, in FIG. 1, only the piezoelectric substrate 1 and the ultrasonic wave transmitting / receiving means X and Y are depicted. Each ultrasonic wave transmitting / receiving means includes an input interdigital electrode 2 and an output interdigital electrode 3. The interdigital electrodes 2 and 3 are made of an aluminum thin film, have ten pairs of electrode fingers, and are provided on the upper end surface of the piezoelectric substrate 1. The piezoelectric substrate 1 is made of a piezoelectric ceramic having a thickness d of 1.5 mm, and the direction of its polarization axis is parallel to the direction of the thickness d.
[0026]
  FIG. 2 is a view showing a relative structure between the interdigital electrodes 2 and 3. The interdigital electrode 2 has a regular structure, the electrode period length P is 1.7 mm, and the electrode crossing width L is 15 mm. The interdigital region of the interdigital electrode 3 is one group R₁Group R₁Is the two parts R_1aAnd R_1bAnd part R sandwiched between them_1mConsists of. Part R_1aAnd R_1bThe direction of each electrode finger is parallel to the direction of the electrode finger of the interdigital electrode 2, and the portion R_1aAnd R_1bEach electrode cycle length is equal to the electrode cycle length P of the interdigital electrode 2.
[0027]
  FIG. 3 shows part R_1mFIG. Part R_1mOf the interdigital transducer 2 has an angle α with respect to the interdigital transducer 2 and the portion R_1mPeriod length P of electrode fingers in a direction orthogonal to the electrode fingers of_RNIs equal to the product of the electrode period length P and cos α. Part R_1mThe electrode crossing width of the_1mCrossing width L in the direction of the electrode finger_RPAnd the intersection width L in the direction parallel to the electrode fingers of the interdigital electrode 2_RNThere are two types. Intersection width L_RPIs the intersection width L_RNIs equal to the product of secα and the product of half of the electrode period length P and cosecα. Part R_1aAnd R_1bEach electrode cross width (7mm) and part R_1mIntersection width L_RNThe sum of (1 mm) is equal to the electrode crossing width L (15 mm) of the interdigital electrode 2.
  2 and 3, the part R _1m And R _1a Near the boundary with the part R _1m And R _1b It can be seen that there is a difference corresponding to half of the electrode period length P at the distance from the interdigital electrode 2 in the vicinity of the boundary between and the interdigital electrode 2. This means that the interdigital electrode 2 and the part R _1a , The interdigital electrode 2 and the part R _1b This means that there is a difference corresponding to half of the electrode period length P.
[0028]
  FIG. 4 is a circuit configuration diagram of the ultrasonic touch panel of FIG. The circuit shown in FIG. 4 includes an information processing unit Z. The information processing unit Z includes an amplifier 4 and a signal processor 5. The output terminal of the interdigital electrode 3 is connected to the input terminal of the interdigital electrode 2 and the input terminal of the signal processor 5 via the amplifier 4. When an electric signal having a frequency substantially corresponding to the electrode period length P is input to the interdigital electrode 2, an elastic wave having a wavelength substantially equal to the electrode period length P is excited on the piezoelectric substrate 1. This elastic wave, The interdigital electrode 3 is reached, but the part R _1m If we focus on the electrode part _1m Is inclined with respect to the interdigital electrode 2 for input, so that the elastic wave propagating from the interdigital electrode 2 cannot be received. _1m The output of the electric signal in itself becomes zero. On the other hand, a portion R parallel to the interdigital electrode 2 for input _1a And R _1b If we focus on the part R _1a And R _1b However, since there is a difference corresponding to half of the electrode period length P at the distance from the interdigital electrode 2, as described in ## EQU1 ## _1a And the propagation distance from the interdigital electrode 2 to the portion R _1b The delay propagation distance to reach the wavelength of the propagating elastic wave 2 This results in a shift of one minute cycle. As a result, part R _1a And R _1b The elastic wave that reachedPart R_1aAnd R_1bBy frequency f_1aAnd f_1bElectrical signal E with_1aAnd E_1bRespectively converted toWhenElectrical signal E_1aAnd E_1bThe amplitude of the electrical signal generated by combiningPart R _1m As a result of electrical coupling at the electrode partIt becomes zero.Therefore, part R _1a And R _1b The output of the sum of electrical signals becomes zero. As a result, no electrical signal is output from the entire interdigital electrode 3.
In this way, part R _1m But part R _1a And R _1b And satisfying the conditions specified in FIG. 3 and FIG. 3 result in the output electric signal at the interdigital electrode 3 being zero.
  The interdigital electrodes 2 and 3 are formed on the piezoelectric substrate 1 with a portion R_1aAnd R_1bUltrasonic wave propagation path Z corresponding to each_1aAnd Z_1bForm. If the top or bottom surface of the piezoelectric substrate 1 isUltrasonic wave propagation path Z _1b Corresponding toPosition F_1bThe finger or object touches the ultrasonic wave propagation path Z_1bIs interrupted, the ultrasonic propagation path Z_1aElectrical signal E corresponding to_1aIs output from the interdigital electrode 3. Similarly,Ultrasonic wave propagation path Z _1a Corresponding toPosition F_1aContact with the ultrasonic wave propagation path Z_1aIs interrupted, the electric signal E_1bIs output.In other words, position F _1b Touches position F _1b Position F that is paired with _1a Electrical signal E corresponding to _1a Is output from the interdigital electrode 3 and the position F _1a Touches position F _1a Position F that is paired with _1b Electrical signal E corresponding to _1b Is output from the interdigital electrode 3. That is, when there is no contact, part R _1m The output electric signal of the interdigital electrode 3 as a whole is zero, but when it comes into contact, the electric signal E _1a Or E _1b Is output from the interdigital electrode 3.That is, when the upper end surface or the lower end surface of the piezoelectric substrate 1 is not contacted, an electrical signal is not output from the interdigital electrode 3, but the position F_1bThe frequency f_1aElectrical signal E with_1aIs position F_1aThe frequency f_1bElectrical signal E with_1bIs detected by the signal processor 5. In this way, from the frequency of the electrical signal detected by the signal processor 5, the position F_1aAnd F_1bYou can see which of the contacts. In addition, the contact position related to the ultrasonic transmission / reception means X and the contact position related to the ultrasonic transmission / reception means Y are detected simultaneously. In this embodiment, two ultrasonic transmission / reception means X and Y are used, and an ultrasonic propagation path Z in the ultrasonic transmission / reception means X is used._1aAnd Z_1bAnd the ultrasonic wave propagation path Z in the ultrasonic wave transmitting / receiving means Y_1aAnd Z_1bSince they are orthogonal to each other, the contact position can be expressed by two-dimensional coordinates with the orthogonal propagation paths as the X axis and the Y axis, respectively. Electrical signal E output from the interdigital electrode 3_1aOr E_1bIs amplified by the amplifier 4, and a part of the amplified electric signal is input to the interdigital electrode 2 again. In this way, the ultrasonic wave propagation path Z only at the time of contact_1aOr Z_1bAs a delay element is configured, not only driving with low power consumption is possible, but also the circuit configuration is simplified.
[0029]
  FIG. 5 shows an electromechanical coupling coefficient k calculated from the phase velocity difference between two different electrical boundary conditions of the piezoelectric substrate 1.²5 is a characteristic diagram showing the relationship between the product (fd) of the frequency f of the elastic wave and the thickness d of the piezoelectric substrate 1. However, the transverse wave velocity of the elastic wave propagating through the piezoelectric substrate 1 is 2450 m / s, and the longitudinal wave velocity is 4390 m / s. For example, the electrical energy applied to the interdigital electrode 2 is S₀The fd value when converted to a mode elastic wave is about 1.3 MHz · mm, k²Indicates about 12.4% of the maximum value. K here²The value is LiNbO in the practical range as a piezoelectric substrate for surface acoustic waves.₃It is clear that the single crystal is worthy of evaluation even when compared with the value of about 5%.
[0030]
  FIG. 6 is a characteristic diagram showing a velocity dispersion curve of an elastic wave propagating through the piezoelectric substrate 1, and is a diagram showing the phase velocity of each mode with respect to the fd value. The symbol ● indicates an fd value (a value calculated from FIG. 5, in which electric energy applied to the interdigital electrode 2 is most efficiently converted into an elastic wave in each mode.²Fd value indicating the maximum value). It can be seen that all the phase velocities at the mark ● show values in the vicinity of 3500 m / s.
[0031]
  FIG. 7 is a plan view showing a second embodiment of the ultrasonic touch panel of the present invention. This embodiment comprises a piezoelectric substrate 1, ultrasonic transmission / reception means X in the X-axis direction, ultrasonic transmission / reception means Y in the Y-axis direction, and an information processing unit Z. However, in FIG. 7, only the piezoelectric substrate 1 and the ultrasonic wave transmitting / receiving means X and Y are drawn. Each ultrasonic wave transmission / reception means includes four interdigital electrodes 2 and four interdigital electrodes 3 corresponding thereto.
[0032]
  FIG. 8 is a circuit configuration diagram of the ultrasonic touch panel of FIG. 8 includes a switch 6 and an information processing unit Z. The information processing unit Z includes an amplifier 4 and a signal processor 5. The output terminals of the interdigital electrodes 3 are connected to each other at one connection point, and the connection point is connected to the input terminal of the switch 6 and the input terminal of the signal processor 5 via the amplifier 4. The switch 6 has a function of inputting electrical signals to the four interdigital electrodes 2 in order. When an electric signal is input from the interdigital electrode 2 through the switch 6, an elastic wave is excited in the piezoelectric substrate 1. This elastic wave is part R_1aAnd R_1bBy the frequency f_1aAnd f_1bElectrical signal E with_1aAnd E_{1 b}Respectively. If the upper end surface or the lower end surface of the piezoelectric substrate 1 is located at a position F between one interdigital electrode 2 and the corresponding interdigital electrode 3 in the ultrasonic wave transmitting / receiving means X._1bSignal E_1aIs position F_1aSignal E_1bIs detected by the signal processor 5. In this way, the contact position is clarified by discriminating the frequency of the electric signal detected by the signal processor 5 and only one interdigital electrode 2 connected when the electric signal is detected. The same applies to the ultrasonic wave transmitting / receiving means Y. The contact position related to the ultrasonic transmission / reception means X and the contact position related to the ultrasonic transmission / reception means Y are detected simultaneously. Electrical signal E output from the interdigital electrode 3_1aOr E_1bIs amplified by the amplifier 4, and a part of the amplified electric signal is input again to the interdigital electrode 2 via the switch 6. In this way, the ultrasonic wave propagation path Z only at the time of contact_1aOr Z_1bAs a delay element is configured, not only driving with low power consumption is possible, but also the circuit configuration is simplified.
[0033]
  FIG. 9 is a plan view showing a third embodiment of the ultrasonic touch panel of the present invention. This embodiment comprises a piezoelectric substrate 1, ultrasonic transmission / reception means X in the X-axis direction, ultrasonic transmission / reception means Y in the Y-axis direction, and an information processing unit Z. However, in FIG. 9, only the piezoelectric substrate 1 and the ultrasonic wave transmitting / receiving means X and Y are depicted. Each ultrasonic wave transmitting / receiving means is composed of interdigital reference electrodes 7 and 8, four interdigital electrodes 2, and four interdigital electrodes 3 corresponding thereto. The interdigital electrodes 7 and 8 have a regular structure, and the electrode period length P is 1.7 mm.
[0034]
  FIG. 10 is a circuit configuration diagram of the ultrasonic touch panel of FIG. The circuit of FIG. 10 includes an amplifier 4, a switch 6, and an information processing unit Z. The information processing unit Z includes an amplifier 9, a phase comparator 10, and a signal processor 5. The output terminals of the interdigital electrodes 3 are connected to each other at one connection point, and the connection point is connected to the input terminal of the phase comparator 10 via the amplifier 4. The output terminal of the interdigital electrode 8 is connected to the input terminal of the interdigital electrode 7 and the input terminal of the switch 6 through the amplifier 9 and to the input terminal of the phase comparator 10. The switch 6 has a function of inputting electrical signals to the four interdigital electrodes 2 in order. When an electric signal is input from the interdigital electrode 7, an elastic wave is excited in the piezoelectric substrate 1. This elastic wave is phased θ by the interdigital electrode 8._baseIs converted into an electric signal having the following output and amplified by the amplifier 9. Part of the amplified electrical signal (Mal 1) is input to the interdigital electrode 7 and the switch 6. In this way, it is possible to configure an oscillator that uses the ultrasonic wave propagation path between the interdigital electrodes 7 and 8 as a delay element. The remainder (Mull 2) of the amplified electrical signal is input to the phase comparator 10. When an electric signal is input from the interdigital electrode 2 through the switch 6, an elastic wave is excited in the piezoelectric substrate 1. This elastic wave is part R_1aAnd R_1bBy phase θ_1aAnd θ_1bOn the upper end surface or the lower end surface, a position F between one interdigital electrode 2 in the ultrasonic wave transmitting / receiving means X and the interdigital electrode 3 corresponding thereto._1bSignal E_1aIs position F_1aSignal E_1bIs output from the interdigital electrode 3. At this time, in the phase comparator 10, the phase θ_baseAnd phase θ_1aOr θ_1bAnd the difference is detected. The signal processor 5 discriminates this phase difference and only one interdigital electrode 2 connected when this phase difference is detected._1aAnd E_1bRespectively. If the contact position of the piezoelectric substrate 1 is specified. The same applies to the ultrasonic wave transmitting / receiving means Y. The contact position related to the ultrasonic transmission / reception means X and the contact position related to the ultrasonic transmission / reception means Y are detected simultaneously.
[0035]
  FIG. 11 is a plan view showing a fourth embodiment of the ultrasonic touch panel of the present invention. This embodiment has a structure in which the output interdigital electrode 3 in FIG. 1 is replaced with the output interdigital electrode 11.
[0036]
  FIG. 12 is a view showing a relative structure between the interdigital electrodes 2 and 11. The interdigital electrode 11 has 10 pairs of electrode fingers, and the intersecting region of the electrode fingers is divided into two groups R.₁And R₂And one part Q₁Consisting of part Q₁Is Group R₁And R₂Between. Group R₁Is the two parts R_1aAnd R_1bAnd part R sandwiched between them_1mGroup R₂Is the two parts R_2aAnd R_2bAnd part R sandwiched between them_2mConsists of. Part R_1a, R_1b, R_2aAnd R_2bThe direction of each electrode finger is parallel to the direction of the electrode finger of the interdigital electrode 2, and the portion R_1a, R_1b, R_2aAnd R_2bEach electrode cycle length is equal to the electrode cycle length P of the interdigital electrode 2. Part R_1mAnd R_2mThe structure is similar to the structure shown in FIG.
[0037]
  FIG. 13 shows part Q₁FIG. Part Q₁This electrode finger has an angle of -β with respect to the electrode finger of the interdigital electrode 2. In the present embodiment, the inclination is −β as described above, but a case of having an inclination of + β is also possible. Part Q₁Period length P of electrode fingers in a direction orthogonal to the electrode fingers of_QNIs equal to the product of the electrode period length P and cos β. Part Q₁The electrode crossing width of₁Crossing width L in the direction of the electrode finger_QPAnd the intersection width L in the direction parallel to the electrode fingers of the interdigital electrode 2_QNThere are two types. Intersection width L_QPIs the intersection width L_QNIs equal to the product of cosecβ and the value obtained by dividing the electrode period length P by 4 (P / 4). Part R_1a, R_1b, R_2aAnd R_2bEach electrode cross width (3mm) and part R_1mAnd R_2mEach intersection width L_RN(1mm) and part Q₁Intersection width L_QNThe sum of (1 mm) is equal to the electrode crossing width L (15 mm) of the interdigital electrode 2.
[0038]
  When driving the ultrasonic touch panel of the fourth embodiment of FIG. 11, the circuit configuration of FIG. 4 is used. However, the interdigital electrode 3 in FIG. 4 is replaced with the interdigital electrode 11. The elastic wave excited on the piezoelectric substrate 1 by inputting an electric signal from the interdigital electrode 2 isIt will reach the interdigital electrode 11, but the part Q ₁ When focusing on the electrode part, the part Q ₁ Is inclined with respect to the interdigital electrode 2 for input, so that the elastic wave propagating from the interdigital electrode 2 cannot be received. ₁ The output of the electrical signal in itself is the part R described in [0028]. _1m As in the case of, it becomes zero. Meanwhile, Group R ₁ And R ₂ Group R ₁ Part R constituting _1a And R _1b And group R ₂ Part R constituting _2a And R _2b Is the part R described in [0028] _1a And R _1b Group R ₁ Itself and group R ₂ The output of the electric signal in itself is both zero. In this way, elastic wavesPart R_1a, R_1b, R_2aAnd R_2bBy the frequency f_1a, F_1b, F_2aAnd f_2bElectrical signal E with_1a, E_1b, E_2aAnd E_2bRespectively converted toWhenElectrical signal E_1aAnd E_1bThe amplitude of the electric signal produced by synthesizing the electric signal and the electric signal E_2aAnd E_2bBoth of the amplitudes of the electric signals generated by synthesizing are zero.This means that the output electric signal of the interdigital electrode 11 as a whole becomes zero.
  In this way, part R _1m Is part R _1a And R _1b Between the parts R _2m Is part R _2a And R _2b And the part R _1m And R _2m Has the conditions specified in [0027] and the part Q ₁ Is Group R ₁ And R ₂ And part Q ₁ Satisfying the condition specified by ## EQU3 ## results in zero output electric signal at the interdigital electrode 11.
  The interdigital electrodes 2 and 11 are formed on the piezoelectric substrate 1 with a portion R_1a, R_1b, R_2aAnd R_2bUltrasonic wave propagation path Z corresponding to each_1a, Z_1b, Z_2aAnd Z_2bForm. If the top or bottom surface of the piezoelectric substrate 1 isUltrasonic wave propagation path Z _1b , Z _1a , Z _2b And Z _2a Corresponding toPosition F_1b, F_1a, F_2bOr F_2aThe frequency f_1a, F_1b, F_2aOr f_2bElectrical signal E with_1a, E_1b, E_2aOr E_2bIs detected by the signal processor 5.For example, position F _1a Touches position F _1a Position F that is paired with _1b Electrical signal E corresponding to _1b Is output from the interdigital electrode 11 and detected by the signal processor 5. That is, when there is no contact, part R _1m , R _2m And Q ₁ The output electric signal of the interdigital electrode 11 as a whole is zero, but when it comes into contact, the electric signal E _1a , E _1b , E _2a Or E _2b Is detected by the signal processor 5.In this way, from the frequency of the electrical signal detected by the signal processor 5, the position F_1a, F_1b, F_2aAnd F_2bYou can see which of them touched. In addition, the contact position related to the ultrasonic transmission / reception means X and the contact position related to the ultrasonic transmission / reception means Y are detected simultaneously.
[0039]
  In the ultrasonic touch panel of the fourth embodiment, each ultrasonic wave transmitting / receiving means has a structure including four interdigital electrodes 2 and four interdigital electrodes 11 corresponding thereto, that is, interdigital electrodes 3 in FIG. A structure in which the electrode 11 is replaced is possible. When driving the ultrasonic touch panel having such a structure, the circuit configuration of FIG. 8 is used. However, the interdigital electrode 3 in FIG. 8 is replaced with the interdigital electrode 11. The elastic wave excited by the piezoelectric substrate 1 by inputting an electric signal from the interdigital electrode 2 through the switch 6 is a part R_1a, R_1b, R_2aAnd R_2bBy the frequency f_1a, F_1b, F_2aAnd f_2bElectrical signal E with_1a, E_1b, E_2aAnd E_2bRespectively. If the upper end surface or the lower end surface of the piezoelectric substrate 1 is located at a position F between one interdigital electrode 2 and the corresponding interdigital electrode 3 in the ultrasonic wave transmitting / receiving means X._1b, F_1a, F_2bOr F_2aTouches the electrical signal E_1a, E_1b, E_2aOr E_2bIs detected by the signal processor 5. In this way, the contact position is clarified by discriminating the frequency of the electric signal detected by the signal processor 5 and only one interdigital electrode 2 connected when the electric signal is detected. The same applies to the ultrasonic wave transmitting / receiving means Y.
[0040]
  Further, in the ultrasonic touch panel of the fourth embodiment, each ultrasonic wave transmitting / receiving means is composed of reference interdigital electrodes 7 and 8, four interdigital electrodes 2, and four interdigital electrodes 11 corresponding thereto. That is, a structure in which the interdigital electrode 3 in FIG. 9 is replaced with the interdigital electrode 11 is possible. When driving the ultrasonic touch panel having such a structure, the circuit configuration of FIG. 10 is used. However, the interdigital electrode 3 in FIG. 10 is replaced with the interdigital electrode 11. The elastic wave excited on the piezoelectric substrate 1 by inputting an electric signal from the interdigital electrode 2 via the switch 6 is a part R_1a, R_1b, R_2aAnd R_2bBy phase θ_1a, Θ_1b, Θ_2aOr θ_2bElectrical signal E with_1a, E_1b, E_2aOr E_2bRespectively. If the upper end surface or the lower end surface of the piezoelectric substrate 1 is located at a position F between one interdigital electrode 2 and the corresponding interdigital electrode 3 in the ultrasonic wave transmitting / receiving means X._1b, F_1a, F_2bOr F_2aTouches the electrical signal E_1a, E_1b, E_2aOr E_2bIs output from the interdigital electrode 3. At this time, the phase comparator 10 outputs the phase θ of the electric signal output from the interdigital electrode 8._baseAnd phase θ_1a, Θ_1b, Θ_2aOr θ_2bAnd the difference is detected. The signal processor 5 identifies the contact position by discriminating this phase difference and only one interdigital electrode 2 connected when this phase difference is detected. The same applies to the ultrasonic wave transmitting / receiving means Y.
[0041]
  FIG. 14 is a plan view showing a fifth embodiment of the ultrasonic touch panel of the present invention. This embodiment has a structure in which the input interdigital electrode 2 and the output interdigital electrode 3 in FIG. 1 are replaced with the input interdigital electrode 12 and the output interdigital electrode 13.
[0042]
  FIG. 15 is a view showing a relative structure between the interdigital electrodes 12 and 13.
Interdigital electrodes 12 and 13 have 10 pairs of electrode fingers. The crossing region of the electrode fingers of the interdigital electrode 12 has two parts A₁And A₂And one part B₁Consisting of part B₁Is part A₁And A₂Between. Further, the crossing region of the electrode fingers of the interdigital electrode 13 has three portions C₁, C₂And C₃And two parts D₁And D₂Consisting of part D₁Is part C₁And C₂Part D₂Is part C₂And C₃Between. Part A₁And A₂The direction of each electrode finger is part C₁, C₂And C₃It is parallel to the direction of each electrode finger. Part A₁, A₂, C₁, C₂And C₃Each electrode period length P is 1.7 mm.
[0043]
  FIG. 16 shows part B₁FIG. Part B₁The electrode finger is part A₁And A₂With an angle of -β with respect to the electrode fingers, and part B₁Period length P of electrode fingers in a direction orthogonal to the electrode fingers of_BNIs equal to the product of the electrode period length P and cos β. Part B₁The electrode crossing width of₁Crossing width L in the direction of the electrode finger_BPAnd part A₁And A₂Width L in the direction parallel to the electrode fingers_BNThere are two types. Intersection width L_BPIs the intersection width L_BNIs equal to the product of secβ. Furthermore, the intersection width L_BPIs equal to the product of the value obtained by dividing the electrode period length P by 4 (P / 4) and cosecβ.
[0044]
  FIG. 17 shows part D₁FIG. Part D₂Also part D₁It has the same structure as Part D₁The electrode finger is part C₁, C₂And C₃With an angle α to the electrode fingers of₁Period length P of electrode fingers in a direction orthogonal to the electrode fingers of_DNIs equal to the product of the electrode period length P and cos α. Part D₁The electrode crossing width of₁Crossing width L in the direction of the electrode finger_DPAnd part C₁, C₂And C₃Width L in the direction parallel to the electrode fingers_DNThere are two types. Intersection width L_DPIs the intersection width L_DNIs equal to the product of secα and the product of half of the electrode period length P and cosecα. Part D₂The same applies to. Part A₁And A₂Each electrode cross width (7mm) and part B₁Intersection width L_BN(1mm) total (15mm) is part C₁And C₃Each electrode cross width (3mm) and part C₂Electrode crossing width (7mm) and part D₁And D₂Each intersection width L_DNIt is equal to the sum (15 mm) of (1 mm).
[0045]
  When the ultrasonic touch panel of the fifth embodiment shown in FIG. 14 is driven, the circuit configuration shown in FIG. 4 is used. However, the interdigital electrodes 2 and 3 in FIG. 4 are replaced with interdigital electrodes 12 and 13.In the case of FIG. 14, as apparent from FIG. ₁ To C ₁ And the delay propagation distance up to ₁ To C ₂ The delay propagation distance up to ₁ Is different because there is a part A ₁ To C ₂ And the delay propagation distance up to ₂ To C ₂ The delay propagation distance to ₁ Is different because there is a part A ₂ To C ₂ And the delay propagation distance up to ₂ To C ₃ The delay propagation distance up to ₂ It can be seen that it is different because of That is, there are four types of delayed propagation distances between the interdigital electrodes 12 and 13, and the elastic wave from the interdigital electrode 12 is received by the interdigital electrodes 13 corresponding to the respective distances. In this wayThe elastic wave excited on the piezoelectric substrate 1 by inputting an electric signal from the interdigital electrode 12 is converted into two electric signals E by the interdigital electrode 13._1aAnd E_2aAnd two electrical signals E_1bAnd E_2bConverted toIn that case, part B ₁ , D ₁ And D ₂ As a result of the presence ofElectrical signal E_1aAnd E_1bThe amplitude of the electric signal generated by synthesizing the signal becomes zero, and the electric signal E_2aAnd E_2bThe amplitude of the electric signal generated by synthesizing is zero.
In this way, part B ₁ But part A ₁ And A ₂ With the condition specified in ## EQU1 ## and part D ₁ Is part C ₁ And C ₂ In between, part D ₂ Is part C ₂ And C ₃ Between the two and the part D ₁ And D ₂ Satisfying the condition specified by ## EQU1 ## results in the output electric signal at the interdigital electrode 13 being zero.
  The interdigital electrodes 12 and 13 are formed on the piezoelectric substrate 1 as follows:Ultrasonic wave propagation path Z _1a , Z _1b , Z _2a And Z _2b Form.These four ultrasonic propagation paths correspond to the above four delay propagation distances., Ultrasonic wave propagation path Z_1aIs part A₁And C₁Between the ultrasonic propagation path Z_1bIs part A₁And C₂Between the ultrasonic propagation path Z_2aIs part A₂And C₂Between the ultrasonic propagation path Z_2bIs part A₂And C₃Between each. If the top or bottom surface of the piezoelectric substrate 1Ultrasonic wave propagation path Z _1b , Z _1a , Z _2b Or Z _2a Corresponding toPosition F_1b, F_1a, F_2bOr F_2aThe frequency f_1a, F_1b, F_2aOr f_2bElectrical signal E with_1a, E_1b, E_2aOr E_2bIs detected by the signal processor 5. At this time, position F_1b, F_1a, F_2bOr F_2aPart D with or without touching₁And D₂The electrical signal that is converted in is not output. In this way, from the frequency of the electrical signal detected by the signal processor 5, the position F_1a, F_1b, F_2aAnd F_2bYou can see which of them touched. In addition, the contact position related to the ultrasonic transmission / reception means X and the contact position related to the ultrasonic transmission / reception means Y are detected simultaneously.
[0046]
  In the ultrasonic touch panel of the fifth embodiment, each ultrasonic wave transmitting / receiving means has a structure comprising four interdigital electrodes 12 and four interdigital electrodes 13 corresponding thereto, that is, interdigital electrodes 2 and 3 in FIG. A structure in which the interdigital electrodes 12 and 13 are replaced is possible. When driving the ultrasonic touch panel having such a structure, the circuit configuration of FIG. 8 is used. However, the interdigital electrodes 2 and 3 in FIG. 8 are replaced with interdigital electrodes 12 and 13. The elastic wave excited by the piezoelectric substrate 1 by inputting an electric signal from the interdigital electrode 12 via the switch 6 is converted into two electric signals E by the interdigital electrode 13._1aAnd E_2aAnd two electrical signals E_1bAnd E_2bIs converted to If the upper end surface or the lower end surface of the piezoelectric substrate 1 is located at a position F between one interdigital electrode 12 and the corresponding interdigital electrode 13 in the ultrasonic wave transmitting / receiving means X._1b, F_1a, F_2bOr F_2aTouches the electrical signal E_1a, E_1b, E_2aOr E_2bIs detected by the signal processor 5. In this way, the contact position is clarified by discriminating the frequency of the electric signal detected by the signal processor 5 and only one interdigital electrode 12 connected when the electric signal is detected. The same applies to the ultrasonic wave transmitting / receiving means Y.
[0047]
  Further, in the ultrasonic touch panel of the fifth embodiment, each ultrasonic wave transmitting / receiving means is composed of reference interdigital electrodes 7 and 8, four interdigital electrodes 12, and four interdigital electrodes 13 corresponding thereto. That is, a structure in which the interdigital electrodes 2 and 3 in FIG. 9 are replaced with interdigital electrodes 12 and 13 is possible. When driving the ultrasonic touch panel having such a structure, the circuit configuration of FIG. 10 is used. However, the interdigital electrodes 2 and 3 in FIG. 10 are replaced with interdigital electrodes 12 and 13. The elastic wave excited on the piezoelectric substrate 1 by inputting an electric signal from the interdigital electrode 12 via the switch 6 is phase-shifted by the interdigital electrode 13._1aElectrical signal E with_1aAnd phase θ_2aElectrical signal E with_2aAnd phase θ_1bElectrical signal E with_1bAnd phase θ_2bElectrical signal E with_2bIs converted to If the upper end surface or the lower end surface of the piezoelectric substrate 1 is located at a position F between one interdigital electrode 12 and the corresponding interdigital electrode 13 in the ultrasonic wave transmitting / receiving means X._1b, F_1a, F_2bOr F_2aTouches the electrical signal E_1a, E_1b, E_2aOr E_2bIs output from the interdigital electrode 13. At this time, the phase comparator 10 outputs the phase θ of the electric signal output from the interdigital electrode 8._baseAnd phase θ_1a, Θ_1b, Θ_2aOr θ_2bAnd the difference is detected. The signal processor 5 identifies the contact position by discriminating this phase difference and only one interdigital electrode 12 connected when this phase difference is detected. The same applies to the ultrasonic wave transmitting / receiving means Y.
[0048]
  In the ultrasonic touch panels of the first to fifth embodiments, the interdigital electrodes 2, 7 and 12 on the input side have an electrode cycle length P of 400 μm, and the interdigital electrodes 3, 8, 11 and 13 on the output side correspond to them. A structure having an electrode periodic length is possible. In this case, when an electric signal having a frequency substantially corresponding to the electrode cycle length P is input from the interdigital electrode on the input side, a surface acoustic wave having a wavelength substantially equal to the electrode cycle length P is generated in the vicinity of the upper end surface of the piezoelectric substrate 1. Excited. In the ultrasonic touch panel using such surface acoustic waves, the position is specified by contacting the upper end surface of the piezoelectric substrate 1.
[0049]
【The invention's effect】
  The ultrasonic touch panel of the present invention includes a piezoelectric substrate, two ultrasonic wave transmitting / receiving means provided on one plate surface of the piezoelectric substrate, and an information processing unit connected to the two ultrasonic wave transmitting / receiving means. Each ultrasonic wave transmitting / receiving means comprises at least one set of input interdigital electrodes and an output interdigital electrode corresponding to the input interdigital electrodes.
[0050]
  In the first structure of the ultrasonic touch panel of the present invention, the input interdigital electrode has a regular structure. The intersection region of the electrode fingers of the output interdigital electrode is one group R_i(I = 1) only or N groups R_i(I = 1, 2,..., N) and two groups R_iAnd R_{(I + 1)}(N-1) pieces Q sandwiched between_i{I = 1, 2,... (N−1)}. Each group R_iIs the two parts R_iaAnd R_ibAnd part R sandwiched between them_imConsists of. If an electric signal is input to the interdigital transducer for input, ultrasonic waves are excited on the piezoelectric substrate. This ultrasonic wave is part R_iaAnd R_ibBy the electrical signal E_iaAnd E_ib(I = 1, 2,..., N) respectively. At this time, the electric signal E_iaAnd E_ibThe amplitude of the electric signal generated by synthesizing is zero. The interdigital electrodes for input and output are formed on the piezoelectric substrate with a portion R_iaAnd R_ibUltrasonic wave propagation path Z corresponding to each_iaAnd Z_ib(I = 1, 2,..., N). If the position F on the piezoelectric substrate_iaOr F_ibWhen contacting (i = 1, 2,..., N), the ultrasonic wave propagation path Z_iaOr Z_ibIs cut off and the electric signal E_ibOr E_iaIs output from the output interdigital electrode. The information processing unit_XaThe position F_XaPosition F that is paired with_XbElectrical signal E corresponding to_XbIs detected from the output interdigital electrode. Similarly, position F_XbThe position F_XaElectrical signal E corresponding to_XaIs detected from the output interdigital electrode. Thus, the ultrasonic touch panel of the present invention has the position F._iaOr F_ibElectrical signal E only when touching_ibOr E_iaCan be output.
[0051]
  In the second structure of the ultrasonic touch panel of the present invention, the intersection region of the electrode fingers of the interdigital electrodes for input has N portions A._i(I = 1, 2,..., N) and two parts A_iAnd A_{(I + 1)}(N-1) parts B sandwiched between_i{I = 1, 2,..., (N−1)}, and the intersection region of the electrode fingers of the output interdigital electrode is (N + 1) portions C_i{I = 1, 2,... (N + 1)} and two parts C_iAnd C_{(I + 1)}N parts D sandwiched between_i(I = 1, 2,..., N). If an electric signal is input to the interdigital transducer for input, ultrasonic waves are excited on the piezoelectric substrate. This ultrasonic wave is generated by N electric signals E by an output interdigital electrode._ia(I = 1, 2,..., N) and N electrical signals E_ib(I = 1, 2,..., N). Electrical signal E_iaAnd E_ibThe amplitude of the electric signal generated by synthesizing is zero. The interdigital electrodes for input and output are composed of N ultrasonic propagation paths Z on the piezoelectric substrate._ia(I = 1, 2,..., N) and N ultrasonic propagation paths Z_ib(I = 1, 2,..., N). Ultrasonic wave propagation path Z_iaIs part A_iAnd C_iBetween the ultrasonic propagation path Z_ibIs part A_iAnd C_{(I + 1)}Between. If the position F on the piezoelectric substrate_iaOr F_ibWhen contacting (i = 1, 2,..., N), the ultrasonic wave propagation path Z_iaOr Z_ibIs cut off and the electric signal E_ibOr E_iaIs output from the output interdigital electrode. The information processing unit_XaThe position F_XaPosition F that is paired with_XbElectrical signal E corresponding to_XbIs detected from the output interdigital electrode. Similarly, position F_XbThe position F_XaElectrical signal E corresponding to_XaIs detected from the output interdigital electrode. Thus, the ultrasonic touch panel of the present invention has the position F._iaOr F_ibElectrical signal E only when touching_ibOr E_iaCan be output.
[0052]
  In the ultrasonic touch panel of the present invention, the touched position F_iaOr F_ibOutput electric signal E_ibOr E_iaEach frequency f_ibOr f_iaIt is possible to specify by. In this case, the information processing unit includes a signal processor, and the signal processor_XaThe electrical signal E_XbFrequency f_XbBy detecting the contact position F_XbThe electrical signal E_XaFrequency f_XaIt is specified by detecting.
[0053]
  In the ultrasonic touch panel of the present invention, the touched position F_iaOr F_ibOutput electric signal E_ibOr E_iaEach phase θ_ibOr θ_iaAnd the reference phase θ_baseIt is possible to specify from the difference. In this case, the information processing unit includes a phase comparator and a signal processor, and each ultrasonic wave transmitting / receiving unit includes two reference interdigital electrodes. When an electric signal is input to one of the reference interdigital electrodes, an ultrasonic wave is excited on the piezoelectric substrate, and this ultrasonic wave is phase-thetased by the other interdigital electrode._baseIt is converted into an electrical signal having The phase comparator produces a phase difference (θ_base−θ_ia) Or phase difference (θ_base−θ_ib) Is detected. The signal processor is in contact position F_XaThe phase difference (θ_base−θ_Xb) Based on the contact position F_XbThe phase difference (θ_base−θ_Xa) To identify.
[0054]
  In the ultrasonic touch panel of the present invention, a structure in which the electrode periodic length P is larger than the thickness d of the piezoelectric substrate is possible. In this case, elastic waves are excited in the piezoelectric substrate. In a device using such an elastic wave, the position F on one plate surface of the piezoelectric substrate is F._iaOr F_ibTouches the electrical signal E_ibOr E_iaOccurs.
[0055]
  In the ultrasonic touch panel of the present invention, a structure in which the electrode periodic length P has a value equal to or less than one third of the thickness d of the piezoelectric substrate is possible. In this case, a surface acoustic wave is excited in the vicinity of the surface of the plate surface of the piezoelectric substrate having the interdigital electrode. In a device using such a surface acoustic wave, the position F on the plate surface of the piezoelectric substrate having the interdigital electrode._iaOr F_ibTouches the electrical signal E_ibOr E_iaOccurs.
[0056]
  The ultrasonic touch panel of the present invention employs a piezoelectric ceramic as a piezoelectric substrate, and adopts a structure in which the direction of the polarization axis of the piezoelectric ceramic is parallel to the direction of the thickness d, thereby facilitating design ease. Devices can be provided.
[0057]
  In the ultrasonic touch panel of the present invention, an ultrasonic wave propagation path in one ultrasonic wave transmission / reception means and an ultrasonic wave propagation path in the other ultrasonic wave transmission / reception means are orthogonal to each other, so that their propagation paths are orthogonal to each other. The contact position can be expressed by two-dimensional coordinates with X and Y axes respectively.
[Brief description of the drawings]
FIG. 1 is a plan view showing a first embodiment of an ultrasonic touch panel according to the present invention.
FIG. 2 is a view showing a relative structure between the interdigital electrodes 2 and 3;
FIG. 3 Part R_1mFIG.
4 is a circuit configuration diagram of the ultrasonic touch panel of FIG. 1;
FIG. 5 shows k calculated from a phase velocity difference under two different electrical boundary conditions of the piezoelectric substrate 1²The characteristic view which shows the relationship between a value and fd value.
6 is a characteristic diagram showing a velocity dispersion curve of elastic waves propagating through the piezoelectric substrate 1. FIG.
FIG. 7 is a plan view showing a second embodiment of the ultrasonic touch panel of the present invention.
8 is a circuit configuration diagram of the ultrasonic touch panel of FIG. 7;
FIG. 9 is a plan view showing a third embodiment of the ultrasonic touch panel of the present invention.
10 is a circuit configuration diagram of the ultrasonic touch panel of FIG. 9;
FIG. 11 is a plan view showing a fourth embodiment of the ultrasonic touch panel of the present invention.
12 is a view showing a relative structure between the interdigital electrodes 2 and 11. FIG.
FIG. 13 Part Q₁FIG.
FIG. 14 is a plan view showing a fifth embodiment of the ultrasonic touch panel of the present invention.
FIG. 15 is a view showing a relative structure between the interdigital electrodes 12 and 13;
FIG. 16 Part B₁FIG.
FIG. 17 Part D₁FIG.
[Explanation of symbols]
1 Piezoelectric substrate
2,12 Interdigital electrode for input
3,11,13 Output interdigital electrode
4,9 amplifier
5 signal processor
6 switch
7,8 Interdigital electrode for reference
10 Phase comparator

Claims (10)

An ultrasonic touch panel comprising a piezoelectric substrate, two ultrasonic transmission / reception means provided on one plate surface of the piezoelectric substrate, and an information processing unit connected to the two ultrasonic transmission / reception means, Each ultrasonic wave transmitting / receiving means is composed of at least one pair of interdigital electrodes for input and interdigital electrodes for output corresponding to the interdigital electrodes for input, and the intersection region of the electrode fingers of the interdigital electrodes for output is 1 Consisting of N groups R _i (i = 1) or sandwiched between N groups R _i (i = 1, 2,..., N) and the two groups R _i and R _{(i + 1)} ( N−1) parts Q _i {i = 1, 2,... (N−1)}, and each group R _i has two parts R _ia and R _ib and a part sandwiched between them. It consists R _im, the portion _{R ia} and _{R ib} respective electrodes Direction parallel to the direction of the electrode fingers of said input interdigital transducer, said portion R _ia and R _ib respective interdigital periodicity is equal to the electrode periodicity P of the input interdigital transducer, said portion R _im The electrode finger has an inclination of an angle α with respect to the electrode finger of the interdigital electrode for input, and the period length P _RN of the electrode finger in the direction orthogonal to the electrode finger of the portion R _im is equal to the electrode period length P equal to the product of the cos [alpha], the electrode crossing width of the portion R _im is the part and overlap length L _RP in the direction of the electrode fingers of R _im, in a direction parallel to the electrode fingers of said input interdigital transducer There are two types of cross width L _RN, and the cross width L _RP is equal to the product of the cross width L _RN and sec α, and is equal to the product of half of the electrode period length P and cosec α, and the portion Q _i is the electrode fingers of the corner ± beta to the electrode fingers of said input interdigital transducer Has come, periodicity P _QN of the electrode fingers in a direction perpendicular to the electrode fingers of the part Q _i is equal to the product of the electrode periodicity P and cos .beta, the electrode crossing width of the portion Q _i is There are two types of intersection width L _{QP in} the direction of the electrode finger of the portion Q _i and intersection width L _QN in the direction parallel to the electrode finger of the interdigital electrode for input, and the intersection width L _QP is It is equal to the product of the intersection width L _QN and secβ, and the sum of the electrode intersection widths of the portions R _ia and R _ib , the intersection width L _RN, and the intersection width L _QN is the interdigital electrode The input interdigital electrode is substantially equal to the electrode crossing width L, and the input interdigital electrode excites an ultrasonic wave to the piezoelectric substrate by _{receiving an} electric signal, and the portions R _ia and R _{ib convert the} ultrasonic wave into the electric signal E _ia and _{E ib (i = 1,2, ......} , N) to change each And the amplitude of the electrical signal produced by synthesizing the electric signals E _ia and E _ib is zero, the input and output interdigital electrodes, in the piezoelectric substrate, each said moiety R _ia and R _ib Corresponding ultrasonic wave propagation paths Z _ia and Z _ib (i = 1, 2,..., N) are formed, and positions F _ia and F _ib (i = 1, 1) on one of the plate surfaces of the piezoelectric substrate. 2,..., N) correspond to the ultrasonic wave propagation paths Z _ia and Z _ib , respectively, and the output interdigital electrode contacts the position F _ia or F _ib with a finger or an object and the ultrasonic wave Only when the propagation path Z _ia or Z _ib is interrupted, the electrical signal E _ib or E _ia is output, and the information processing unit is in contact with one of the positions F _ia F _Xa , The position F _X or sensed by an electrical signal E _Xb corresponding to the position F _Xb forming a _a pair is output from the interdigital electrode and the output, or that in contact with the position F _Xb, corresponding to the position F _Xa An ultrasonic touch panel that senses when an electrical signal _EXa is output from the output interdigital electrode. 2. The ultrasonic touch panel according to claim 1, wherein the intersection width L _QP is equal to a product of a value obtained by dividing the electrode period length P by twice the number N of the groups R _i and cosec β. An ultrasonic touch panel comprising a piezoelectric substrate, two ultrasonic transmission / reception means provided on one plate surface of the piezoelectric substrate, and an information processing unit connected to the two ultrasonic transmission / reception means, Each ultrasonic wave transmitting / receiving means is composed of at least one set of interdigital electrodes for input and interdigital electrodes for output corresponding to the interdigital electrodes for input, and the intersection region of the electrode fingers of the interdigital electrodes for input is N Parts A _i (i = 1, 2,..., N) and (N−1) parts B _i {i = 1, 2 sandwiched between the two parts A _i and A _{(i + 1).} ,..., (N−1)}, and the interdigital region of the output interdigital electrode has (N + 1) portions C _i {i = 1, 2,..., (N + 1)}. , two of the portions _{C i} and _{C (i + 1)} sandwiched by N portions _{D i (i = 1,2, ......} , Made), the direction of the electrode fingers of the part A _i is parallel to the direction of the electrode fingers of the portions C _i, the electrode fingers of the portion B _i is the inclination of the portion A _i corner -β relative to the electrode fingers has, periodicity P _BN electrode fingers in a direction perpendicular to the electrode fingers of the portion B _i is equal to the product of the interdigital periodicity P and cosβ of the portion a _i and C _i, the portion B _i There are two types of electrode cross widths: a cross width L _{BP in} the direction of the electrode finger of the portion B _i and a cross width L _{BN in} a direction parallel to the electrode finger of the portion A _i. L _BP is equal to the product of the overlap length L _BN and Secbeta, wherein the electrode finger portion D _i having an inclination of angle α with respect to the electrode fingers of the portions C _i, perpendicular to the electrode fingers of the part D _i periodicity P _DN of the electrode fingers in a direction in which is equal to the product of the electrode periodicity P and cos [alpha], the electrode crossing width of the portion D _i The overlap length L _DP in the direction of the electrode fingers of the part D _i, there are two types of cross width L _DN in the direction parallel to the electrode fingers of the portions C _i, the overlap length L _DP, the together equal to the product of the overlap length L _DN and Secarufa, equal to the product of half the cosecα of the interdigital periodicity P, the sum of the partial a _i crossing width and the overlap length L _BN of the electrode fingers of the part approximately equal to the sum of C _i crossing width and the overlap length L _DN of the electrode fingers, said input interdigital transducer, by inputting an electric signal to excite an ultrasonic wave to the piezoelectric substrate, blinds for said output The electrode converts the ultrasonic waves into N electrical signals E _ia (i = 1, 2,..., N) and N electrical signals E _ib (i = 1, 2,..., N). , the amplitude of the electrical signal produced by synthesizing the electric signals E _ia and E _ib is , And the said input and output interdigital electrodes, said in piezoelectric substrate, N numbers of ultrasonic propagation path _{Z ia (i = 1,2, ......} , N) and N numbers of ultrasonic propagation path Z _ib (I = 1, 2,..., N), the ultrasonic wave propagation path Z _ia is between the portions A _i and C _i , and the ultrasonic wave propagation path Z _ib is the portions A _i and C _{( i + 1)} , and the positions F _ia and F _ib (i = 1, 2,..., N) on either one of the piezoelectric substrates are respectively in the ultrasonic wave propagation paths Z _ia and Z _ib . Correspondingly, the output interdigital electrode is connected to the electric signal E _ib only when the finger or object touches the position F _ia or F _ib and the ultrasonic wave propagation path Z _ia or Z _ib is interrupted. or outputs _{E ia,} the information processing unit, among the position _{F ia} One that has been in contact with the F _Xa, or electrical signal E _Xb corresponding to the position F _Xb forming the position F _Xa paired senses by being output from the interdigital electrode the output, or the position F _Xb ultrasonic touch panel for sensing by the fact that contact with the electrical signal E _Xa corresponding to the position F _Xa is output from the interdigital electrode the output. The overlap length L _BP An ultrasonic touch panel according to the electrode periodicity P in the portion A and a value obtained by dividing twice the number N of _i, claim 3 equal to the product of the Cosecbeta. The information processing unit comprises an amplifier and a signal processor, and the output end of the output interdigital electrode is connected to the input end of the input interdigital electrode and the input end of the signal processor via the amplifier, said electric signals _{E ia} and _{E ib} each have a frequency _{f ia} and _{f ib,} the signal processor is a frequency _{f Xb} of the electrical signal _{E Xb} said position _{F Xa} in contact of the position _{F ia} 5. The method according to claim 1, 2, 3, or 4, wherein the position F _Xb in contact with the position F _{i b} is specified by detecting the frequency f _Xa of the electric signal E _Xa. Ultrasonic touch panel. Each of the ultrasonic wave transmitting / receiving means includes two reference interdigital electrodes, one of the reference interdigital electrodes is used for input, and the other is used for output, and the electrodes of the two reference interdigital electrodes Finger directions are parallel to each other, the information processing unit is composed of an amplifier, a phase comparator, and a signal processor, and the output terminal of the other reference interdigital electrode is connected to the one reference reference through the amplifier. The interdigital transducer and the input interdigital transducer are connected to the input ends of the interdigital transducer and the input end of the phase comparator, respectively, and the output end of the output interdigital transducer is connected to the signal processing device via the phase comparator. The reference interdigital electrode is connected to the input end of the device, and an ultrasonic wave is excited to the piezoelectric substrate by inputting an electric signal, and the other reference interdigital electrode is And outputs the converted electrical signal having a phase theta _base, the electric signal _{E ia} and _{E ib} each have a phase theta _ia and theta _ib, the phase comparator and the phase theta _base, the phase theta _ia or detecting the difference between theta _ib, said signal processor on the basis of the position _{F Xa} in contact of the position _{F ia} the difference between the phase _{theta Xb} of the electrical signal _{E Xb} and the phase theta _{bas e} claims 1 to 4 identified based either specific or the position _{F Xb} in contact of the position _{F i b} the difference between the phase _{theta Xa} of the phase theta _base and the electrical signal _{E Xa} The ultrasonic touch panel as described in 2.   The electrode cycle length P is larger than the thickness d of the piezoelectric substrate, and the interdigital electrode for input receives an electric signal having a frequency substantially corresponding to the electrode cycle length P, whereby the piezoelectric substrate is subjected to the above-described operation. The ultrasonic touch panel according to claim 1, wherein an acoustic wave having a wavelength substantially equal to the electrode period length P is excited.   The electrode period length P has a value equal to or less than one-third of the thickness d of the piezoelectric substrate, and the input interdigital electrode receives an electric signal having a frequency substantially corresponding to the electrode period length P. The supersonic wave according to claim 1, 2, 3, 4, 5 or 6, wherein a surface acoustic wave having a wavelength substantially equal to the electrode periodic length P is excited in the vicinity of the surface of the one plate surface of the piezoelectric substrate. Sonic touch panel.   The super substrate according to claim 1, 2, 3, 4, 5, 6, 7 or 8, wherein the piezoelectric substrate is made of a piezoelectric ceramic, and a direction of a polarization axis of the piezoelectric ceramic is parallel to a thickness direction of the piezoelectric ceramic. Sonic touch panel. And the ultrasonic propagation path Z _ia and Z _ib of one of the ultrasonic transmitter means, the claims and the ultrasonic propagation path Z _ia and Z _ib at the other of said ultrasonic transmitter means are orthogonal to each other The ultrasonic touch panel according to 1, 2, 3, 4, 5, 6, 7, 8, or 9.

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