WO2011041948A1 - 分析位置的方法与装置 - Google Patents
分析位置的方法与装置 Download PDFInfo
- Publication number
- WO2011041948A1 WO2011041948A1 PCT/CN2010/001562 CN2010001562W WO2011041948A1 WO 2011041948 A1 WO2011041948 A1 WO 2011041948A1 CN 2010001562 W CN2010001562 W CN 2010001562W WO 2011041948 A1 WO2011041948 A1 WO 2011041948A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- value
- zero
- sensing information
- positive
- negative
- Prior art date
Links
Classifications
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/044—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means
- G06F3/0446—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means using a grid-like structure of electrodes in at least two directions, e.g. using row and column electrodes
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R27/00—Arrangements for measuring resistance, reactance, impedance, or electric characteristics derived therefrom
- G01R27/02—Measuring real or complex resistance, reactance, impedance, or other two-pole characteristics derived therefrom, e.g. time constant
- G01R27/26—Measuring inductance or capacitance; Measuring quality factor, e.g. by using the resonance method; Measuring loss factor; Measuring dielectric constants ; Measuring impedance or related variables
- G01R27/2605—Measuring capacitance
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/0416—Control or interface arrangements specially adapted for digitisers
- G06F3/04166—Details of scanning methods, e.g. sampling time, grouping of sub areas or time sharing with display driving
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/0416—Control or interface arrangements specially adapted for digitisers
- G06F3/0418—Control or interface arrangements specially adapted for digitisers for error correction or compensation, e.g. based on parallax, calibration or alignment
- G06F3/04182—Filtering of noise external to the device and not generated by digitiser components
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/044—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means
- G06F3/0445—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means using two or more layers of sensing electrodes, e.g. using two layers of electrodes separated by a dielectric layer
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F2203/00—Indexing scheme relating to G06F3/00 - G06F3/048
- G06F2203/041—Indexing scheme relating to G06F3/041 - G06F3/045
- G06F2203/04104—Multi-touch detection in digitiser, i.e. details about the simultaneous detection of a plurality of touching locations, e.g. multiple fingers or pen and finger
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/047—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means using sets of wires, e.g. crossed wires
Definitions
- the present invention relates to a method and apparatus for analyzing a position, and more particularly to a method and apparatus for position analysis based on sensing information at a zero crossing.
- Touch Display has been widely used in many electronic devices. It is common to use a Touch Sensing Panel to define a two-dimensional touch area on the touch display by using the touch panel. A scan of the vertical and horizontal axes is performed to obtain Sensing Information to determine the touch or proximity of an external object (such as a finger) on the touch screen, such as a capacitive type provided by US Pat. No. 4,639,720. Touch the display.
- the sensing information can be converted into a plurality of continuous signal values by an analog-to-digital converter (ADC), and the external value can be judged by comparing the amount of change of the signal values before or after the external object touches or approaches. The location where the object touches or is closest to the touch screen.
- ADC analog-to-digital converter
- the controller that controls the touch screen first obtains sensing information when no external object touches or approaches, as a baseline. For example, in a capacitive touch screen, each of the conductive strips corresponds to a respective reference value. The controller determines whether there is an external object approaching or touching by judging the comparison between the subsequent sensing information and the reference value, and further determining the position of the external object. For example, when the external object is not approached or touched, the subsequent sensing information is zero or approaches zero with respect to the reference value, and is determined by whether the sensing information is zero or close to zero relative to the reference value. Whether there are external objects approaching or touching.
- FIG. 1A when an external object 12 (such as a finger) touches or approaches the sensing device 120 of the touch display 10, the sensing information of the sensor 140 in an axial direction (such as the X-axis) is converted.
- the signal value shown in FIG. 1B corresponds to the shape of the finger, and the signal value presents a waveform or a finger profile, and the position of the peak 14 on the fingertip indicates that the finger touches or approaches. position.
- a further object of the present invention is to provide a new method and apparatus for analyzing a position by overcoming the existing methods and apparatus for analyzing a position, and the technical problem to be solved is to make the number of touches and zeros When the number of intersections is different, each position is judged, which is more suitable for practical use.
- Still another object of the present invention is to provide a novel method and apparatus for analyzing a position by overcoming the existing methods and apparatus for analyzing a position, and the technical problem to be solved is to make the touch-related sensing
- the odd number is set to zero, and the zero crossing is judged according to the positive threshold and the negative threshold, so that it is more suitable for practical use and has industrial utilization value.
- the object of the present invention and solving the technical problems thereof can be further achieved by the following technical measures.
- the foregoing method for analyzing a position wherein the number of the at least one zero crossing is an even number.
- the foregoing method for analyzing a position wherein the number of the at least one zero crossing is one, and the number of the at least one position is two.
- the foregoing method for analyzing a position wherein the sensing information is double differential sensing information, and each value of the double differential sensing information is generated according to signals of three sensors in the sensors.
- the method for analyzing a location wherein the sensing information is differential sensing information, and each value of the differential sensing information is generated according to a signal of a pair of sensors in the sensors.
- the foregoing method for analyzing a location further includes: analyzing, by the sensing information, at least one location that is the same as the number of the at least one zero intersection.
- An apparatus for analyzing a position according to the present invention comprising:
- a controller or a host performs the following tasks:
- the sensing information includes at least one zero crossing, wherein each of the zero crossings is between a positive value and a negative value;
- a plurality of locations different from the at least one zero intersection are analyzed by the sensing information.
- the object of the present invention and solving the technical problems thereof can be further achieved by the following technical measures.
- the aforementioned apparatus for analyzing a position wherein said at least one position is analyzed based on a zero intersection located at an odd position.
- the foregoing apparatus for analyzing a position wherein the number of the at least one zero crossing is an even number.
- the foregoing apparatus for analyzing a position wherein the number of the at least one zero crossing is one, and the number of the at least one position is two.
- the device for analyzing the position further includes: a sensing device including a plurality of sensors; wherein the sensing information is double differential sensing information, and each value of the double differential sensing information is based on the senses The signals from the three sensors in the detector are generated.
- the device for analyzing the position further includes: a sensing device including a plurality of sensors; wherein the sensing information is differential sensing information, and each value of the differential sensing information is based on the sensors The signal of a pair of sensors is generated.
- the foregoing apparatus for analyzing a location wherein the controller or the host further comprises: performing, by the sensing information, at least one location that is the same as the number of the at least one zero intersection.
- the present invention has significant advantages and advantageous effects over the prior art. From the above, in order to achieve the above object, the present invention provides a method and apparatus for analyzing a position. By performing an analysis of the sensing information including at least one zero crossing, a plurality of different locations from the zero crossing can be analyzed. When the number of positions analyzed is different from the number of zero-crossing points, the number of positions analyzed is plural.
- a method for analyzing a location includes: obtaining a sensing information, where the sensing information includes at least one zero-crossing, wherein each zero-crossing is located between a positive value and a negative value; The sensing information analyzes a different number of locations than the at least one zero crossing.
- an apparatus for analyzing a location includes a controller or a host, and performs the following operations: obtaining a sensing information, where the sensing information includes at least one zero-crossing place, where each zero-crossing is located a positive value and a negative value; and analyzing, by the sensing information, a plurality of positions different from the at least one zero intersection.
- a method for analyzing a position according to the present invention includes: obtaining a sensing information; determining at least one first starting position in the sensing information according to a first threshold value; and facing each of the first starting positions A first range of the first direction performs a zero-crossing position analysis to determine the position of a zero-crossing point, wherein each zero-crossing is located between a positive value and a negative value.
- a device for analyzing a location according to the present invention includes a controller or a host, and performs the following operations: obtaining a sensing information; determining at least one first in the sensing information according to a first threshold value.
- each zero-crossing position analysis from each of the first starting positions toward a first range of the first direction to respectively determine a position of a zero-crossing point, wherein each zero-crossing is located at a positive value and a Negative value.
- a method for detecting a finger touch in a sensing device includes: obtaining a sensing information; determining, according to a positive threshold, whether the sensing information has a positive value greater than a positive threshold; determining according to a negative threshold Whether there is a negative value less than a negative threshold in the sensing information; and a zero intersection between a positive value greater than the positive threshold and a negative value less than the negative threshold when there is a positive value greater than the positive threshold and a negative value less than the negative threshold At the office.
- a device for detecting a finger touch in a sensing device includes a controller or a host, and performs the following operations: obtaining a sensing information; determining whether the sensing information exists according to a positive threshold a positive value greater than the positive threshold; determining whether there is a negative value less than the negative threshold in the sensing information according to a negative threshold; and judging that the positive threshold is greater than the negative threshold when there is a positive value greater than the positive threshold and a negative value smaller than the negative threshold Between the value and the negative value less than the negative threshold Zero-crossing office.
- the method and apparatus for analyzing a position of the present invention have at least the following advantages and beneficial effects:
- the location is analyzed based on the characteristics of the differential sensing information, which is more accurate than the peak value of the signal.
- the present invention relates to a method and apparatus for analyzing a position. By analyzing an sensing information including at least one zero crossing, a plurality of different positions from the zero intersection can be analyzed. When the number of positions analyzed is different from the number of zero-crossing points, the number of positions analyzed is plural.
- the invention has significant advances in technology and has obvious positive effects, and is a novel, progressive and practical new design.
- FIG. 1A is a schematic diagram of a prior art touch device.
- Figure 1B is a schematic illustration of prior art signal values.
- Figure 1C is a schematic illustration of the difference values in accordance with the present invention.
- 1D and 1E are schematic illustrations of double differences in accordance with the present invention.
- Figure 1F is a schematic view showing the structure of a sensing device in accordance with the present invention.
- 1G is a functional block diagram of an arithmetic system in accordance with the present invention.
- FIGS. 2A and 2B are schematic structural views of a driving/detecting unit and a sensing device according to the present invention.
- 3A is a functional block diagram of a detecting unit in accordance with the present invention.
- 3E to 3J are schematic diagrams showing the connection of a detecting circuit and an analog to digital circuit in accordance with the present invention.
- 4A-4B are schematic diagrams showing binarized difference detection positions in accordance with the present invention.
- 4C-4D are schematic diagrams showing examples of detecting centroid positions in accordance with the present invention.
- 5A-5B are schematic diagrams showing examples of determining a zero crossing in accordance with the present invention.
- 5C to 5F are diagrams showing an example of judging a multi-zero intersection according to the present invention.
- 6A-6B illustrate the proximity or touch of a single object or multiple external objects according to the present invention.
- Figure 8 is a flow chart showing a second embodiment of the present invention.
- Host 171 Central Processing Unit
- Cinv Inverter Pl, P2: Contact
- Tp Positive threshold
- TTn Negative threshold
- the sensing information may be provided by a touch sensing device (Touch Sensing Device), indicating a state of one dimension, two dimensions or multiple dimensions on the touch device, and the sensing information may be one or more
- a sensor is obtained by converting one or more analog-to-digital converters into a plurality of continuous signal values to indicate the amount or change of the detected charge, current, voltage, capacitance, impedance, or other electrical characteristic. the amount.
- the process of obtaining or transmitting the sensing information may be performed in a rotating, sequential or parallel manner, and may be combined into one or more signals, which can be easily inferred by those skilled in the art.
- the sensing information according to the present invention includes, but is not limited to, a signal of the sensor and a signal subtraction reference value of the sensor (such as a signal when not touched or an initial signal).
- the sensing information may exist in a signal state, any state recorded by the storage medium (such as a scratchpad, a memory, a disk, a disc) converted by an electrical signal or convertible into an electrical signal, including But not limited to analog or digital form.
- the sensing information may be provided by two one-dimensional sensing information in different axial directions.
- Two one-dimensional sensing information can be used to indicate sensing information on the first axial direction (such as the longitudinal axis) and the second axial direction (such as the horizontal axis) on the touch device, which can be used for the first Position detection in an axial direction and a second axial direction respectively provides a one-dimensional position in the first axial direction and the second axial direction, or further constitutes a two-dimensional position.
- the two one-dimensional sensing information can also be used for triangulation based on the distance between the sensors to detect the two-dimensional position on the touch device.
- the sensing information may be provided by a two-dimensional sensing information, and the two-dimensional sensing information is composed of a plurality of one-dimensional sensing information coaxially upward.
- a two-dimensional sensing information is provided to represent a signal distribution on a two-dimensional plane, for example, a plurality of one-dimensional sensing information in the longitudinal axis or a plurality of one-dimensional sensing information in the horizontal axis to represent a signal.
- the signal matrix can be used for position detection according to the water diversion algorithm or other image processing identification methods.
- the sensing area on the touch device includes a first two-dimensional detection range detected by the at least one first sensor and a second detected by the at least one second sensor.
- the overlap range of the dimension detection range is an overlapping range of three or more two-dimensional detection ranges.
- the detection range of a single sensor is a two-dimensional detection range, such as a camera-based optical detection sensor (such as a CCD or CMOS sensor) or a surface acoustic wave.
- the detected voltage inductive detector obtains one-dimensional sensing information from the two-dimensional detection range.
- the one-dimensional sensing information may be composed of information sensed by a plurality of consecutive time points, and the different time points correspond to different angles, positions or ranges.
- this one-dimensional sensing information can be based on one Images acquired during the time interval (such as those obtained by CCD or CMOS sensors).
- the two-dimensional detection range is composed of detection ranges of multiple sensors, such as each infrared-detecting light receptor, capacitive detection or resistive detection of linear or strip-shaped conductive
- the detection range of the strip or electromagnetically detected U-shaped coil is a fan-shaped or strip-shaped detection range toward an axial direction, and a plurality of sensors arranged in the same axial direction on a line segment (straight line or arc)
- the detection range can constitute the two-dimensional detection range of the axis, such as a detection range of a plane or a curved surface constituting a rectangle or a sector.
- a two-dimensional sensing information can be constructed by collecting one-dimensional sensing information corresponding to each of the first axial sensors.
- the two-dimensional sensing information can be regarded as an image.
- a person skilled in the art can infer that the present invention can be applied to a touch sensitive display, for example, with or with the above-mentioned resistive detection, capacitive detection, surface acoustic wave detection, or other detection touch.
- a touch device or touch sensitive device that touches the display.
- touch-sensitive display or touch device may be considered as a touch-sensitive information (touch sensitive information) 0
- the touch device is a continuous signal at different points in time, that is, a composite signal continuously detected by one or more sensors at the same time.
- the touch device can be electromagnetic, even Continue to scan the coil on the electromagnetic touch device to emit electromagnetic waves, and the sensing information is detected by one or more sensors on an electromagnetic pen, continuously combined into a signal, and then converted into multiple signals by the analog to digital converter. Continuous signal values.
- the electromagnetic pen may emit electromagnetic waves or reflect electromagnetic waves from the electromagnetic touch device, and the sensing information may be obtained by a plurality of sensors (coils) on the touch device.
- Touch related sensing information When an external object (such as a finger) touches or approaches the touch device, the sensing information of the corresponding position that the external object touches or approaches generates corresponding electrical characteristics or changes.
- the electrical properties are stronger or vary larger than the center of the external object (such as centroid: center of gravity, center of gravity or geometric center).
- centroid center of gravity, center of gravity or geometric center.
- continuous sensing information may be considered to consist of a plurality of consecutive values, and the outer object center may correspond to a value or between two values. In the present invention, a plurality of consecutive values may be continuous or temporally continuous in respective spaces.
- the first one-dimensional sensing information provided by the present invention is presented by a plurality of consecutive signal values, which may be signal values detected by multiple sensors in a time interval, or a single sensor in a continuous time interval.
- the detected signal value may also be a signal value detected by a single sensor corresponding to different detection positions in a single time interval.
- the signal of the corresponding individual sensor, time interval or position may be converted into a signal value in turn, or some or all of the sensing information may be obtained and then analyzed. Individual signal values.
- the continuous signal value of the one-dimensional sensing information may be as shown in FIG.
- the present invention does not limit the form in which the sensing information exists, and the difference can be regarded as another form of the differential signal.
- the difference will be described in the following description in the form of a difference type, and one of ordinary skill in the art can infer the implementation of the differential signal type in accordance with the embodiment of the difference type.
- the difference may be a difference between a pair of adjacent or non-adjacent signal values, such as a difference between each signal value and a previous signal value, or each signal value is followed by The difference between a signal value.
- the difference may be a difference between two adjacent signal values.
- the continuous difference of the one-dimensional sensing information may be as shown in FIG. 1C, and the external object position is the zero-crossing point 15 of the sensing information of the corresponding external object, wherein the zero-crossing place 15 may fall between the two signal values.
- the corresponding position of each difference is the middle of the corresponding position of the two signal values.
- the difference between the difference between the first pair of signal values and the second pair of signal values is a first difference and a second difference, respectively, and the double difference is the first difference.
- a sum of the second difference wherein one of the first difference and the second difference is a difference between the previous signal value minus the subsequent signal value, and the other of the first difference and the second difference is The subsequent signal value is subtracted from the difference of the previous signal value.
- the two pairs of signal values sequentially include a first signal value, a second signal value, a third signal value, and a fourth signal value
- the double difference corresponding to the four signal values is (the second signal Value - first signal value) + (third signal value - fourth signal value), (second signal value - first signal value) - (fourth signal value - third signal value), (first signal value - Second signal value) + (fourth signal value - third signal value) or (first signal value - second signal value) - (third signal value - fourth signal value).
- the sensing information composed of a plurality of consecutive double differences can be regarded as dual-differential sensing information.
- the double difference is not limited to be generated after the signal value or the difference is generated, or may be the sum or difference of the subtraction of the two pairs of signals respectively when the sensing information is provided, providing a similar or A double differential signal equivalent to the sum or difference of the difference between two pairs of signal values.
- the present invention does not limit the form in which the sensing information exists, and the double difference can be regarded as another form of the double differential signal of the sensor.
- the present invention will be described in the following description in the form of a double difference type, and one of ordinary skill in the art can infer the implementation of the double differential signal type according to the embodiment of the double difference type. .
- the two pairs of signal values are composed of three signal values that are adjacent or not adjacent.
- the difference between the difference between the first two signal values and the last two signal values is a first difference and a second difference, respectively, and the double difference is the first difference and the first difference
- the difference between the two differences, wherein the first difference and the second difference are both the difference between the previous signal value minus the subsequent signal value or the difference between the subsequent signal value and the previous signal value.
- the two pairs of signal values sequentially include a first signal value, a second signal value, and a third signal value
- the double difference corresponding to the three signal values is (second signal value - first signal value) + (second signal value - third signal value), (second signal value - first signal value M third signal value - second signal value), (first signal value - second signal value) + (first Three signal value - second signal value) or (first signal value - second signal value M second signal value - third signal value).
- the continuous double difference of the one-dimensional sensing information may be as shown in the figure ID, wherein the external object position is A central peak 16 of the sensed information of the corresponding external object, wherein the central peak 16 may fall between the two signal values.
- the continuous double difference value of the one-dimensional sensing information may be as shown in FIG. 1E, wherein the external object position
- the central peak 17 of the sensed information for the corresponding external object may have a central peak 17 that falls between the two signal values.
- the sensing information of the corresponding individual sensor, time interval or position may be a signal detected by the sensor, and when the signal is analog, it may be converted into a digital signal value via an analog to digital converter. Therefore, the above difference may also be a value of a difference between a pair of signals, for example, a signal: a value converted by subtraction by a differential amplifier. Similarly, the double difference may also be a value converted by subtracting and then adding (or subtracting) the two pairs of signals respectively through a differential amplifier.
- the difference and double difference described in the present invention include, but are not limited to, signal or signal value, and also include recording during hardware or software implementation (electrical recording, magnetic recording). Temporary state of recording, optical recording), signal or signal value.
- the sensing information may be a signal on the sensor or between the sensors, a differential signal (such as a pair of signal differences), a double differential signal (such as a sum or difference of two pairs of signal differences), a signal value, a difference
- the double difference (signal after the analog to digital, difference, double difference) is another form of existence. Since the signal and signal values, the differential signal and the difference, the double differential signal and the double difference can be presented at different stages of the sensing information.
- the touch-related sensing information generally refers to sensing information corresponding to an external object touching or approaching, such as original touch-related sensing information, differential touch-related sensing. Information, double differential touch related sensing information.
- the zero crossing is located between at least a positive value and at least a negative value, that is, between a pair of positive and negative values (between a pair of Positive and negative values).
- Corresponding to the difference between the proximity and the touch of the external object or the double difference is a continuous combination of at least one positive value and at least one negative value, at least one positive value and at least one negative value are adjacent to each other or at least one interval apart value.
- the difference or double difference corresponding to the proximity or touch of an external object is a continuous combination of multiple positive values and multiple negative values.
- the zero intersection between positive and negative values may be Is at least a zero value or is between two values.
- the touch-related signal value is a plurality of consecutive non-zero values, or may be an independent non-zero value that is not adjacent to other non-zero values.
- an independent non-zero value that is not adjacent to other non-zero values may be due to noise and needs to be identified or excluded by a threshold or other mechanism.
- the differential touch-related sensing information and the double-difference touch-related sensing information are alternating combinations of at least one positive value and at least one negative value at the zero-crossing, wherein the zero-crossing may be at least one zero.
- the value is either between positive and negative values.
- the present invention compares the differential touch-related sensing information into a plurality of zero values of positive and negative values in the double-differential touch-related sensing information, and is also regarded as a zero-crossing point, or one of the zero values is zero. At the office.
- the touch-related sensing information preset is started by at least one positive value or a negative value, and the at least one positive or negative value is initially searched for at least one positive including zero intersection.
- An alternating combination of values and at least one negative value, wherein the zero crossing may be at least a zero value or between a positive value and a negative value.
- the touch-related differential sensing information at least one positive value and at least one negative value are alternately combined as a pair of linings, and in the touch-related double differential sensing information, at least one positive value and at least one negative value
- the alternating combination is that no lining appears.
- the touch-related sensed information is a continuous non-zero value, such as a plurality of consecutive non-zero signal values.
- the at least one positive value can be regarded as a positive value set, including at least one positive value
- the above-mentioned at least one negative value can be regarded as a negative value set, including at least one negative value.
- the alternating combination described above may be a combination of two sets comprising a positive set and a negative set or a combination of more than three sets interleaved with a set of positive values and a set of negative values.
- the present invention uses a capacitive touch device as an example, and those skilled in the art can easily infer that other applications are applied to resistive, infrared, and surface acoustic waves.
- the application of optical touch devices is not limited to, but not limited to, but not limited to, but not limited to, but not limited to, but not limited to, but not limited to, but not limited to, but not limited to, but not limited to, but not limited to, buth., a capacitive touch device, and those skilled in the art can easily infer that other applications are applied to resistive, infrared, and surface acoustic waves.
- the application of optical touch devices are examples of optical touch devices.
- the present invention provides a position detecting device 100.
- the device includes a sensing device 120 and a driving/detecting unit 130.
- the sensing device 120 has a sensing layer.
- a first sensing layer 120A and a second sensing layer 120B may be included.
- the first sensing layer 120A and the second sensing layer 120B respectively have a plurality of sensors 140, wherein One sense The plurality of first sensors 140A of the layer 120A overlap the plurality of second sensors 140B of the second sensing layer 120B.
- the plurality of first sensors 140A and the second sensors 140B may be disposed in a coplanar sensing layer.
- the driving/detecting unit 130 generates a sensing information according to the signals of the plurality of sensors 140. For example, in the self-capacitance detection, the sensed sensor 140 is sensed, and in the mutual-point capacitive detection, the partial sensing that is not directly driven by the driving/detecting unit 130 is sensed.
- the sensing device 120 may be disposed on the display 110.
- the sensing device 120 and the display 110 may be configured with a shielding layer (not shown) or a back shield layer.
- the position detecting device 100 of the present invention can be applied to a computing system, as shown in FIG. 1G, including a controller 160 and a host 170.
- the controller includes a drive/detect unit 130 for operatively coupling the sensing device 120 (not shown).
- the controller 160 can include a processor 161 that controls the driving/detecting unit 130 to generate sensing information.
- the sensing information can be stored in the memory 162 for access by the processor 161.
- the host 170 constitutes the main body of the computing system, and mainly includes a central processing unit 171, and a storage unit 173 for access by the central unit 171, and a display 110 for displaying the result of the operation.
- the sensing information may be initial sensing information generated by the processor 161, and the host 170 performs position analysis, such as position analysis, gesture determination, command recognition, and the like. .
- the sensing information may be analyzed by the processor 161 first, and the determined position, gesture, command, and the like are delivered to the host 170.
- the present invention includes, but is not limited to, the foregoing examples, and one of ordinary skill in the art can infer the interaction between other controllers 160 and host 170.
- the driving unit 130A drives or drives all the sensors 140A in a first period of time through the wire W1, and may also drive the partial sensors 140A in stages.
- the unit 130B generates a first axial sensing information (one-dimensional sensing information) according to the signal of the sensor 140A via the wire W1.
- the driving unit 130A drives or drives all the sensors 140B in a second period via the wire W2, or may be a simultaneous drive.
- the sensor portion 140B generates a second axial sensing information (one-dimensional sensing information:) by the detecting unit 130B according to the signal of the sensor 140B via the wire W2.
- the driving unit 130A alternately drives the sensor 140B in the first period via the wire W2, and is respectively driven by the detecting unit 130B via the wire W1 when each sensor 140B is driven.
- the signal of the sensor 140A generates one-dimensional sensing information corresponding to the first axial direction of the driven sensor, and the first-dimensional one-dimensional sensing information constitutes a two-dimensional sensing information of the first axial direction ( Or an image).
- the driving unit 130A alternately drives the sensor 140A in the second period via the wire W1, and when each sensor 140A is driven, the detecting unit 130B generates a corresponding signal according to the sensor 140B via the wire W2.
- the second axial one-dimensional sensing information is used to form a second-dimensional one-dimensional sensing information (or an image) of the second axial direction of the driven sensor.
- a signal may be provided between the driving unit 130A and the detecting unit 130B via the line 132 for synchronization, and the signal of the line 132 may be provided by the processor 160.
- the sensing device 120 can also generate two-dimensional sensing information only in a single axial direction.
- the sensor 140B is driven by the wire W2 in turn, respectively, in each of the sensors 140B.
- the detecting unit 130B When driving, the detecting unit 130B generates a one-dimensional sensing information corresponding to the driven sensor according to the signal of the sensor 140A via the wire W1, and the one-dimensional sensing information constitutes a two-dimensional sensing information (or an image) ).
- the position detecting device 100 of the present invention may have the capability of generating two axial one-dimensional sensing information or two axial two-dimensional sensing information, or one dimension that generates two axial directions.
- the ability to sense information and two-dimensionally sense information can also produce only uniaxial two-dimensional sensing information.
- the present invention includes, but is not limited to, the above-described capacitive position detecting device, and those skilled in the art can easily infer other applications for resistive, infrared, surface acoustic wave, and optical touch devices.
- the detecting circuit 320 may be composed of one or more detectors, each of which receives at least one signal of the sensor 140 to generate an output, and the detector may be a detector as shown in FIG. 3B to FIG. 3D. 340, 350, 360 are shown.
- the detection of the signal of the sensor 140 may be detected by an integrator, and those skilled in the art may infer other quantifiable electrical properties such as an analog to digital converter. Circuitry of characteristics such as voltage, current, capacitance, inductance, etc. can also be applied to the present invention.
- the integrator can be implemented as an amplifier Cint having an input (as shown by integrator 322 of Figure 3B) or a pair of inputs (shown as integrator 324 of Figures 3C and 3D), and an output.
- the output signal may be a value of the sensing information SI generated by the analog to digital circuit 320.
- the generation of each value may be controlled by a reset signal, such as the reset signal of the 3S to 3D.
- the signal of the sensor 140 is an alternating current signal, which changes with a pair of half cycles, so the detection of the signal of the sensor 140 is also changed according to different half cycles, such as in the first half.
- the signal of the period detection sensor 140 detects the reverse signal of the sensor 140 during the second half of the cycle, and vice versa. Therefore, the detection of the signal of the sensor 140 can be controlled by a synchronization signal Ssync. As shown in FIG. 3B to FIG. 3C, the synchronization signal Ssync and the signal of the sensor 140 can be synchronized or have the same period.
- the detection of the signal of the sensor 140 is detected by at least one predetermined period (or phase) of at least one period, and may be at least one period and a second period of the first half period.
- the detection may be performed for at least one period of time, or may be detected only during the first half period or at least one period of the second half period.
- at least one period of time during which the signal in a period is preferred is scanned as a detection period, wherein the detection period is less interfered by noise than other periods.
- the scanning of the detection period can be determined based on the detection of the signal of the at least one sensor in each of the at least one period. After the detection period is judged, the detection of the signal of the sensor 140 is only detected during the detection period, and may be controlled by a signal, such as the enable signal Senable in FIG. 3B to FIG. 3D.
- the present invention generates a value of the sensing information SI according to the signal of the at least one sensor 140.
- the sensing information SI is composed of a plurality of signal values.
- an input 311 is operatively coupled to a sensor 140 to detect a signal, and then a signal value of the sensing information SI is generated via the analog-to-digital circuit 330.
- the sensing information SI is composed of a plurality of differences.
- a pair of inputs 312, 313 are operatively coupled to a pair of sensors 140 to detect a differential signal, and a difference value of the sensing information SI is generated via the analog to digital circuit 330.
- the sensing information SI is composed of a plurality of double differences.
- Figure 3D shows. Three inputs 314, 315, 316 are operatively coupled to the three sensors 140 to detect a pair of differential signals, and then a pair of difference values of the sensing information SI are generated via the analog to digital circuit 330. Double differential signal is based on a pair of differential signals The difference between the numbers is generated, and each differential signal is generated based on the signals of a pair of sensors.
- the double differential signal may be generated according to signals of a first pair of sensors and a second pair of sensors, the first pair of sensors being the first two of the three sensors, And the second pair of sensors is the last two of the three sensors, three of which may be adjacent or not adjacent.
- the detection circuit 320 includes a plurality of detectors that simultaneously generate values of all or part of the sensing information SI.
- the detecting circuit 320 may be composed of a plurality of detectors 340, 350 or 360, and the outputs of the detectors are converted by the analog-to-digital circuit 330 into the values of the sensing information SI. .
- the analog-to-digital circuit 330 includes at least one analog-to-digital ADC, and each analog-to-digital device can generate the value of the sensing information SI according to the output of only one detector, as shown in FIG. 3E, FIG. 3G, and FIG.
- the value of the sensing information SI may be generated by the output of the plurality of detectors in turn, as shown in FIG. 3F, FIG. 3H, and FIG. 3J.
- the value of the sensing information SI may be generated in parallel or in sequence.
- the value of the sensing information SI is sequence generated, which may be achieved by a switching circuit 370, for example, multiple
- the analog-to-digital device alternately outputs the value of the sensing information SI, as shown in FIG. 3E, FIG. 3G, and FIG. 31, or provides the output of the plurality of integrators to an analog-to-digital device to generate the value of the sensing information SI. : as shown in Figure 3F, Figure 3H, Figure 3J.
- the sensing information SI having a plurality of signal values is generated according to the signals of the plurality of sensors, wherein each of the signal values is generated according to a signal of a sensor, as shown in the figure. 3B, FIG. 3E and FIG. 3F.
- the sensing information SI having a plurality of differences is generated according to the signals of the plurality of sensors, wherein each difference is generated according to a signal of the pair of sensors, as shown in FIG. 3C. Figure 3G and Figure 3H.
- the sensing information SI having a plurality of double differences is generated according to signals of the plurality of sensors, wherein each double difference is generated according to signals of the three sensors, such as 3D, 31 and 3J are shown.
- the wires connecting the plurality of detectors include, but are not limited to, a wire W1 or a wire W2.
- the integrator and the conductor include, but are not limited to, a direct connection, or may be connected through a switching circuit, as shown in Fig. 3A.
- the value of the sensing information is generated by the at least one detector of the detecting circuit 320 by multiple detections, and the detecting circuit 320 is selected by the sensing circuit through the switching circuit 310. Some sensors are used for detection.
- only the selected sensor is driven by drive unit 130A, such as in self-capacitance detection.
- only selected sensors and portions adjacent to the selected sensor are driven by drive unit 130A.
- the sensing information may be obtained by a double differential circuit
- the double differential circuit includes: a first stage differential circuit, a second stage differential circuit and a measuring circuit, for example Figure 3D, Figure 31 or Figure 3J.
- the first stage differential circuit includes one or more first subtractors (e.g., differential amplifiers in the switch circuit 325), each of which is based on a signal of a pair of the sensors A first level difference signal is generated.
- first subtractors e.g., differential amplifiers in the switch circuit 325
- the second stage differential circuit includes one or more second subtractors (eg, integrators in the integrating circuit 324), and each of the second subtractors respectively depends on a pair of the first stages of the first level difference signals The difference signal produces a second level difference signal.
- second subtractors eg, integrators in the integrating circuit 324.
- the measurement circuit may be as shown in the analog-to-digital circuit of FIG. 3A, and may be composed of an integrator 324 and an analog conversion circuit ADC as shown in FIG. 3D, or a plurality of integrators 324 as shown in FIG. 31, and multiple simulations.
- the conversion circuit ADC is composed of a switching circuit 370, and may also be composed of a plurality of integrators 324, a switching circuit 370 and an analog conversion circuit ADC as shown in FIG.
- the measurement circuit measures the second level difference signals at one or more time points to generate the sensing information. For example, as shown in Fig. 3D or Fig. 3J, the second level difference signals are measured at a plurality of time points, or as shown in Fig. 31, the second level difference signals are measured at a time point.
- the signal subtraction and measurement are simultaneously performed by the differential integrator 324, wherein the signal measurement can further include generating a digital value by the analog conversion circuit ADC.
- the foregoing related illustrations and descriptions are only one of the examples of the present invention, and are not intended to limit the present invention. Those skilled in the art may infer that signal subtraction and signal measurement may be performed by different circuits, for example, by a subtraction method. The device passes through an integrator and will not be described here.
- each value of the sensing information is generated by one of the second level difference signals, and each of the second level difference signals is respectively determined by the pair of first level differences.
- Generating a first difference signal and a second difference signal of the signal wherein the first difference signal is generated according to signals of a first sensor and a second sensor of the sensors, respectively, and The two difference signals are generated according to the signals of the second sensor and the third sensor of the sensors, respectively.
- each value of the sensed information corresponds to the signal of three of the sensors.
- the sensing information may be obtained by a differential circuit
- the differential circuit includes: one or more subtractors and a measuring circuit, such as shown in FIG. 3C, FIG. 3G or FIG. 3H. .
- each of the subtractors generates a difference signal based on the signals of a pair of sensors, respectively.
- the measurement circuit measures the difference signals to generate a differential sensing information, wherein each value of the sensing information is a difference between a pair of values of the differential sensing information.
- the measurement circuit measures the second level difference signals at one or more time points to generate the sensed information. For example, as shown in Fig. 3C or Fig. 3H, these second level difference signals are measured at a plurality of time points, or as shown in Fig. 3G, the second level difference signals are measured at a time point.
- each value of the sensing information is a difference between a first difference and a second difference of the differential sensing information, wherein the first difference is a first sensor according to the sensors respectively.
- the first difference is a first sensor according to the sensors respectively.
- the second difference is generated according to the signals of the second sensor and the third sensor of the sensors, respectively.
- each value of the sensed information corresponds to the signal of three of the sensors, respectively.
- the sensing information may be obtained by a measuring circuit as shown in Fig. 3B, Fig. 3E or Fig. 3F.
- the measuring circuit measures the signals of the sensors at one or more time points to generate an initial sensing information, and the sensing information is generated according to the initial sensing information, wherein each value of the sensing information is respectively initiated by Three values of the sensed information are generated.
- the measurement circuit measures the second level difference signals at one or more time points to generate the sensed information. For example, as shown in Fig. 3B or Fig. 3F, these second level difference signals are measured at a plurality of time points, or as shown in Fig. 3E, the second level difference signals are measured at a time point.
- Each value of the sensing information is a difference or sum of a first difference value and a second difference value, wherein the first difference value is a difference between the first two values of the three values of the initial sensing information, and The difference is the difference between the last two values of the three values of the initial sensing information.
- the three values of the initial sensing information are a first value, a second value, and a third value, respectively, and each value of the sensing information is (second value - first value H third value, respectively) - second value), (first value - second value M second value - third value), (second value - first value) + (second value - first value) or (first value - first Binary) + (third value - second value).
- Each of the aforementioned initial sensing information is generated based on a signal from one of the sensors, in other words, each value of the sensing information corresponds to a signal of three of the sensors, respectively.
- each touch-sensing information in the sensing information has two zero-crossing points, and the position at which the external object approaches or touches is determined based on each of the touch-related sensing information.
- the touch-related sensing information is located at the foremost part or the last part of the sensing information, and the external object only partially approaches or touches the active area edge of the sensing device, instead of two At the zero-crossing office, an exception is required.
- the aforementioned points in time may include, but are not limited to, portions passing through one or more clocks, or one or more clocks.
- the acquisition and generation of the sensing information may be performed by the controller 160, and the double differential circuit, the differential circuit, and the measuring circuit may be implemented by the controller 160.
- the senor may be composed of a plurality of conductive sheets and connecting wires, for example, a plurality of connecting wires are connected in series with a series of diamond-shaped or square conductive sheets.
- the conductive sheets of the first sensor i 40A and the second sensor 140B may be arranged in different planes, or may be arranged in the same plane.
- the first and second sensing layers 120A, 120B are separated by an insulating layer or a piezoresistive layer, wherein the piezoresistive layer may be composed of an anisotropic conductive paste.
- the conductive strips of the first sensor 140A and the second sensor 140B are substantially aligned in a same plane, and the connecting wires of the first sensor 140A straddle the connecting wires of the second sensor 140B.
- a spacer may be disposed between the connecting wire of the first sensor 140A and the connecting wire of the second sensor 140B, and the spacer may be made of an insulating material or a piezoresistive material.
- each sensor senses a sensing range and is sensed by a plurality of sensors including a plurality of first sensors and a plurality of a second sensor, the sensing ranges between the first sensors are parallel, and the sensing ranges between the second sensors are parallel, and the parallel sensing ranges of the first and second sensors overlap to form a An array of overlapping regions.
- the first and second sensors are two rows of infrared receivers arranged in a horizontal direction and a longitudinal direction, respectively, respectively sensing a parallel scanning range of direct and horizontal, and the straight and horizontal parallel scanning ranges are interlaced to form a cross. Overlay array.
- the parallel and horizontal parallel scan ranges described above are implemented by a plurality of capacitive or resistive overlapping sensors.
- Conversion of Touch Sensitive Information The signal values, difference values, and double differences of the above sensing information can be converted to each other.
- continuous signal values are converted into continuous difference values, each difference being a difference between a pair of adjacent or non-adjacent signal values.
- continuous signal values are converted into continuous double differences, each double difference being a difference sum or difference between two pairs of signal values.
- > is to convert successive differences into continuous signal values, and each difference is added to all previous or subsequent differences to generate corresponding signal values, which constitutes continuous Signal value.
- continuous double difference values are converted into continuous signal values.
- each double difference plus all previous double differences is used to generate a corresponding difference, which constitutes a continuous difference, and then subtracts all subsequent differences from each difference.
- each double difference value is subtracted from each of the double difference values to generate a corresponding difference value, which constitutes a continuous difference value, and then each difference is added to all subsequent differences. The values are used to generate corresponding signal values that form a continuous signal value.
- All of the aforementioned plus or double difference values may be sequentially or backwardly accumulated or subtracted to sequentially generate corresponding signal values or differences.
- the above-mentioned conversion methods include, but are not limited to, conversion of one-dimensional sensing information. Those skilled in the art can deduce that the above-mentioned conversion method can also be applied to two-dimensional sensing information or sensing information of three-dimensional or higher. Moreover, one of ordinary skill in the art can deduce the above conversions
- the mode of operation may be performed by the aforementioned controller 160 or the host 170.
- the position analysis can be a determination including, but not limited to, the proximity and touch of an external object, that is, the determination of the corresponding position of the external object includes, but is not limited to, the judgment of the proximity and touch of the external object.
- a pair of adjacent difference values including a positive value and a negative value are searched, that is, a pair of positive and negative values on both sides of the zero intersection, and then the pair of adjacent differences are determined.
- the position of the zero crossing for example, based on the pair of adjacent differences produces a slope to determine the zero crossing. In addition, it may be based on the order of occurrence of positive and negative values to match the judgment of the zero crossing at the adjacent difference.
- the pair of neighboring differences described above may be adjacent differences, and may also include non-adjacent differences of at least one zero value in between.
- the pair of adjacent positive and negative values may be searched in a predetermined ranking order, for example, searching for a pair of adjacent positive and negative values in which a positive value occurs first and then a negative value occurs.
- a threshold value corresponding to a positive value is generated by a threshold value, for example, a difference value smaller than a threshold value (such as a positive threshold value) is represented by 0 or a false value (false), and is greater than a threshold value.
- the difference is represented by 1 or true (true), with 1 position of the adjacent difference of 10 or the true value of the true value and the false value as the starting position, and the search direction of the zero crossing is the backward search.
- the difference value greater than the threshold value may be represented by 0 or a false value (false)
- the difference smaller than the threshold value is represented by 1 or a true value (true) to The one with the neighbor difference of 01 or the true value of the true value and the pseudo value is the starting position, and the search direction of the zero intersection is the forward search.
- Table 1 and Figure 4A are examples of determining the proximity or touch of an external object by the threshold value. Table I
- a binarization value corresponding to a negative value is generated with a second threshold value, for example A difference greater than the threshold value is represented by 0 (or a pseudo value), and a difference smaller than the threshold value is represented by 1 (or a true value), and an adjacent two points having a difference of 01 is an end position.
- the starting position and the ending position are paired to determine the interval at which the zero crossing is searched.
- the starting position is as
- the interval of the first search zero-crossing after pairing is between the fourth and fifth differences
- the interval of the second search zero-crossing after pairing is the tenth. Between the 12th difference.
- the scan of the positive threshold and the scan of the negative threshold can be performed simultaneously (or parallel processing:), and the pairing of the intervals can also be determined after the initial position is determined. The end position judged later.
- the starting position determined according to the positive threshold value is a backward search for the zero-crossing point.
- the starting position judged by the negative threshold is the forward search zero crossing, and vice versa.
- the proximity or touch corresponding to the same external object does not necessarily determine the starting position when scanning with the positive threshold and the negative threshold.
- a second position analysis provided by the present invention analyzes the centroid position (center of gravity position or weighted average position) as a corresponding position of an external object based on a plurality of signal values or double differences in the sensing information.
- a threshold value is used to determine a signal for determining a centroid position. Value or double difference.
- a binarization value corresponding to a signal value or a double difference value may be generated with a threshold value, for example, a signal value smaller than a threshold value or a double difference value of 0 or a false value (false ), and the signal value or double difference greater than the threshold value is represented by 1 or true (true).
- the signal value or double difference represented by 1 or true value is the signal value or double difference for judging the centroid position.
- the plurality of signal values or double differences adjacent to each other are signal values or double differences for determining the position of the centroid.
- the signal values represented by adjacent consecutive 1 or true values or the relative central signal values or double differences in the double difference are taken forward and backward respectively to take i and j signal values or double difference values for Determine the signal value or double difference of the centroid position.
- the zero crossing is analyzed by the continuous difference, and the continuous difference is converted into a continuous signal value or a double difference, and then the corresponding signal value or double difference at the zero crossing is analyzed.
- the value is taken as the central signal value or double difference, and then the i or j signal values or double differences are taken forward and backward as the signal value or double difference for determining the centroid position, respectively, with the central signal value or the double difference value. value.
- a one-dimensional coordinate such as X coordinate or Y coordinate
- a two-dimensional coordinate such as (X, Y)
- DD k D k ⁇
- nth double difference /) Z forward and backward respectively take i and j double differences as centroid calculation Range, according to each double difference in the centroid calculation range, judge the centroid position D) f , , as follows »+./
- the third position analysis analyzes the centroid position (center of gravity position or weighted average position) as a corresponding position of the external object according to the plurality of differences in the sensing information.
- the centroid position can be obtained according to the difference between the signal values, wherein the difference in the centroid calculation range is ⁇ - ⁇ , / ⁇ ,..., ⁇ , / ⁇ ,..., / ⁇ ⁇ in other words,
- the centroid position C... can be calculated as the difference in the centroid calculation range. For example, the following example assumes that 1 signal value is taken forward and backward with the nth signal value. To determine the centroid position (c.), you can calculate the range of centroids
- i and j signal values, difference values, or double difference values are taken forward and backward respectively as the nth signal value, the difference value, or the double difference value as the centroid calculation range.
- the method can be applied to determine the signal value, difference value, or double difference value of the centroid position, and vice versa. It can be inferred from the above description that the present invention performs position by analyzing the sensing information.
- the detection, the sensing information includes but is not limited to the initially obtained signal value, the difference value or the double difference value, and may also include, but is not limited to, a signal value, a difference value or a double difference value converted by the initially obtained sensing information.
- the position (or coordinates) of the external object in two different axial directions can be obtained, forming a two-dimensional position (or two-dimensional coordinates).
- the above-described one-dimensional position analysis job can be performed by the aforementioned controller 160 or the host 170.
- the two-dimensional sensing information may be composed of a plurality of one-dimensional sensing information, wherein each one-dimensional sensing information includes sensing information corresponding to a plurality of first one-dimensional positions, and each one-dimensional sensing information is respectively Corresponds to the position of a second dimension. Therefore, the two-dimensional position analysis may include at least one-dimensional position analysis for the plurality of one-dimensional touch-sensitive resources, that is, the two-dimensional position analysis may include at least a plurality of one-dimensional position analysis.
- the first one-dimensional centroid position of each external object in each first dimension sensing information is a two-dimensional position (eg, a two-dimensional coordinate (first first-dimensional centroid)
- the position, the position of the second dimension of the first dimension sensing information) can be used to calculate the two-dimensional centroid position (or geometric center) of the external object, wherein the weighting value of each one-dimensional centroid position can be an external object
- the signal value or double difference in the sensing information of the first dimension of the mandarin such as one of the two signal values or double differences of the nearest neighboring one-dimensional centroid position on the first dimension sensing information or its average value, interpolation value ), or the sum of the signal values or double differences of the external objects on the corresponding first dimension sensing information.
- the two-dimensional position analysis may be a first-order position of sensing information for each first dimension.
- the analysis analyzes the two-dimensional centroid position of each external object according to at least one two-dimensional position corresponding to each external object.
- the two-dimensional position analysis may include performing one-dimensional position analysis on the plurality of one-dimensional sensing information on a first axial direction (or the first one dimension), respectively. At least one dimension position of the outer object in the first axial direction divides the first one-dimensional centroid position of each outer object in the first axial direction.
- another one-dimensional position analysis is performed on the plurality of one-dimensional sensing information in a second axial direction (or the second dimension), according to at least one dimension position corresponding to each external object in the second axial direction. And analyzing a second-dimensional centroid position of each external object in the second axial direction.
- the two-dimensional position analysis may be performed by two-dimensional sensing information (such as two-dimensional sensing information in the first axial direction and two-dimensional sensing information in the second axial direction) of two different axial directions. Dimensional position analysis to analyze the two-dimensional position of each external object.
- the two-dimensional position analysis may be a plurality of one-dimensional sensing information analysis in a first axial direction. And determining, according to the one-dimensional centroid position of each external object, the two-dimensional position corresponding to each one-dimensional centroid position of each external object in the first axial direction according to the corresponding two-dimensional position of each dimension sensing information.
- Dimensional position analysis additionally analyzes a one-dimensional heart position corresponding to each external object in a plurality of one-dimensional sensing information in a second axial direction, and senses a corresponding two-dimensional position according to each dimension Determining a two-dimensional position corresponding to each one-dimensional centroid position of each external object in the first axial direction.
- the two-dimensional position analysis is further based on all the dimensions of each external object in the first and second axial directions.
- the two-dimensional position of the centroid position is analyzed to obtain a two-dimensional centroid position.
- the two-dimensional sensing information can determine the position of each external object through the image processing program, for example, a watershed algorithm can be used. Or other image processing for position analysis.
- the watershed algorithm can be used to analyze the points.
- the position of the water collar is calculated by the sensing information adjacent to the position of each water-collecting collar to obtain a more accurate position.
- the initially obtained plurality of one-dimensional sensing information is represented by a signal value or a double difference, and constitutes an image (or array) presented by a two-dimensional sensing information, which may be a watershed.
- Algorithm or other image processing for position analysis It is also possible to use a connected component algorithm to analyze the connected portions of the image to determine the image of each external object, and to further analyze the location or which external object, such as a hand, palm or pen.
- the initially obtained plurality of one-dimensional sensing information is represented by a difference value, and then converted into a signal value or a double difference to form an image presented by the two-dimensional sensing information (or Array), which can be location analysis using a watershed algorithm or other image processing.
- the initially obtained plurality of one-dimensional sensing information is represented by a difference, and the position of each zero-crossing is determined by analyzing the position of each one-dimensional sensing information. And the signal value or double difference at the position of each zero intersection to form an image (or array) presented by the two-dimensional sensing information, which may be a watershed algorithm or other image processing for position analysis.
- the double difference at the zero crossing can be generated by two directly adjacent differences.
- the zero intersection is between the k-1th difference and the kth difference
- the signal value at the zero crossing may be generated by converting the difference representing the entire one-dimensional sensing information into a signal value, or may be generated by a plurality of differences closest to the zero intersection.
- the nth signal value at the zero-crossing point is taken as the n-th signal value forward and backward, respectively, and the ith signal value cradically_,.
- the initially obtained plurality of one-dimensional sensing information is represented by a signal value and a double difference value, and then converted into a difference value, and is determined by analyzing a position of each one-dimensional sensing information.
- the position of each zero intersection, matching the signal value or double difference at the position of each zero intersection, to form an image (or array) presented by the two-dimensional sensing information which may be a watershed algorithm or Other image processing for position analysis.
- the one-dimensional sensing information in the second axial direction is also obtained during the same or during the acquisition of the two-dimensional sensing information in the first axial direction.
- a one-dimensional position or a two-dimensional position of each of the external objects in the first axial direction can be obtained.
- # ⁇ After performing the position analysis of the one-dimensional sensing information on the second axial direction, the - dimensional position of each external object in the second axial direction can be obtained.
- the one-dimensional position in the second axial direction may be paired with the one-dimensional position in the first axial direction to become a two-dimensional position, and may also be used to replace or correct the second axial direction in the two-dimensional position in the first axial direction. position.
- a one-dimensional distance or two-dimensionality corresponding to a one-dimensional centroid position of the same external object approaching or touching and at least one other one-dimensional centroid position corresponding to the proximity or touch of the same outer object The distance is within a threshold.
- the weighted value of each dimension centroid position corresponding to the proximity or touch of the same external object is greater than a threshold value.
- the touch-related sensing information may be one of the touch-related sensing information or the plurality of touch-related sensing information in the sensing information, and the related operation for the touch-related sensing information. This includes, but is not limited to, application to specific touch-related sensing information, and may also be applied to all touch-related sensing information applicable to the present invention.
- the position of the zero crossing may be determined by a pair of positive and negative values of the touch related sensing information.
- the zero-crossing is located between a positive value and a negative value. From the positive and negative values and the relative position, a slope can be obtained. According to the slope, the position of the zero-crossing can be estimated, that is, the positive and negative values are determined according to the slope.
- the connection is at a zero value.
- the pair of positive and negative values may be determined by a positive threshold value Tp and a negative threshold value Tn, respectively, as shown in FIG. 5A, and the positive value may be located at point a, point. b, or the value closest to point a (such as the N+1th difference) or the value closest to point b (such as the N+3th value).
- the negative value can be the value at point c, point d, or the closest point c (such as the N+4 difference) or The value closest to point d (such as the N+6th value).
- the positive value is the N+3 value
- the negative value is the N+ 4 value. From the virtual line between the high point of the positive value and the low point of the negative value, a slope can be determined, which can be calculated according to the slope. This line is at the zero value, ie zero intersection Z.
- the position of the zero crossing may be judged by the maximum value (positive peak) and the lowest point (negative peak) of the touch-related sensing information, as shown in Fig. 5B. From the maximum and minimum values and the relative position, a slope can be obtained. Based on the slope, the position of the zero intersection can be estimated, that is, the line between the maximum value and the minimum value is determined to be at the zero value according to the slope.
- the touch-related sensing information is located between the Nth difference and the N+6th difference, and the maximum value and the minimum value are the N+2 difference and the N+5 difference, respectively.
- a line and the slope of the line can be virtualized between the high point of the value and the low point of the minimum value.
- the zero crossing is assumed to be at the zero value of the line, which can be calculated based on the slope.
- the aforementioned maximum value and minimum value may be determined by the aforementioned threshold value.
- the positive threshold value Tp and the negative threshold value ⁇ may be fixed or dynamically adjusted, and the maximum value and the minimum value respectively protrude from the positive threshold value.
- Tp and negative threshold Tn It is also possible to obtain a positive group greater than the positive threshold Tp and a negative group smaller than the negative threshold ⁇ ⁇ according to the positive threshold Tp and the negative threshold Tn, respectively, and the positive group and the negative group respectively
- the value group determines the maximum and minimum values.
- the touch-related sensing information in a sensing information may be one or more, that is, the sensing device may be approached or touched by one or more external objects. For example, as shown in FIG.
- the sensing information includes two touch-related sensing information, and each touch-related sensing information can determine a positive group according to the positive threshold Tp and the negative threshold Tn (or The maximum value is associated with a negative value group (or minimum value), and the zero intersections Z1 and Z2 are further determined.
- the judgment of the zero-crossing meeting includes, but is not limited to, determining the position and number of zero-crossings.
- the judgment of the zero-crossing is also equivalent to judging the proximity or touch of several external objects.
- FIG. 5C e.g. two zero intersection is judged, it is determined that proximity is also equal to two external object or touching 0
- the upper curve is the signal value
- the lower polyline is the corresponding difference, as observed by the curve.
- the zero-crossing is determined based on the rising and falling sequence of each pair of positive and negative values. For example, only the zero intersection between each positive value and the negative value of the negative value after the positive value is judged, and the zero intersection between each positive value and the negative value of the positive value after the negative value is not determined. Or, only the zero intersection between each positive value and the negative value of the positive value after the negative value is judged, and the zero intersection between each positive value and the negative value of the negative value after the positive value is not determined. As shown in Fig. 5D, it is only the zero intersection between each positive value and the negative value of the negative value after the positive value is determined, so that two zero intersections can be judged. That is, when a single object approaches or touches, and the touch-related sensing information is positive and negative, only the first positive The value of each negative value of each pair of positive and negative zero intersections, and vice versa.
- the present invention can analyze the position where each external object approaches or touches at the touch-related sensing information having a plurality of zero-crossing points, and the present invention can be a touch-related sense at an odd number of zero-crossing points.
- the measurement information analyzes the position where each external object approaches or touches, and the number of positions analyzed is different from the number of zero intersections.
- the number of positions analyzed in the foregoing is different from the number of zero intersections including but not limited to the number of zero intersections larger than the number of positions analyzed, or the number of zero intersections is smaller than the number of analyzed positions, for example, by a touch with a single zero intersection.
- the sensing information determines the proximity or touch of two external objects.
- the first sensor 1 that exceeds the preset range is obtained from the signal values of the plurality of sensors by using a predetermined range, and the first one does not reach the preset range.
- the previous sensor J1 of the sensor J calculates two centroids or geometric centers according to the sensor ⁇ and the sensor J-1 to calculate two positions.
- the centroid or geometric center is calculated based on the average of the signal values of the ⁇ sensors on either side of a sensor.
- the coordinates are calculated as the sum of the ((signal value - base value) * coordinate value) of each sensor in the K-1th sensor on both sides of the sensor divided by the distance on both sides of the sensor.
- sensors 1-11 there are 11 sensors, including sensors 1-11.
- the signal values of sensors 1 ⁇ 11 are (0,0,0,3,4,4,5,3,0,0,0), and the difference is (0,0,3, respectively).
- the preset range is 1.9 to -1.9, so the aforementioned sensor I and sensor J-1 are the sensor 4 and the sensor, respectively 7.
- the coordinates of the sensor 4 is calculated according to the average value of the second sensor on both sides of the sensor 4, which is 0 of the sensor 2 and 4 of the sensor 6, respectively, and the average value thereof is 2, so the coordinates are 5.17 (0*3.5+1*4.5+2*5.5)/(0+1+2), and similarly, the coordinate value corresponding to the sensor 7 is 6.33, and the distance between them is 1.17. .
- the sensor 1 and the sensor J-1 are the sensor 4 and the sensor 7, respectively, and the coordinates of the sensor 4 and the sensor 7 are 5.5 and respectively. 6.04, the distance between the two is 0.54. Therefore, when the first threshold value is 0.8, it can be discerned that FIG. 6A is a two-finger touch, and FIG. 6B is a single finger touch.
- Fig. 6A it is possible to use 5.17 and 6.33 as the positions where the two fingers touch.
- the average of 5.5 and 6.04 or the position of the zero intersection may be used as the position of the single-finger touch. Comparing FIG. 6A with FIG. 6B, although the number of values of the touch-related sensing information is the same and both have a single zero-crossing, the judging method provided according to the present invention can effectively distinguish the touch-related sensing information. Single-finger touch or two-finger touch.
- the manner of determining the sensor I and the sensor J-1 or J is only for the purpose of the present invention, and is not used. In order to limit the present invention, those skilled in the art can infer that other two locations are determined by the touch-related sensing information, and then according to the centroid position or geometric center distance of the touch-sensitive sensing information. To determine whether it is a single-finger touch or a two-finger touch.
- the sensor I and the sensor J are respectively the Kth sensor from the touch-related sensing information.
- the sensor I and the sensor J are determined according to a pair of zero-crossings of the double differential sensing information, such as according to the signal value of the corresponding zero-crossing, or corresponding to the zeroth of the zero-crossing. Signal value.
- the manner in which the two locations are determined by the touch-related sensing information may vary depending on the distance between the sensors, the signal characteristics, the thickness of the carrier or substrate on which the sensor is disposed.
- FIG. 7 is a method for analyzing a position according to a first embodiment of the present invention.
- a sensing information is obtained.
- the sensing information includes at least one zero-crossing meeting, wherein each zero-crossing is located between a positive value and a negative value.
- a plurality of different locations from the zero intersection are analyzed from the sensing information. In other words, in addition to the number of zero-crossings equal to the number of external objects approaching or touching, each position is analyzed, and even if the number of zero-crossings is not equal to the number of external objects approaching or touching, each analysis is analyzed. -- A location.
- the number of zero crossings can be greater or less than the number of locations analyzed. For example, a zero intersection of each odd position is judged from an odd number of zero intersections to analyze a position less than the number of zero intersections.
- the touch-related sensing information at the single zero-crossing can be judged to be a proximity or touch of a single object (e.g., one-touch), or a proximity or touch (e.g., two-touch) of multiple objects. -'
- the number of zero-crossing points can also be an even number.
- the sensing information is double-differential sensing information, and each position is analyzed based on the peak between a pair of zero-crossings or a pair of zero-crossings.
- the sensing information may be generated based on signals of a plurality of sensors.
- the sensing information is differential sensing information, and each value of the differential sensing information is generated based on signals of a pair of sensors in the sensors.
- the sensing information is double differential sensing information, and each value of the double differential sensing information is generated based on signals of three of the sensors.
- the sensing information may be generated based on another sensing information composed of a plurality of signal values, a plurality of differences, or a plurality of double differences (such as the conversion of the sensing information described above).
- the foregoing steps 710 and 720 may be performed by the controller 160 or the host 170.
- the sensor may be obtained by the controller 160 to generate another sensing information according to the signals of the plurality of sensors, and then the controller 160 or the host 170 according to another sensed information conversion step 710. Measurement information.
- Other related details of the present embodiment have been disclosed in the foregoing description and will not be described again.
- a sensing information is obtained.
- the sensor may be generated by the controller 160 according to the signals of the plurality of sensors, or may be controlled by the controller 160.
- the controller 160 or the host 170 converts the sensing information described in the step 810.
- At least one first starting position is determined in the sensing information according to a first threshold value.
- a first threshold value For example, Figures 5A and 5C and related descriptions are shown.
- a zero-crossing position analysis is performed from each of the first starting positions toward a first range of the first direction to respectively determine the position of a zero-crossing point, wherein each zero-crossing point Located between a positive value and a negative value.
- At least one first starting range is determined by a first threshold value, and each first starting position is located within a first starting range or a maximum value within the first starting range, and the first The value, or the last value.
- the first range may be the previous value from the first starting position to the zero crossing, the zero crossing, or the next value at the zero crossing.
- the first starting range including the point a, the maximum value, and the point b is determined by the positive threshold Tp
- the first starting position may be the point a, the maximum value, or the point b.
- the first direction may be backward, and the first range is the first start position backward to the first sign value (negative value) or zero value.
- the position of the zero crossing is analyzed based on the first different value and another value adjacent to the zero crossing.
- the position of the zero-crossing is analyzed based on a pair of positive and negative values adjacent to the zero-crossing.
- the position of each zero intersection is used as the position of the at least one external object, or the position corresponding to one of the at least one external object is determined by the position of each zero intersection.
- a centroid position or geometric center is calculated as the position of each of the at least one external object based on the position of each zero intersection.
- the centroid position or the geometric center may be based on the position of the zero intersection, which may be calculated directly from the sensing information, or may be calculated by using a plurality of signal values corresponding to the sensing information and a plurality of double differences.
- the present invention further includes determining, according to steps 840 and 850, at least one second starting position in the sensing information according to a second threshold value, and from each of the first starting positions to a second A second range of directions performs a zero crossing location analysis to determine the location of the zero crossing, respectively.
- At least one second starting range is determined by a second threshold value, and each second starting position is located within a second starting range or a maximum value within the second starting range. Value, the first value, or the last value.
- the second range may be the previous value from the second starting position to the zero crossing, the zero crossing, or the next value at the zero crossing.
- the second starting range including the point a, the maximum value, and the point b is determined by the positive threshold value Tp
- the second starting position may be the point a, the maximum value, or the point b.
- the second direction may be backward, and the second range is the second start position backward to the first sign value (negative value) or zero value.
- the second threshold range including the point is determined by the positive threshold value Tn, and the second starting position may be the point 0, the minimum value or the point d.
- the second direction may Is forward, and the second range is the second starting position forward to the first sign value (positive value) or zero value.
- the second threshold range or the second start is determined by the second threshold value. The location may be performed in a manner previously described using binarized values, as described in Figure 4A and related description.
- one of the first threshold value and the second threshold value is a positive value, and the other of the first threshold value and the second threshold value is a negative value. Further, the first direction is opposite to the second direction.
- the foregoing steps 810 to 850 are applied to the sensing information or the touch-related sensing information with an odd number of zero-crossings, and the analyzed zero-crossing is the zero-crossing of the odd-numbered positions.
- the zero-crossing of the odd-numbered positions refers to the zero-crossing of odd-numbered positions that appear sequentially in all zero-crossings.
- the foregoing steps 810 to 850 may be performed by the controller 160 or the host 170.
- the sensor may be obtained by the controller 160 to generate another sensing information according to the signals of the plurality of sensors, and then the controller 160 or the host 170 according to another sensed information conversion step 810. Measurement information.
- Other related details of the present embodiment have been disclosed in the foregoing description and will not be described again.
- FIG. 9 is a method for detecting a finger touch in a sensing device according to a third embodiment of the present invention.
- a sensing information is obtained.
- step 920 it is determined whether there is a positive value greater than the positive threshold in the sensing information according to a positive threshold.
- step 930 it is determined whether there is a negative value smaller than the negative threshold in the sensing information according to a negative threshold.
- step 940 when there is a positive value greater than the positive threshold and a negative value less than the negative threshold, it is determined that the zero crossing between the positive value greater than the positive threshold and the negative value less than the negative threshold.
- the zero intersection is a touched position
- the number of zero intersections is the number of touches.
- the judgment of the zero-crossing meeting may be to determine that the zero-crossing between the first positive and negative values is positive, and the first positive and negative values are positive and negative, and the judgment of the zero-crossing may be Including not determining the zero intersection between a second pair of positive and negative values, the second pair of positive and negative values are first negative and then positive.
- the judgment of the zero-crossing can be judged to be located at a zero-crossing between the first positive and negative values, and the first positive and negative values are negative and positive, and the judgment of the zero-crossing can be Is included without judging the zero crossing between a second pair of positive and negative values Where, the second positive and negative values are positive and negative.
- the foregoing steps 910 through 940 may be performed by the controller 160 or the host 170.
- the sensor may be obtained by the controller 160 to generate another sensing information according to the signals of the plurality of sensors, and then the controller 160 or the host 170 according to another sensed information conversion step 910.
- Measurement information For example, the sensing information is generated by the controller 160 based on signals from a plurality of sensors, and each of the values of the sensors is generated based on signals of a pair of the sensors, respectively.
- the sensing information is generated based on a plurality of signal values, and the signal values are generated by the controller 160 according to signals of the plurality of sensors.
Landscapes
- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Theoretical Computer Science (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Human Computer Interaction (AREA)
- Measurement Of Length, Angles, Or The Like Using Electric Or Magnetic Means (AREA)
- Position Input By Displaying (AREA)
Description
分析位置的方法与装置 技术领域
本发明涉及一种分析位置的方法与装置,特别是涉及一种依据具零交 会处的感测资讯进行位置分析的方法与装置。 坟不
触控显示器 (Touch Display)己广泛地应用于许多电子装置中, 一般的做 法是采用一触控面板 (Touch Sensing Panel)在触控显示器上定义出一二维的 触摸区, 借由在触摸板去上纵轴与横轴的扫瞄来取得感测资讯 (Sensing Information), 以判断外在物件 (如手指)在触摸屏上的碰触或接近,例如美国 专利号 US4639720所提供的一种电容式触摸显示器。
感测资讯可由模拟数字转换器 (Analog-to-Digital Converter, ADC)转换 为多个连续信号值, 借由比较这些信号值在外部物件碰触或接近前与后的 变化量, 可判断出外部物件碰触或最接近触摸屏的位置。
一般而言, 控制触摸屏的控制器会先取得没有外部物件触碰或接近时 的感测资讯, 作为基准值 (baseline)。 例如在电容式触摸屏中, 每一条导电 条相应于各自的基准值。 控制器借由判断后续的感测资讯与基准值的比较 判断是否有外部物件接近或触碰, 以及更进一步判断外部物件的位置。 例 如, 在未被外部物件接近或触碰时, 后续的感测资讯相对于基准值为零值 或趋近零值, 借由感测资讯相对于基准值是否为零值或趋近零值判断是否 有外部物件接近或触碰。
如图 1A所示, 当外部物件 12(如手指)碰触或接近触控显示器 10的感 测装置 120时,在一轴向 (如 X轴向)上的感测器 140的感测资讯转换成如图 1B所示的信号值,相应于手指的外型,信号值呈现一波形或一指廓 (Finger profile), 指廓上的峰 14(peak)的位置即代表手指碰触或接近的位置。
然而, 当多个触碰较接近时,相应于这些触碰的信号值将聚集在一起,尤 其是两个触碰的路径交错而过时。 在许多时候, 单凭一门槛限值无法判断 出是单一触碰, 还是多触碰。 而造成位置判断上的困难。
由此可见, 上述现有的分析位置的方法与装置在方法、 产品结构及使 用上, 显然仍存在有不便与缺陷, 而亟待加以进一步改进。 为了解决上述 存在的问题, 相关厂商莫不费尽心思来谋求解决之道, 但长久以来一直未 见适用的设计被发展完成, 而一般方法及产品又没有适切的方法及结构能 够解决上述问题, 此显然是相关业者急欲解决的问题。 因此如何能创设一 种新的分析位置的方法与装置, 实属当前重要研发课题之一, 亦成为当前
业界极需改进的目标。
有鉴于上述现有的分析位置的方法与装置存在的缺陷, 本发明人基于 从事此类产品设计制造多年丰富的实务经验及专业知识, 并配合学理的 '运 用, 积极加以研究创新, 以期创设一种新的分析位置的方法与装置, 能够 改进一般现有的分析位置的方法与装置, 使其更具有实用性。 经过不断的 研究、 设计,并经过反复试作样品及改进后, 终于创设出确具实用价值的本 发明。 发明内容
本发明的主要目的在于, 克服现有的分析位置的方法与装置存在的缺 陷, 而提供一种新的分析位置的方法与装置, 所要解决的技术问题是使其 在具有零交会处的触碰相关感测判断出每一个触碰位置, 非常适于实用。
本发明的另一目的在于, 克服现有的分析位置的方法与装置存在的缺 陷, 而提供一种新型的分析位置的方法与装置, 所要解决的技术问题是使 其在触碰的数目与零交会处的数目相同时, 判断出每一个位置, 从而更加 适于实用。
本发明的再一目的在于, 克服现有的分析位置的方法与装置存在的缺 陷, 而提供一种新的分析位置的方法与装置, 所要解决的技术问题是使其 在触碰的数目与零交会处的数目不同时, 判断出每一个位置, 从而更加适 于实用。
本发明的还一目的在于, 克服现有的分析位置的方法与装置存在的缺 陷, 而提供一种新型的分析位置的方法与装置,'所要解决的技术问题是使 其在触碰相关感测资讯中判断奇数字置零交会处; 及依据正门槛限值与负 门槛限值来判断零交会处, 从而更加适于实用, 且具有产业上的利用价值。
本发明的目的及解决其技术问题是采用以下技术方案来实现的。 依据 本发明提出的一种分析位置的方法, 其包括以下步骤:
取得一感测资讯, 该感测资讯包括至少一个零交会处, 其中每一个零 交会处位于一正值与一负值间; 以及
由该感测资讯分析出与该至少一零交会处不同数量的多个位置。
本发明的目的及解决其技术问题还可采用以下技术措施进一步实现。 前述的分析位置的方法, 其中所述的至少一零交会处的数量大于该至 少一位置的数量。
前述的分析位置的方法, 其中所述的零交会处为奇数个。
前述的分析位置的方法, 其中所述的至少一位置是依据位于奇数位置 的零交会处分析出来。
前述的分析位置的方法, 其中所述的至少一零交会处的数量为偶数个。
前述的分析位置的方法, 其中所述的至少一零交会处的数量小于该至 少一位置的数量。
前述的分析位置的方法,其中所述的至少一零交会处的数量为一个,并 且该至少一位置的数量为两个。
前述的分析位置的方法, 其中所述的感测资讯为双差动感测资讯, 该 双差动感测资讯的每一个值是依据该些感测器中的三个感测器的信号产 生。
前述的分析位置的方法, 其中所述的感测资讯为差动感测资讯,该差动 感测资讯的每一个值是依据该些感测器中的一对感测器的信号产生。
前述的分析位置的方法, 其更包括: 由该感测资讯分析出与该至少一 零交会处数量相同的至少一位置。
本发明的目的及解决其技术问题还采用以下技术方案来实现。 依据本 发明提出的一种分析位置的装置, 其包括:
一控制器或一主机, 执行下列作业:
取得一感测资讯, 该感测资讯包括至少一个零交会处, 其中每一个零 交会处位于一正值与一负值间; 以及
由该感测资讯分析出与该至少一零交会处不同数量的多个位置。
本发明的目的及解决其技术问题还可采用以下技术措施进一步实现。 前述的分析位置的装置, 其中所述的至少一零交会处的数量大于该至 少一位置的数量。
前述的分析位置的装置, 其中所述的零交会处为奇数个。
前述的分析位置的装置, 其中所述的至少一位置是依据位于奇数位置 的零交会处分析出来。
前述的分析位置的装置, 其中所述的至少一零交会处的数量为偶数个。 前述的分析位置的装置, 其中所述的至少一零交会处的数量小于该至 少一位置的数量。
前述的分析位置的装置, 其中所述的至少一零交会处的数量为一个,并 且该至少一位置的数量为两个。
前述的分析位置的装置, 其更包括: 包括多个感测器的一感测装置; 其中该感测资讯为双差动感测资讯, 该双差动感测资讯的每一个值是依据 该些感测器中的三个感测器的信号产生。
前述的分析位置的装置, 其更包括: 包括多个感测器的一感测装置; 其中该感测资讯为差动感测资讯, 该差动感测资讯的每一个值是依据该些 感测器中的一对感测器的信号产生。
前述的分析位置的装置, 其中所述的控制器或该主机, 更包括执行下 列作业: 由该感测资讯分析出与该至少一零交会处数量相同的至少一位置。
本发明与现有技术相比具有明显的优点和有益效果。 由以上可知,为达 到上述目的, 本发明提供了一种分析位置的方法与装置。 借由对包括至少 一零交会处的感测资讯进行一分析, 可分析出与零交会处不同数量的多个 位置。 当被分析出来的位置数量不同于零交会处的数量时, 分析出来的位 置数量为多个。
如前述, 当多个触碰较接近时, 相应于这些触碰的信号值将聚集在一 起, 尤其是两个触碰的路径交错而过时。 在许多时候, 单凭一门槛限值无 法判断出是单一触碰, 还是多触碰。 而造成位置判断上的困难。
本发明的目的及解决其技术问题可以采用以下技术方案来实现的。 依 据本发明提出的一种分析位置的方法, 包括: 取得一感测资讯, 该感测资 讯包括至少一个零交会处, 其中每一个零交会处位于一正值与一负值间; 以及由该感测资讯分析出与该至少一零交会处不同数量的多个位置。另 外, 依据本发明提出的一种分析位置的装置, 包括一控制器或一主机, 执 行下列作业: 取得一感测资讯, 该感测资讯包括至少一个零交会处, 其中 每一个零交会处位于一正值与一负值间; 以及由该感测资讯分析出与该至 少一零交会处不同数量的多个位置。
本发明的目的及解决其技术问题还可采用以下技术方案来实现的。 依 据本发明提出的一种分析位置的方法, 包括: 取得一感测资讯; 依据一第 一门槛限值在该感测资讯中决定至少一第一起始位置; 以及由每一个第一 起始位置朝一第一方向的一第一范围进行一零交会处位置分析以分别判断 出一零交会处的位置, 其中每一个零交会处位于一正值与一负值间。 此 外, 依据本发明提出的一种分析位置的装置, 包括一控制器或一主机, 执 行下列作业: 取得一感测资讯; 依据一第一门槛限值在该感测资讯中决定 至少一第一起始位置; 以及由每一个第一起始位置朝一第一方向的一第一 范围进行一零交会处位置分析以分别判断出一零交会处的位置, 其中每一 个零交会处位于一正值与一负值间。
本发明的目的及解决其技术问题还可采用以下技术方案来实现的。 依 据本发明提出的一种在感测装置侦测指触的方法, 包括: 取得一感测资讯; 依据一正门槛判断该感测资讯中是否存在大于正门槛的正值; 依据一负门 槛判断该感测资讯中是否存在小于负门槛的负值; 以及当存在大于正门槛 的正值与小于负门槛的负值时判断位于大于正门槛的正值与小于负门槛的 负值间的零交会处。 另外, 依据本发明提出的一种在感测装置侦测指触的 装置, 包括一控制器或一主机, 执行下列作业: 取得一感测资讯; 依据一 正门槛判断该感测资讯中是否存在大于正门槛的正值; 依据一负门槛判断 该感测资讯中是否存在小于负门槛的负值; 以及当存在大于正门槛的正值 与小于负门槛的负值时判断位于大于正门槛的正值与小于负门槛的负值间
的零交会处。
借由上述技术方案, 本发明分析位置的方法与装置至少具有下列优点 及有益效果:
一、 在感测资讯呈现的零交会处少于实际触碰数时,仍然可以判断出被 触碰的位置;
二、 在感测资讯呈现的零交会处多于实际触碰数时,仍然可以判断出被 触碰的位置;
三、 依据差动感测资讯的特性分析位置, 比判断信号峰值更为精准。 综上所述, 本发明是有关于一种分析位置的方法与装置, 借由对包括 至少一零交会处的感测资讯进行一分析, 可分析出与零交会处不同数量的 多个位置。 当被分析出来的位置数量不同于零交会处的数量时, 分析出来 的位置数量为多个。 本发明在技术上有显著的进步,具有明显的积极效 果,诚为一新颖、 进步、 实用的新设计。
上述说明仅是本发明技术方案的概述, 为了能够更清楚了解本发明的 技术手段, 而可依照说明书的内容予以实施, 并且为了让本发明的上述和 其他目的、 特征和优点能够更明显易懂, 以下特举较佳实施例, 并配合附 图,详细说明如下。 附图的简要说明
图 1A为先前技术的触控装置的示意图。
图 1B为先前技术的信号值的示意图。
图 1C为依据本发明的差值的示意图。
图 1D与图 1E为依据本发明的双差值的示意图。
图 1F为依据本发明的感测装置的结构示意图。
图 1G为依据本发明的运算系统的功能方块示意图。
图 2A与图 2B为依据本发明的驱动 /侦测单元与感测装置的架构示意 图。
图 3A为依据本发明的侦测单元的功能方块示意图。
图 3B至图 3D为依据本发明的侦测器的电路示意图。
图 3E至图 3J为依据本发明的侦测电路与模拟转数字电路的连结示意 图。
图 4A至图 4B为依据本发明的二值化差值侦测位置的示意图。
图 4C至图 4D为依据本发明的侦测质心位置的范例示意图。
图 5A至图 5B为依据本发明的判断零交会处的范例示意图。
图 5C至图 5F为依据本发明的判断多零交会处的范例示意图。
图 6A至图 6B为依据本发明的判断单外部物或多外部物件接近或触碰
的范例示意图。
图 7为依据本发明的第一实施例的流程示意图。
图 8为依据本发明的第二实施例的流程示意图。
图 9为依据本发明的第三实施例的流程示意图。
10: 触控显示器 11: 控制器
110: 显示器 12: 外部物件
120: 感测装置 120A、 120B: 感测层
140、 140A、 140B: 感测器 14、 16、 17: 峰
15: 零交会处 100: 位置侦测装装置
130: 驱动 /侦测单元 130A: 驱动单元
130B: 侦测单元 160: 控制器
161: 处理器 162: 记忆体
170: 主机 171: 中央处理单元
173: 储存单元 310、 370: 切换电路
311、 312、 313、 314、 315、 316: 输入
320: 侦测电路 321、 323、 325: 开关电路
322、 324: 积分器 330: 模拟转数字电路
340、 350、 360: 侦测器 Cint: 放大器
Cinv: 反向器 Pl、 P2: 接点
Tp: 正门槛限值 Tn: 负门槛限值
Wl、 W2: 导线 a、 b、 c、 d: 点
Z、 Zl、 Z2、 Z3、 Z4、 Z5: 零交会处 实现发明的最佳方式
为更进一步阐述本发明为达成预定发明目的所采取的技术手段及功 效,以下结合附图及较佳实施例, 对依据本发明提出的分析位置的方法与装 置其具体实施方式、 方法、 步骤、 结构、 特征及其功效, 详细说明如后。
有关本发明的前述及其他技术内容、 特点及功效, 在以下配合参考图 式的较佳实施例的详细说明中将可清楚的呈现。 为了方便说明,在以下的实 施例中, 相同的元件以相同的编号表示。
本发明将详细描述一些实施例如下。 然而, 除了所揭露的实施例外,本 发明亦可以广泛地运用在其他的实施例施行。 本发明的范围并不受该些实 施例的限定, 乃以其后的申请专利范围为准。 而为提供更清楚的描述及使 熟悉该项技艺者能理解本发明的发明内容, 图示内各部分并没有依照其相 对的尺寸而绘图, 某些尺寸与其他相关尺度的比例会被突显而显得夸张,且 不相关的细节部分亦未完全绘出, 以求图示的简洁。
感测资讯 在本发明中,感测资讯可以是由触控装置 (Touch Sensing Device)提供,表 示触控装置上一维度、 二维度或多维度的状态, 并且感测资讯可以是由一 个或多个感测器 (sensor)取得,经由一个或多个模拟数字 转换器转换为多个 连续信号值, 以表示侦测到的电荷、 电流、 电压、 电容、 阻抗或其他电性 特性的量或改变量。 感测资讯在取得或传送的过程可能是以轮替、 循序或 平行的方式进行, 可复合成一个或多个信号, 本技术领域的普通技术人员 可轻易推知。
本技术领域的普通技术人员亦可推知, 本发明所述的感测资讯包括但 不限于感测器的信号、 感测器的信号扣除基准值 (如未触碰时的信号或初始 信号)后的结果、 前述信号或信号扣除基准值后的结果经模拟转数字 后的 值、 前述的值转换为其他表示方式的值。 换言之, 感测资讯可以是以信号 状态、 储存媒体 (如暂存器、 记忆体、 磁碟、 光碟)中的记录的任何由电性信 号转换或可转换成电性信号的状态来存在, 包括但不限于模拟或数字形式。
感测资讯可以是以不同轴向的两个一维度感测资讯被提供。 两个一维 度感测资讯可以被用来表示在触控装置上第一轴向 (如纵轴向)与第二轴向 (如横轴向)上的感测资讯, 可分别用来做第一轴向与第二轴向上的位置侦 测, 以分别提供第一轴向与第二轴向上的一维度位置, 或进一步构成二维 度位置。 此外, 两个一维度感测资讯亦可以基于感测器间的距离, 被用来 进行三角定位, 侦测出在触控装置上的二维度位置。
感测资讯可以是以一二维度感测资讯被提供, 二维度感测资讯为同轴 向上多个一维度感测资讯所组成。 一个二维度的感测资讯被提供可以表示 一个二维平面上的信号分布, 例如以纵轴向上多个一维度的感测资讯或横 轴向上多个一维度的感测资讯表示一个信号阵列 (signal matrix), 可依据分 水领演算法或其他影像处理的辨识方法进行位置侦测。
在本发明的一范例中, 触控装置上的感测区域包括由至少一个第一感 测器侦测的一第一二维度侦测范围与至少一个第二感测器侦测的一第二维 度侦测范围的重迭范围。 本技术领域的普通技术人员亦可推知, 感测区域 可以是三个以上的二维度侦测范围的重迭范围。
例如, 单一感测器的侦测范围为二维度侦测范围, 如基于照像机的光 学式侦测 (camera- based optical detection)的感测器 (如 CCD或 CMOS感测器) 或表面声波式侦测的压电感测器, 由二维度侦测范围中取得一维度感测资 讯。 此一维度感测资讯可以是由连续多个时点感测到的资讯构成, 不同时 点相应于不同的角度、 位置或范围。 此外, 此一维度感测资讯可以依据一
时间区间内取得的影像 (如 CCD或 CMOS感测器所取得的影像)所产生。 又例如, 二维度侦测范围是由多个感测器的侦测范围所构成, 如每一 个红外线式侦测的光接受器、 电容式侦测或电阻式侦测的线状或带状导电 条、 或电磁式侦测的 U形线圈的侦测范围为朝向一轴向的扇状或带状侦测 范围,多个在一线段 (直线或弧线)上朝向同一轴向排列的感测器的侦测范围 可构成该轴向的二维度侦测范围, 如构成矩形或扇形的平面或弧面的侦测 范围。
在本发明的一较佳范例中, 触控装置上的感测区域包括由第一轴向与 第二轴向上的多个感测器侦测的一二维度范围。 例如自电容式侦测 (self-capacitive detection), 提供一驱动信号给多个第一感测器, 并且感测这 些第一感测器的第一二维度侦测范围电容性耦合的信号或变化, 以取得一 第一一维度感测资讯。 此外, 亦提供一驱动信号给多个第二感测器, 并且 感测这些第二感测器的第二二维度侦测范围电容性耦合的信号或变化, 以 取得一第二一维度感测资讯。
在本发明的另一范例中, 触控装置上的感测区域包括由多个感测器侦 测一二维度范围的多个一维度感测资讯来构成一二维度感测资讯。 例如,当 信号源将驱动信号施循序加于一第一轴向上一感测器时, 循序侦测一第二 轴向上至少一感测器或同时侦测第二轴向上多个 (部份或全部)感测器的信 号, 可取得该轴向上的二维度感测资讯, '其中感测器为第二轴向至少一相 邻感测器或第二轴向至少一不相邻但邻近感测器。 例如在互电容式侦测 (mutual-capacitive detection)或模拟矩阵电 '阻式侦测 (analog matrix resistive detection), 由多个感测器构成多个感测处, 分别侦测各感测处的感测资讯。 例如以多个第一感测器 (如多条第一导电条)与多个第二感测器 (如多条第二 导电条)交迭构成多个交迭区, 轮流施加驱动信号于每一个第一感测器时, 相应于被施加驱动信号的第一感测器, 循序侦测第二轴向上至少一第二感 测器或同时侦测第二轴向上多个 (部份或全部)第二感测器的信号或信号变 化, 以取得相应于该第一感测器的一维度感测资讯。 借由汇集相应于各第 一轴向感测器的一维度感测资讯可构成一二维度感测资讯。 在本发明的一 范例中, 二维度感测资讯可视为一影像。
本技术领域的普通技术人员可推知, 本发明可应用于触敏显示器 (touch sensitive display), 例如具有或附加上述电阻式侦测、 电容式侦测、 表面声 波式侦测、或其他侦测触碰的触控装置 (或称触控装置 (touch sensitive device)) 的显示器。 因此, 基于触敏显示器或触控装置所取得感测资讯可视为触敏 资讯 (touch sensitive information) 0
在本发明的一范例中, 触控装置是不同时点的连续信号, 亦即连续由 一个或多个感测器同时侦测到的复合信号。 例如,触控装置可以是电磁式,连
续地扫瞄电磁式触控装置上的线圈以发出电磁波, 由一电磁笔上的一个或 多个感测器侦测感测资讯, 持续地复合成一信号, 再由模拟数字 转换器转 换为多个连续信号值。 此外, 亦可以是电磁笔发出电磁波或反射来自电磁 式触控装置的电磁波, 由触控装置上的多个感测器 (线圈)来取得感测资讯。 触碰相关感测资讯 (touch related sensing information) 外部物件 (如手指)碰触或接近触控装置时,会造成外部物件碰触或接近 的相应位置的感测资讯产生相应的电性特性或变化, 电性特性较强或变化 较大之处较接近外部物件中心 (如质心 (centroid:)、 重心或几何中心)。 无论感 测资讯是模拟或数字 , 连续的感测资讯可视为由连续多个值所构成, 上述 外部物件中心可能是相应于一值或两值之间。 在本发明中, 连续多个值可 以是相应空间上的连续或时间上的连续。
本发明提供的第一种一维度感测资讯是以多个连续的信号值呈现, 可 以是在一时间区间中多个感测器侦测的信号值, 或连续的时间区间中单一 感测器侦测的信号值, 亦可以是单一时间区间中单一感测器相应不同侦测 位置侦测到的信号值。 在感测资讯以信号^:呈现的过程中, 可以是轮流将 相应个别感测器、 时间区间或位置的信号转换成信号值, 亦可以是取得部 份或全部的感测资讯后再分析出个别的信号值。 当外部物件碰触或接近感 测装置时, 一维度感测资讯的连续信号值可以是如图 1B所示, 碰触位置为 相应外部物件的感测资讯的峰 14,其中峰 14可能落于两信号值之间。如前 述, 本发明不限定感测资讯存在的形态, 信号值可视为感测器的信号的另 一种形态。 为简化说明, 在以下叙述中是以信号值型态的实施方式来叙述 本发明, 本技术领域的普通技术人员可依据信号值型态的实施方式推知信 号型态的实施方式。
本发明提供的第二种一维度感测资讯是以多个连续的差值 (Difference) 呈现, 相对于上述信号值, 每个差值为一对信号值的差值, 并且连续多个 差值呈现的感测资讯可视为差动感测资讯 (differential sensing information)。 在本发明中, 差动感测资讯的取得可以是在感测时直接取得, 如同时或连 续地取得多个信号, 每一个差值是依据相应于一对感测器、 时间区间或位 置的差动信号来产生。 差动感测资讯亦可以是先产生包括多个信号值的原 始感测资讯 (original sensing information)后, 再依据原始感测资讯来产生。 如前述, 本发明不限定感测资讯存在的形态, 差值可视为差动信号的另一 种形态。 为简化说明, 在下面叙述中是以差值型态的实施方式来叙述本发 明, 本技术领域的普通技术人员可依据差值型态的实施方式推知差动信号 型态的实施方式。
在本发明的一范例中, 差值可以是相邻或不相邻的一对信号值间的差 值, 例如每个信号值与前一信号值的差值, 或是每个信号值与后一信号值 的差值。 在本发明的另一范例中, 差值可以是不相邻两信号值间的差值。 当外部物件碰触或接近触控装置时, 一维度感测资讯的连续差值可以是如 图 1C所示, 外部物件位置为相应外部物件的感测资讯的零交会处 15, 其 中零交会处 15可能落于两信号值之间。 在本发明的一范例中, 在触控装置 上, 每一个差值的相应位置为两信号值相应的位置的中间。
本发明提供的第三种一维度感测资讯是以多个连续的双差值 (Dual Differences)呈现, 相对于上述信号值或差值, 每个双差值可以是一第一对 信号值的差值与一第二对信号值的差值的和或差, 亦即两对信号值的差值 和或差。 在本发明的一范例中, 第一对信号值的差值与第二对信号值的差 值分别为一第一差值与一第二差值, 并且双差值为第一差值与第二差值的 差, 其中第一差值与第二差值皆为在前的信号值减在后的信号值的差或在 后的信号值减在前的信号值的差。 在本发明的另一范例中, 第一对信号值 的差值与第二对信号值的差值分别为一第一差值与一第二差值, 必且双差 值为第一差值与第二差值的和, 其中第一差值与第二差值之一为在前的信 号值减在后的信号值的差, 并且第一差值与第二差值的另一为在后的信号 值减在前的信号值的差。 例如, 两对信号值依序包括一第一信号值、 一第 二信号值、 一第三信号值、 一第四信号值, 该相应于该四个信号值的双差 值为 (第二信号值 -第一信号值 )+(第三信号值-第四信号值)、 (第二信号值-第 一信号值) - (第四信号值-第三信号值) 、 (第一信号值-第二信号值) + (第四信 号值-第三信号值)或 (第一信号值-第二信号值) - (第三信号值-第四信号值)。 此外, 连续多个双差值组成的感测资讯可视为双差动感测资讯 (dual-differential sensing information)。 在本发明中, 双差值并不限定是在产 生信号值或差值后产生, 亦可以是在感测资讯被提供时已分别完成两对信 号的相减后的和或差, 提供相似或等效于两对信号值的差值的和或差的双 差动信号。 如前述, 本发明不限定感测资讯存在的形态, 双差值可视为感 测器的双差动信号的另一种形态。 为简化说明, 在下面叙述中是以双差值 型态的实施方式来叙述本发明, 本技术领域的普通技术人员可依据双差值 型态的实施方式推知双差动信号型态的实施方式。
在本发明的一范例中, 当外部物件碰触或接近触控装置时, 两对信号 值由相邻或不相邻的三个信号值组成。 在本发明的一范例中, 前两个信号 值的差值与后两个信号值的差值分别为一第一差值与一第二差值, 并且双 差值为第一差值与第二差值的差, .其中第一差值与第二差值皆为在前的信 号值减在后的信号值的差或在后的信号值减在前的信号值的差。 在本发明 的另一范例中, 前两个信号值的差值与后两个信号值的差值分别为一第一
差值与一第二差值, 必且双差值为第一差值与第二差值的和, 其中第一差 值与第二差值之一为在前的信号值减在后的信号值的差, 并且第一差值与 第二差值的另一为在后的信号值减在前的信号值的差。 例如, 两对信号值 依序包括一第一信号值、 一第二信号值、 一第三信号值, 该相应于该三个 信号值的双差值为 (第二信号值-第一信号值) + (第二信号值-第三信号值)、 (第 二信号值 -第一信号值 M第三信号值-第二信号值)、 (第一信号值-第二信号 值) + (第三信号值-第二信号值)或 (第一信号值 -第二信号值 M第二信号值-第 三信号值)。 当两对信号值由相邻的三个信号值组成, 并且外部物件碰触或 接近触控装置时,一维度感测资讯的连续双差值可以是如图 ID所示, 其中 外部物件位置为相应外部物件的感测资讯的中央峰 16,其中中央峰 16可能 落于两信号值之间。 当两对信号值由不相邻的三个信号值组成, 并且外部 物件碰触或接近触控装置时, 一维度感测资讯的连续双差值可以是如图 1E 所示, 其中外部物件位置为相应外部物件的感测资讯的中央峰 17, 其中央 峰 17可能落于两信号值之间。
在本发明中, 相应个别感测器、 时间区间或位置的感测资讯可以是感 测器侦测的信号,当信号为模拟时,可经由模拟数字 转换器转换成数字 的 信号值。 因此, 上述的差值亦可以是一对信号的差的值, 例如是 对信号 :经差动放大器进行相减后所转换的值。 同样地, 双差值亦可以是两对信号 分别经差动放大器进行相减后再相加 (或相减)所转换的值。本技术领域的普 通技术人员可推知本发明所述的差值与双差值包括但不限于是以信号或信 号值来产生,亦包括硬体或软体实施过程中的记录 (电性记录、 磁性记录、 光 学记录)、 信号或信号值的暂时状态。
换言之, 感测资讯可以是感测器上或感测器间的信号、 差动信号 (如一 对信号差)、双差动信号 (如二对信号差的和或差),信号值、差值、双差值 (经 模拟转数字 后的信号、差值、双差值)为另一种存在形态。 由于信号与信号 值、 差动信号与差值、 双差动信号与双差值可以是感测资讯在不同阶段的 呈现。 此外, 为简化说明, 在本发明的说明中以触碰相关感测资讯泛指相 应于外部物件触碰或接近的感测资讯, 如原始触碰相关感测资讯、 差动触 碰相关感测资讯、 双差动触碰相关感测资讯。
本技术领域的普通技术人员可推知在差值或双差值中, 零交会处位于 至少一正值与至少一负值间, 亦即位于一对正值与负值之间 (between a pair of positive and negative values)。相应于外部物件接近与触碰的差值或双差值 为连续的至少一正值与至少一负值的交替组合, 至少一正值与至少一负值 间为彼此相邻或间隔至少一零值。 在大部份的情况下, 相应于外部物件接 近或触碰的差值或双差值为连续的多个正值与多个负值的交替组合, 正值 与负值间的零交会处可能是至少一零值或位于两值间。
相对地, 触碰相关的信号值为多个连续的非零值, 或可能是一个不相 邻其他非零值的独立非零值。 在某些情形中, 一个不相邻其他非零值的独 立非零值可能是因杂讯所产生, 需要靠一门槛值或其他机制辨识或排除
(neglect)。
由于在杂讯较大时,有可能产生类似外部物件接近与触碰的零交会 处,因此在本发明的一范例中, 是将落于一零值范围内的值皆视为零值, 相 应于外部物件接近与触碰的差值或双差值为连续多个大于一正门槛的值与 小于一负门槛的值的交替组合, 大于一正门槛的值与小于一负门槛的值间 的零交会处可能是至少一零值或位于两值间。
综合上述, 差动触碰相关感测资讯与双差动触碰相关感测资讯为包括 零交会处的连续至少一正值与至少一负值的交替组合, 其中零交会处可能 是至少一零值或位于正值与负值间。 换言之, 本发明将差动触碰相关感测 资讯为双差动触碰相关感测资讯中正值与负值间连续多个零值亦视为零交 会处, 或其中一个零值为零交会处。
在本发明的一范例中, 触碰相关感测资讯预设是由至少一正值或一负 值起始, 由起始的至少一正值或负值搜寻包括零交会处的连续至少一正值 与至少一负值的交替组合, 其中零交会处可能是至少一零值或位于正值与 负值间。 在触碰相关的差动感测资讯中, 至少一正值与至少一负值的交替 组合为对衬出现, 并且在触碰相关的双差动感测资讯中, 至少一正值与至 少一负值的交替组合为不对衬出现。 在本发明的另一范例中, 触碰相关感 测资讯是连续的非零值, 如连续多个非零的信号值。
上述至少一正值可视为一正值集合, 包括至少一正值, 同样地上述至 少一负值可视为一负值集合, 包括至少一负值。 因此上述的交替组合可以 是包括一正值集合与一负值集合的两个集合的组合或三个以上的集合以正 值集合与负值集合交互穿插的组合。 在本发明的一范例中,可能在零个、 一 个、 或多个正值集合与负值集合间存在至少一零值。 系统架构 为了更清楚说明本发明的感测资讯的产生方式, 本发明采用电容式触 控装置为例, 本技术领域的普通技术人员可轻易推知其他应用于电阻式、 红外线式、 表面声波式、 光学式触控装置的应用方式。
请参照图 1F本发明提出一种位置侦测装置 100, 如第一图所示, 包括 一感测装置 120, 与一驱动 /侦测单元 130。感测装置 120具有一感测层。在 本发明的一范例中, 可包括一第一感测层 120A与一第二感测层 120B, 第 一感测层 120A与第二感测层 120B分别有多个感测器 140, 其中第一感测
层 120A 的多个第一感测器 140A与第二感测层 120B 的多个第二感测器 140B交迭。 在本发明的另一范例中, 多个第一感测器 140A与第二感测器 140B 可以配置在共平面的感测层中。 驱动 /侦测单元 130依据多个感测器 140的信号产生一感测资讯。例如在自电容式侦测时, 是感测被驱动的感测 器 140, 并且在互点容式侦测时, 是感测的是没有被驱动 /侦测单元 130直 接驱动的部份感测器 140。此外,感测装置 120可以是配置在显示器 110 上,感测装置 120与显示器 110间可以是有配置一背盾层 (shielding layer) (未 显于图示)或没有配置背盾层。
本发明的位置侦测装置 100可以是应用于一计算系统中, 如图 1G 所示, 包括一控制器 160与一主机 170。控制器包含驱动 /侦测单元 130, 以 操作性耦合感测装置 120(未显于图示)。 此外, 控制器 160可包括一处理器 161 ,控制驱动 /侦测单元 130产生感测资讯,感测资讯可以是储存在记忆体 162中,以供处理器 161存取。 另外, 主机. 170构成计算系统的主体, 主要 包括一中央处理单元 171,以及供中央^:理单元 171存取的储存单元 173,以 及显示运算结果的显示器 110。
在本发明的另一范例中, 控制器 160与主机 170间包括一传输界面,控 制单元透过传输界面传送资料至主机, 本^ ^术领域的普通技术人员可推知 传输界面包括但不限于 UART、 USB. I2C. Bluetooth. WiFi等各种有线或 无线的传输界面。 在本发明的一范例中, 传输的资料可以是位置 (如座标)、 辨识结果 (如手势代码)、 命令、 感测资讯或其他控制器 160可提供的资讯。
在本发明的一范例中, 感测资讯可以是由处理器 161 控制所产生的初 始感测资讯 (initial sensing information), 交由主机 170进行位置分析, 例如 位置分析、 手势判断、 命令辨识等等。 在本发明的另一范例中, 感测资讯 可以是由处理器 161 先进行分析,.再将判断出来的位置、 手势、 命令等等 递交给主机 170。本发明包括但不限于前述的范例, 本技术领域的普通技术 人员可推知其他控制器 160与主机 170之间的互动。
请参照图 2A所示, 在本发明的一范例中, 驱动 /侦测单元 130可以是 包含驱动单元 130A与侦测单元 130B。 感测装置 120的多个感测器 140是 经由多条导线 (wires)操作性耦合至驱动 /侦测单元 130。 在图 2A的范例中, 驱动单元 130A与侦测单元 130B是分别经由导线 W1操作性耦合至感测器 140 A与经由导线 W2操作性耦合至感测器 140B。
例如, 在自电容式侦测时, 驱动单元 130A是经由导线 W1在一第一时 段轮流驱动或同时驱动全部感测器 140A, 亦可以是分次同时驱动部份感测 器 140A,由侦测单元 130B经导线 W1依据感测器 140A的信号产生一第一 轴向的感测资讯 (一维度感测资讯)。 同理, 驱动单元 130A是经由导线 W2 在一第二时段轮流驱动或同时驱动全部感测器 140B, 亦可以是分次同时驱
动部份感测器 140B, 由侦测单元 130B经导线 W2依据感测器 140B的信号 产生一第二轴向的感测资讯 (一维度感测资讯:)。
又例如, 在互电容式侦测时,驱动单元 130A是经由导线 W2在第一时 段轮流驱动感测器 140B, 分别在每一个感测器 140B被驱动时, 由侦测单 元 130B经导线 W1依据感测器 140A的信号产生相应于被驱动感测器的第 一轴向的一维度感测资讯, 这些第一轴向的一维度感测资讯构成第一轴向 的一二维度感测资讯 (或一影像)。 同理, 驱动单元 130A是经由导线 W1在 第二时段轮流驱动感测器 140A, 分别在每一个感测器 140A被驱动时, 由 侦测单元 130B经导线 W2依据感测器 140B的信号产生相应于被驱动感测 器的第二轴向的一维度感测资讯, 这些第二轴向的一维度感测资讯构成第 二轴向的一二维度感测资讯 (或一影像)。 此外, 驱动单元 130A与侦测单元 130B间可以经由线路 132提供信号来进行同步, 线路 132的信号可以是由 上述处理器 160提供。
请参照图 2B所示,感测装置 120也可以是只产生单一轴向的二维度感 测资讯, 在本范例中是由导线 W2轮流驱动感测器 140B, 分别在每一个感 测器 140B被驱动时, 由侦测单元 130B经导线 W1依据感测器 140A的信 号产生相应于被驱动感测器的一维度感测资讯, 这些一维度感测资讯构成 一二维度感测资讯 (或一影像)。
换言之, 本发明的位置侦测装置 100可以是具备产生两个轴向的一维 度感测资讯或两个轴向的二维度感测资讯的能力,或者是兼具产生两个轴向 的一维度感测资讯与二维度感测资讯的能力, 亦可以只产生单轴向的二维 度感测资讯。 本发明包括但不限于上述电容式位置侦测装置,本技术领域的 普通技术人员可轻易推知其他应用于电阻式、 红外线式、 表面声波式、 光 学式触控装置的应用方式。
请参照图 3Α所示,上述侦测单元 130B是经由导线 (如 W1)操作性耦合 至感测装置, 操作性耦合可以是由一切换电路 310来达成, 切换电路可以 是由一个或多个多工器、 开关 (switch)等电性元件组合, 本技术领域的普通 技术人员可推知其他切换电路的应用。 感测器 140 的信号可以是由一侦测 电路 320来侦测, 当侦测电路 320输出的信号为模拟时, 可再经由模拟转 数字 电路 320来产生感测资讯 SI。 感测资讯 SI可以是模拟或数字 , 在本 发明一较佳范例中, 感测资讯为数字 型式。 本发明包括但不限于上述 范例,本技术领域的普通技术人员可推知侦测电路 320与模拟转数字 电路 330可以是整合于一个或多个电路。
侦测电路 320可以是由一个或多个侦测器组成, 每一个侦测器接收至 少一感测器 140的信号来产生一输出, 侦测器可以是如图 3B至图 3D的侦 测器 340、 350、 360所示。
在本发明的一范例中, 对于感测器 140的信号的侦测, 可以是以一积 分器来侦测, 本技术领域的普通技术人员可推知其他如模拟转数字 器等可 量测电性特性 (如电压、 电流、 电容、 电感等等)的电路亦可应用于本发明。 积分器可以是可以是以一放大器 Cint来实施, 具有一输入 (如图 3B的积分 器 322所示:)或一对输入 (如图 3C及图 3D的积分器 324所示), 以及一 输出, 输出的信号可以是经由模拟转数字 电路 320来产生感测资讯 SI的 值,每一个值的产生可以是透过一重置信号来控制,如图 3B至图 3D的重置 信号 Sreseto
在本发明的另一范例中, 感测器 140 的信号为交流信号, 随一对半周 期而改变, 因此对于感测器 140的信号的侦测也是依据不同的半周期而改 变, 如在前半周期侦测感测器 140的信号, 在后半周期侦测感测器 140的 反向信号, 反之亦然。 因此, 感测器 140 的信号的侦测可以是透过一同步 信号 Ssync来控制, 如图 3B至图 3C所示, 同步信号 Ssync与感测器 140 的信号可以是同步或具有相同周期。例如,利用同步信号 Ssync控制一个或 多个开关 (如开关电路 321、 323、 325)在基点 P1与 P2间切换, 在前半周期 侦测感测器 140的信号, 在后半周期侦测感测器 140的反向信号。 在图 3B 中, 反向信号可以是借由一反向器 Cinv来提供。
在本发明的再一范例中, 感测器 140 的信号的侦测是在至少一周期的 至少一预设的时段 (或相位)侦测,可以是在前半周期的至少一时段与后半周 期的至少一时段来侦测, 亦可以只在前半周期或只在后半周期的至少一时 段来侦测。 在本发明的一较佳范例中, 是先扫描一周期中信号较佳的至少 一时段, 作为侦测时段, 其中侦测时段相对于其他时段受到杂讯的干扰较 小。 侦测时段的扫描可以依据至少一个感测器的信号在至少一周期中每一 个时段的侦测来判断。 在侦测时段判断出来之后, 感测器 140的信号的侦 测只在侦测时段侦测, 可以是透过一信号来控制, 如图 3B至图 3D中的致 能信号 Senable。
本发明是依据至少一感测器 140的信号来产生感测资讯 SI的值。 在本 发明的一范例中, 感测资讯 SI是由多个信号值组成。 例如图 3B所示, 是 由一输入 311操作性耦合至一感测器 140, 来侦测出一信号, 再经由模拟转 数字 电路 330产生感测资讯 SI的一信号值。在本发明的另一范例中,感测 资讯 SI是由多个差值组成。 例如图 3C所示, 是由一对输入 312、 313操作 性耦合至一对感测器 140, 来侦测出一差动信号, 再经由模拟转数字 电路 330产生感测资讯 SI的一差值 (或称单差值)。在本发明的再一范例中,感测 资讯 SI是由多个双差值组成。 例如图 3D所示。 是由三个输入 314、 315、 316操作性耦合至三个感测器 140, 来侦测出一双差动信号, 再经由模拟转 数字 电路 330产生感测资讯 SI的一双差值。双差动信号是依据一对差动信
号的差来产生,每一个差动信号是依据一对感测器的信号来产生。 换言 之,双差动信号可以是依据一第一对感测器与一第二对感测器的信号来产 生, 第一对感测器为三个感测器中的前两个感测器, 并且第二对感测器为 三个感测器中的后两个感测器, 其中三个感测器可以是相邻或不相邻。
在本发明的一较佳范例中, 侦测电路 320包含多个侦测器, 可同时产 生感测资讯 SI中的全部或部份的值。例如图 3E至图 3J所示,侦测电路 320 可以是由多个侦测器 340、 350或 360所组成, 这些侦测器的输出再由模拟 转数字 电路 330转换成感测资讯 SI的值。
模拟转数字 电路 330包括至少一模拟转数字 器 ADC, 每一个模拟转 数字 器可以是只依据一侦测器的输出产生感测资讯 SI的值, 如图 3E、 图 3G、 图 31.所示, 亦可以是轮流由多个侦测器的输出产生感测资讯 SI的 值, 如图 3F、 图 3H、 图 3J所示。 感测资讯 SI的值可以是平行产生也可以 是序列产生, 在本发明的一较佳范例中, 感测资讯 SI的值是序列产生,可以 是由一切换电路 370来达成, 例如将多个模拟转数字 器轮流输出感测资讯 SI的值, 如图 3E、 图 3G、 图 31所示, 或将多个积分器的输出轮流提供给 一模拟转数字 器来产生感测资讯 SI的值,:如图 3F、 图 3H、 图 3J所示。
据此, 在本发明的一范例中, 是依据多个感测器的信号产生具有多个 信号值的感测资讯 SI, 其中每一个信号值是依据一个感测器的信号来产 生, 如图 3B、 图 3E与图 3F所示。 在本发明的另一范例中, 是依据多个感 测器的信号产生具有多个差值的感测资讯 SI, 其中每一个差值是依据一对 感测器的信号来产生, 如图 3C、 图 3G与图 3H所示。在本发明的再一范例 中, 是依据多个感测器的信号产生具有多个双差值的感测资讯 SI, 其中每 一个双差值是依据三个感测器的信号来产生, 如图 3D、 图 31与图 3J所示。
在图 3E至图 3J中, 连接多个侦测器的导线包括但不限于导线 Wl, 亦 可以是导线 W2。积分器与导线间包括但不限于直接连接, 亦可以是透过切 换电路来连接, 如图 3A所示。 在本发明的一范例中, 感测资讯的值是由侦 测电路 320的至少一个侦测器以多次侦测来产生, 侦测电路 320是透过切 换电路 310 由这些感测器中挑选部份的感测器来进行侦测。 此外, 只有被 挑选的感测器被驱动单元 130A驱动, 例如是在自电容式侦测中。 另外, 亦 可以是只有被挑选的感测器与部份相邻于被挑选的感测器被驱动单元 130A 驱动。
在本发明的一第一范例中, 感测资讯可以是由一双差动电路取得,双差 动电路包括: 一第一级差动电路、 一第二级差动电路与一量测电路, 例如 图 3D、 图 31或图 3J所示。
第一级差动电路包括一对或多个第一减法器 (例如开关电路 325中的差 动放大器), 每一个第一减法器分别依据这些感测器中的一对感测器的信号
产生一第一级差值信号。
此外, 第二级差动电路包括一个或多个第二减法器 (例如积分电路 324 中的积分器), 每一个第二减法器分别依据这些第一级差值信号中的一对第 一级差值信号产生一第二级差值信号。
另外, 量测电路可以是如图 3A的模拟转数字 电路所示, 可以是如图 3D的积分器 324与模拟转换电路 ADC所组成, 或是如图 31的多个积分器 324、 多个模拟转换电路 ADC与一切换电路 370所组成, 亦可以是如图 31 的多个积分器 324、一切换电路 370与一模拟转换电路 ADC所组成。此 外,量测电路是在一个或多个时点量测这些第二级差值信号, 以产生该感测 资讯。 例如图 3D或图 3J所示, 是在多个时点量测这些第二级差值信号,或 如图 31所示, 是在一个时点量测这些第二级差值信号。
. 在本发明图 3D、 图 31与图 3J中, 是以差动积分器 324同时进行信号 相减与量测,其中信号量测可再包括以模拟转换电路 ADC产生一数字值。前 述相关图示与说明仅为本发明的范例之一, 并非用以限制本发明, 本技术 领域的普通技术人员可推知信号相减与信号量测可以是以不同电路施行,例 如先经过一减法器再经过一积分器, 在此不再赘述。
在前述双差动电路中, 感测资讯的每一个值分别是由这些第二级差值 信号之一产生, 并且每一个第二级差值信号分别是由所述一对第一级差值 信号的一第一差值信号与一第二差值信号产生, 其中第一差值信号是分别 依据这些感测器的一第一感测器与一第二感测器的信号产生,并且第二差值 信号是分别依据这些感测器的第二感测器与一第三感测器的信号产生。 换 言之, 感测资讯的每一个值分别相应于这些感测器中三个感测器的信号。
在本发明的一第二范例中, 感测资讯可以是由一差动电路取得, 差动 电路包括: 一个或多个减法器与一量测电路, 例如图 3C、 图 3G或图 3H所 示。 在这些减法器中, 每一个减法器分别依据一对感测器的信号产生一差 值信号。 量测电路则量测这些差值信号, 以产生一差动感测资讯, 其中感 测资讯的每一个值分别是由差动感测资讯的一对值的差值。
此外, 量测电路是在一个或多个时点量测这些第二级差值信号, 以产 生该感测资讯。 例如图 3C或图 3H所示, 是在多个时点量测这些第二级差 值信号, 或如图 3G所示, 是在一个时点量测这些第二级差值信号。
在图 3C、图 3G或图 3H,减法器与量测电路的部份可以是由积分器 324 来实施。 前述相关图示与说明仅为本发明的范例之一, 并非用以限制本发 明, 本技术领域的普通技术人员可推知信号相减与信号量测可以是以不同 电路施行, 例如先经过一减法器再经过一积分器, 在此不再赘述。
此外, 感测资讯的每一个值分别是差动感测资讯的一第一差值与一第 二差值的差值, 其中第一差值是分别依据这些感测器的一第一感测器与一
第二感测器的信号产生, 并且第二差值是分别依据这些感测器的第二感测 器与一第三感测器的信号产生。 换言之, 感测资讯的每一个值分别相应于 这些感测器中三个感测器的信号。
在本发明的第三范例中,感测资讯可以是由一量测电路取得,如图 3B、 图 3E或图 3F所示。 量测电路在一个或多个时点量测这些感测器的 信号, 以产生一初始感测资讯, 感测资讯是依据初始感测资讯产生, 其中 感测资讯的每一个值分别是由初始感测资讯的三个值产生。
此外, 量测电路是在一个或多个时点量测这些第二级差值信号, 以产 生该感测资讯。 例如图 3B或图 3F所示, 是在多个时点量测这些第二级差 值信号, 或如图 3E所示, 是在一个时点量测这些第二级差值信号。
感测资讯的每一个值分别是一第一差值与一第二差值的差或和, 其中 第一差值为初始感测资讯的三个值的前两个值的差值, 并且第二差值为初 始感测资讯的三个值的后两个值的差值。 换言之, 所述初始感测资讯的三 个值分别是一第一值、一第二值与一第三值,感测资讯的每一个值分别是 (第 二值-第一值 H第三值 -第二值)、(第一值-第二值 M第二值 -第三值)、(第二值 -第一值)+(第二值-第一值)或 (第一值-第二值) + (第三值-第二值)。前述初始感 测资讯的每一个值是依据这些感测器之一的信号产生, 换言之, 感测资讯 的每一个值分别相应于这些感测器中三个感测器的信号。
在发明的一范例中, 感测资讯中的每一个触碰相关感测资讯具有两个 零交会处, 并且被外部物件接近或触碰的位置是依据每一个触碰相关感测 资讯判断出来。 在发明的另一范例中, 触碰相关感测资讯位于感测资讯最 前面部份或最后面部份, 外部物件仅部份接近或触碰感测装置的主动区边 缘, 而不具有两个零交会处, 需要例外处理。
此外, 前述的时点可以是包括但不限于经过一个或多个时脉,或一个或 多个时脉的部份。
再者, 上述感测资讯的取得与产生可以是由前述控制器 160来实施, 上述双差动电路、 差动电路与量测电路亦可以是由控制器 160来实施。
在本发明中, 感测器可以是由多个导电片与连接导线所构成, 例如是 由多个连结导线串连一连串的菱形或方形导电片所构成。 在结构上, 第一 感测器 i40A与第二感测器 140B的导电片可以是排列不同平面, 亦可以是 排列在相同平面。例如, 第一、第二感测层 120A、 120B间隔着一绝缘层或 一压阻 (piezoresistive)层, 其中压阻层可以是由异方性导电胶所构成。 又例 如, 第一感测器 140A与第二感测器 140B的导电片大体上排列在同一 平面, 第一感测器 140A的连接导线跨过第二感测器 140B的连接导线。 此 外, 第一感测器 140A的连接导线与第二感测器 140B的连接导线间可配置 一垫片, 垫片可以是由绝缘材质或压阻材质所构成。
因此, 在本发明的一范例中, 每一感测器感测一感测范围,并且是由多 个感测器来感测, 这些感测器包含多个第一感测器与多个第二感测器,这些 第一感测器间的感测范围平行, 并且这些第二感测器间的感测范围平行,这 些第一、 第二感测器的平行感测范围交迭构成一交迭区阵列。 例如这些第 一、 第二感测器分别为横向与纵向排列的两列红外线接收器, 分别感测重 直与水平的平行扫瞄范围, 重直与水平的平行扫瞄范围交错处构成一交迭 区阵列。 又例如上述重直与水平的平行扫瞄范围由电容式或电阻式的多条 交迭的感测器来实施。 感测资讯转换 (Conversion of Touch Sensitive Information) 上述感测资讯的信号值、 差值、 双差值间可以相互转换。 在本发明提 供的一第 转换方式中, 是将连续的信号值转换成连续的差值, 每一个差 值为一对相邻或不相邻信号值的差值。
在本发明提供的一第二转换方式中, 是将连续的信号值转换成连续的 双差值, 每一个双差值为两对信号值的差值和或差。
在本发明提供的一第三转换方式中, >是将连续的差值转换成连续的信 号值, 以每一个差值加上在前或在后所有差值来产生相应的信号值, 组成 连续的信号值。
在本发明提供的一第四转换方式中, 是将连续的差值转换成连续的双 差值, 每一个双差值为相邻或不相邻的一对差值的和或差。
在本发明提供的一第五转换方式中, 是将连续的双差值转换成连续的 差值, 以每一个双差值加上在前或在后所有双差值来产生相应的差值, 组 成连续的差值。
在本发明提供的一第六转换方式中, 是将连续的双差值转换成连续的 信号值。 在本发明的一范例中, 是以每一个双差值加上在前所有双差值来 产生相应的差值, 组成连续的差值, 再以每一个差值减去在后所有的差值 来产生相应的信号值, 组成连续的信号值。 在本发明的另一范例中, 是以 每一个双差值减去在前所有双差值来产生相应的差值, 组成连续的差值,再 以每一个差值加上在后所有的差值来产生相应的信号值, 组成连续的信号 值。
前述加上在前或在后的所有差值或双差值可以是以向前或向后累加或 累减方式来依序产生相应的信号值或差值。
上述的转换方式包括但不限于一维度感测资讯的转换, 本技术领域的 普通技术人员可推知上述的转换方式亦可以应于于二维度感测资讯或三维 度以上的感测资讯。 此外, 本技术领域的普通技术人员可推知上述的转换
方式的作业可以是由前述控制器 160或主机 170来执行。
据此, 在本发明的一范例中, 是将侦测到的第一形式的感测资讯 (如一 维度、 二维度感测资讯)转换成用于位置分析的感测资讯。 在本发明的另一 范例中, 是将侦测到的第一形式的感测资讯转换成一第二形式的感测资 讯, 再将第二形式的感测资讯转换成用于位置分析的感测资讯, 例如由连 续的双差值转换成连续的信号值。 一维度位置分析 (One Dimension Position Analysis) 本发明提供的一第一种位置分析是依据感测资讯中多个差值分析出零 交会处 (zero-crossing)的位置作为外部物件相应的位置。 本技术领域的普通 技术人员可推知位置分析可以是包括但不限于外部物件接近与触碰的判 断, 亦即外部物件相应的位置的判断包括但不限于外部物件接近与触碰的 判断。
在本发明的一范例中, 是搜寻包含一正值与一负值的一对邻近差值,即 零交会处两侧的一对正值与负值, 再判断出这对邻近的差值间零交会处的 位置, 例如依据这对邻近的差值产生一斜率来判断出零交会处。 此外,更可 以是依据正值与负值的出现的先后顺序配合邻近的差值间零交会处的判 断。 前述的这对邻近的差值可以是相邻的差值, 亦可以中间包含至少一零 值的非相邻的差值。 此外, 可以是以一预设的排列顺序来搜寻这对邻近正 值与负值, 例如是搜寻先出现正值再出现负值的一对邻近正值与负值。
在本发明的另一范例中, 是利用一门槛限值决定搜寻零交会处的起始 位置, 由起始位置搜寻包含一正值与一负值的一对邻近的差值, 再依据这 对邻近的差值判断出零交会处的位置。 本技术领域的普通技术人员可推知 在差值表示的感测资讯中, 相应于外部物件接近或触碰的感测资讯大于一 正门槛限值或小于一负门槛限值时, 以此门槛限值所进行的搜寻包括但不 限于对外部物件接近或触碰的判断。 换言之, 在扫描感测资讯的过程中,每 当感测资讯大于一正门槛限值或小于一负门槛限值时, 可判断出感测资讯 存在相应一外部物件接近或触碰的零交会处。
例如以一门槛限值产生相应于正值的差值的二值化值, 例如小于门槛 限值 (如正门槛限值)的差值以 0或伪值 (false)代表, 并且大于门槛限值的差 值以 1或真值 (true)代表,以相邻差值为 10的 1处或真值及伪值的真值处为 起始位置, 零交会处的搜寻方向为向后搜寻。 同样地, 可以是以大于门槛 限值 (如负门槛限值)的差值以 0或伪值 (false)代表, 并且小于门槛限值的差 值以 1或真值 (true)代表,以相邻差值为 01的 1处或真值及伪值的真值处为 起始位置, 零交会处的搜寻方向为向前搜寻。
例如表一及图 4A为以门槛限值判断外部物件接近或触碰的范例。 表一
范例中包括相应 15个感测器的信号值与差值, 以及利用一正门槛限值 T1 (以 4为例)及一负门槛限值 T2(以 -4为例)的判断结果。在利用正门槛限值 的判断结果中, 起始位置 10的 1处, 即第 4个差值与第 10个差值, 在图 示中以直纹棒为例, 代表有两个外部物件接近或触碰。 同样地, 在利用负 门槛限值的判断结果中, 起始位置为相邻差值为 01的 1处, 即第 5个差值 与第 12个差值,在图示中以横纹棒为例,代表有两个外部物件接近或触碰。 本技术领域的普通技术人员可推知起始位置的数量相应于外部物件接近或 触碰的数量, 本发明不限于本范例中的 2个外部物件接近或触碰的数量,亦 可以是 1个或更多个。
在本发明的另一范例中, 是利用一第一门槛限值与一第二门槛限值决 定搜寻零交会处的区间, 包括但不限于判断出一外部物件的接近或触碰,再 由区间内搜寻零交会处的位置。 例如以一第一门槛限值产生相应于正值的 差值的二值化值, 例如小于门槛限值的差值以 0(或伪值 (false))代表, 并且 大于门槛限值的差值以 1(或真值 (true))代表, 以相邻两差值为 10处的 1为 起始位置。 此外, 以第二门槛限值产生相应于负值的差值的二值化值,例如
大于门槛限值的差值以 0(或伪值)代表, 并且小于门槛限值的差值以 1(或真 值)代表, 以相邻两差值为 01处的 1为结束位置。 另外, 将起始位置、 结束 位置配对决定搜寻零交会处的区间。在本发明的一范例中,是以起始位置 (如
10处中的 1位置)与结束位置 (如 01处中的 1位置)间的斜率判断出零交会处。 本技术领域的普通技术人员可推知上述起始位置与结束位置可分别互换为 结束位置与起始位置。 本技术领域的普通技术人员亦可推知可以是起始位 置为 01的 1处并且结束位置为 10的 1处来判断出触碰相关感测资讯。
例如以前述图 4A与表一为例,配对后的第一个搜寻零交会处的区间为 第 4个与第 5个差值间, 配对后的第二个搜寻零交会处的区间为第 10个与 第 12个差值间。
本技术领域的普通技术人员可推知正门槛限值的扫描与负门槛限值的 扫瞄可以是同时进行 (或平行处理:),区间的配对亦可以是在一起始位置被判 断出后, 配对在后判断出来的结束位置。
在本发明的一范例中, 门槛限值是依感测资讯来产生, 例如门槛限值 是以所有差值的绝对值中最大者乘上一比例 (如小于一的比例, 例如 0.9)来 决定, 亦可以是正门槛限值是以正差值中最大者乘上一比例来决定, 或是 ft门槛限值是以负差值中最小者乘上一比例来决定。 换言之, 门槛限值可 以是固定的或是动态的。 因此, 门槛限值的绝对值较大时, 有可能发生相 应的外部物件的接近或触碰在利用正门槛限值的扫描中被判断出来, 但在 利用负门槛限值的扫描中未被判断出来, 反之亦然。 其中较大的门槛限值 较有利于滤除杂讯或鬼点, 较小的门槛限值较有利于避免漏判真实的触 碰, 或有利于判断外部物件的接近。
从上述说明中可推知, 相应于同一外部物件的接近或触碰, 不论是由 正门槛限值来判断出起始位置后向后搜寻, 或是由负门槛限值来判断出起 始位置后向前搜寻, 皆会搜寻到相同的零交会处。 因此, 在本发明的一范 例中, 是分别利用正门槛限值与负门槛限值扫描起始位置, 由起始位置搜 寻零交会处, 依据搜寻到的零交会处的数量判断被外部物件接近或触碰的 数量, 并进一步判断零交会处的位置。 当相应于外部物件触碰或接近的零 交会处两侧的一对正值与负值是先正值再负值, 依据正门槛限值判断出的 起始位置是向后搜寻零交会处, 而依据负门槛限值判断出的起始位置是向 前搜寻零交会处, 反之亦然。 另外, 相应于同一外部物件的接近或触碰不 必然能在利用正门槛限值与负门槛限值扫描时都判断出起始位置。
本发明提供的一第二种位置分析是依据感测资讯中多个信号值或双差 值分析出质心 (centroid)位置 (重心位置或加权平均位置)作为外部物件相应 的位置。
在本发明的一范例中,是利用一门槛限值决定用于判断质心位置的信号
值或双差值。 如图 4B至图 4D所示, 可以是以一门槛限值产生相应于信号 值或双差值的二值化值, 例如小于门槛限值的信号值或双差值以 0或伪值 (false)代表, 并且大于门槛限值的信号值或双差值以 1或真值 (true)代表。在 本例中是以 1 或真值代表的信号值或双差值为用于判断质心位置的信号值 或双差值。 本技术领域的普通技术人员可推知其他以一门槛限值决定用于 判断质心位置的信号值或双差值的方式, 例如是以 1 或真值代表的信号值 或双差值再加上两侧相邻的多个信号值或双差值为用于判断质心位置的信 号值或双差值。 又例如是以相邻的连续 1 或真值代表的信号值或双差值中 相对中央的信号值或双差值向前与向后分别取 i与 j个信号值或双差值作为 用于判断质心位置的信号值或双差值。
在本发明的另一范例中, 是将连续的信号值或双差值转换为连续差 值,以分析出零交会处相应的信号值或双差值作为中央的信号值或双差 值,再以中央的信号值或双差值向前与向后分别取 i与 j个信号值或双差值 作为用于判断质心位置的信号值或双差值。
在本发明的另一范例中, 是以连续差值分析出零交会处, 并且将连续 的差值转换为连续的信号值或双差值, 再分析出零交会处相应的信号值或 双差值作为中央的信号值或双差值, 然后以中央的信号值或双差值向前与 向后分别取 i与 j个信号值或双差值作为用于判断质心位置的信号值或双差 值。
假设以第 n个信号值向前及向后分别取 i个及 j个信号值作为质心计算 范围, 依据质心计算范围中的每个信号值 Ck及每个信号值所在位置 Xk判断
其中, 可以是一维度座标 (如 X座标或 Y座标), 或是二维度座 标 (如 (X, Y))。 假设第 k-1个信号值与第 k个信号值间的差值为 A,并且一第 k个 双差值为 DDk = Dk―、 - Dk = (Ck― Ck_、 ) - - Ck ) = 2Ck - Ck_x + Ck+X,假设以第 n个双差值/) Z)„向前及向后分别取 i个及 j个双差值作为质心计算范 围,依据质心计算范围中的每个双差值 判断质心位置 D ) f。, , 如下
»+./
DD centroid k=" n-+ j
∑DDk 其中, 可以是一维度座标 (如 X座标或 Y座标:), 或是二维度座 标 (如 (X, Y))。 本技术领域的普通技术人员可推知当第 k个双差值为 DDk =(Ck -Ck_2)-(Ck+2-Ck) = 2Ck - 2 +Ci+2时的质心位置计算,在此不再 赘述。 在本发明的另一范例中,用于判断质心位置的信号值或双差值是减 去一基础值后再进行质心位置的判断。 例如, 基础值可以是所有信号值 或双差值的平均值、 用于判断质心位置的信号值或双差值两侧多个信号 值或双差值的平均值、 或用于 Λ断质心位置的信号值或双差值两侧相邻 多个非用于判断质心位置的信号值或双 ¾值的平均值, 本技术领域的普 通技术人员可推知其他基础值的决定方式。 例如, 可以是依据一侧至少 一信号值或双差值的一第一比例与另一侧至少一信号值或双差值的一 第二比例来决定基础值。
假设以第 n个信号值向前及向后分别取第 i个信号值 C„_,.与第 j个信 号值 的平均值作为基础 (Base)值 C6flS^ (C4flS ) = C"- , 并且以 第 n个信号值向前及向后分别取 i个及 j个信号值作为质心计算范 围, 依据质心计算范围中的每个信号值 (^4减去基底信号值 C^(, )作为计 算信号值 (CA - C^(, ):), 以判断质心位 SC 。W, 如下。
2 r _r ― 2Ck - C„— , - C„+ ― (Q. -Cn„) , (Ck -Cn+J)
n-i≤ <n+ j ^ Γ· _ f _ Γ1 n-i≤k≤n+j
∑ Χ " ;- '· N+J) ∑XK(2CK ~CN_L -CN+J) ,
Q ― k=n-i _ k=n - i
cnetroid n-i≤k≤n+ j ― C ― C tt-i≤k≤n+ j
∑ ;-' ∑(2Q-C„,-Cn+ ) 其中, 可以是一维度座标 (如 X座标或 Y座标), 或是二维度座 标 (如 (Χ,Υ))。 据此,本发明提供的一第三种位置分析是依据感测资讯中多个差值 分析出质心 (centroid)位置 (重心位置或加权平均位置)作为外部物件相应 的位置。
假设第 k-1个信号值 与第 k个信号值 间的差值为 A。 (Q - C") = /)„—(,.—,) + DN_(I_2) + ' (CK-CN+J) = -(DK+I +DK+2 +— +
2CK -CN ,. -C,
Ct -C,
) +^-(.-2) +.. - + K)-(D^ +DK+2+... + DN+J)
' 2
∑ A -∑DS
、 —厂 ― s=n-(i-]) s=k+\
'k ^base(ij)一
据此, 质心位置 )可以是依据信号值间的差值来求出,其中质 心计算范围中的差值为^-^,/^^,…,^,/^,…,/^ ^换言之,质心 位置 C„„ 可以是以质心计算范围中的差值来计算得出。 例如下列范例,假设要以第 n个信号值向前及向后分别取 1信号值
来判断质心位置 (c 。 ),可以质心计算范围中
计算, 证明如下。
Dn_x =Cn_x -C„_2 D„ =C„-Cn_i =C_ -C„
Dn+2 =Cn+2-Cn c„, + .
2C„_, - C„_2 - Cn+2 —Dn— - Dn
r -C
2C -C. C, D., +£>. - D c„ -c„ r _ 2 B+, -Cn_2-Cn+2 ― Dn_ +Dn +Dn+1 -Dn+2
一
2 2 - G , + X (C„
C
(C — C6flse(22)) + (Crt— C6iWe(2,2)) + (Cn+1 — C
C一 =(H -Dn -Dn+l -Dn+2) + Xn(Dn_l +Dn -Dn+l -Dn+2)
+ ^+1Φη-. +D„ + -Dn+2))l{{Dn_x -D„ -Dn+l -D„,2) +
+Dn-Dn+l +2 ) + (/)„_, +Dn +Dn+l -Dn+2))
本技术领域的普通技术人员可推知以第 n个信号值、差值、或双差 值向前及向后分别取 i个及 j个信号值、 差值、 或双差值以作为质心计 算范围的方式可应用于判断质心位置的信号值、 差值、 或双差值上, 反 之亦然。 . 由上述说明中可推知, 本发明借由对感测资讯的分析, 来进行位置
侦测, 感测资讯包括但不限于初始取得的信号值、 差值或双差值, 亦可 以是包括但不限于由初始取得的感测资讯所转换的信号值、 差值或双差 值。 因此借由分析相应于同一外部物件的两个不同轴向 (如 X轴与 Y轴) 上的一维度或二维度感测资讯, 亦即借由两个不同轴向的一维度或二维 度位置分析, 可获得外部物件在两个不同轴向上的位置 (或座标), 构成 一二维度位置 (或二维度座标)。 本技术领域的普通技术人员可推知上述的一维度位置分析的作业 可以是由前述控制器 160或主机 170来执行。
二维度位置分析 (One Dimension Position Analysis)
二维度感测资讯可以是由多个一维度感测资讯所组成,其中每一个 一维度感测资讯包括相应于多个第一一维度位置的感测资讯, 并且每一 个一维度感测资讯分别相应于一个第二一维度的位置。因此,二维度位置 分析可以是至少包括对多个一维度触敏资分别进行一维度位置分析,亦 即二维度位置分析可以是至少包括多个一维度位置分析。 此外, 在本发明的一第一范例中, 任一外部物件在各第一维度感测 资讯上的第一一维度质心位置, 为一二维度位置 (如二维度座标 (第一一 维度质心位置, 第一维度感测资讯的第二一维度的位置)),可被用来计算 外部物件的二维度质心位置 (或几何中心), 其中每一个一维度质心位置 的加权值可以是外部物件在柑应第一维度感测资讯上的信号值或双差 值 (如第一维度感测资讯上的最邻近一维度质心位置的两信号值或双差 值之一或其平均值、 内插值), 或是外部物件在相应第一维度感测资讯上 的信号值或双差值的总和。 因此,二维度位置分析可以是先对各第.一维度感测资讯的一维度位
置分析, 依据每一个外部物件所相应的至少一二维度位置, 分析出每一 外部物件的二维度质心位置。 此外, 在本发明的一第二范例中, 二维度位置分析可以是包括对一 第一轴向 (或第一一维度)上的多个一维度感测资讯分别进行一维度位置 分析,依据每一个外部物件在第一轴向上所相应的至少一一维度位置,分 - 析出每一个外部物件在第一轴向上的第一一维度质心位置。同样地,另外 对一第二轴向 (或第二维度)上的多个一维度感测资讯进行一维度位置分 析,依据每一个外部物件在第二轴向上所相应的至少一一维度位置,分析 出每一个外部物件在第二轴向上的第二一维度质心位置。 借由配对每一 个外部物件在第一轴向上的第. "一维度质心位置与在第二轴向上的第 二一维度质心位置, 可分析出每一个外部物件的一二维度位置。 换言之,二维度位置分析可以是借由两个不同轴向上的二维度感测 资讯 (如第一轴向上的二维度感测资讯与第二轴向上的二维度感测资讯)' 进行一维度位置分析, 来分析出每一个外部物件的二维度位置。 另外, 在本发明的一第三范例中, 二维度位置分析可以是在一第一 轴向的多个一维度感测资讯分析相应于各外部物件的一维度质心 位置,并依据各一维度感测资讯相应的二维度位置,判断在第一轴向上相 应于每一个外部物件的每一个一维度质心位置的二维度位置。 二维度位 置分析另外在一第二轴向的多个一维度感测资讯分析相应于各外部物 件的一维度 心位置,并依据各一维度感测资讯相应的二维度位置,判断 在第一轴向上相应于每一个外部物件的每一个一维度质心位置的二维 度位置。 二维度位置分析再依据每一个外部物件在第一、 第二轴向上相 应的所有一维度质心位置的二维度位置分析出出二维度质心位置。 本技术领域的普通技术人员亦可推知,二维度感测资讯可以经由影 像处理程序来判断出各外部物件的位置, 例如可以用分水岭演算法或其 他影像处理来进行位置分析。 又例如可以是以分水岭演算法分析出各分
水领的位置, 再以各分水领的位置邻近的感测资讯进行质心位置的计 算, 以取得较精确的位置。 在本发明的一第四范例中,初始取得的多个一维度感测资讯是由信 号值或双差值表示, 构成一二维度感测资讯所呈现的影像 (或阵列), 可 以是用分水岭演算法或其他影像处理来进行位置分析。 亦可以是利用连 接元件 (connected component)演算法,将影像中相连的部份分析出来,判 断出每一个外部物件的影像, 进一步分析出位置或是哪种外部物件, 如 手、 手掌或笔。 在本发明的一第五范例中,初始取得的多个一维度感测资讯是由差 值表示, 再转换成为信号值或双差值, 以构成一二维度感测资讯所呈现 的影像 (或阵列), 可以是用分水岭演算法或其他影像处理来进行位置分 析。 : 在本发明的一第六范例中,初始取得的多个一维度感测资讯是由差 值表示, 经由对每一个一维度感测资讯的位置分析, 判断出每一个零交 会处的位置, 以及每个零交会处的位置上的信号值或双差值, 以构成一 二维度感测资讯所呈现的影像 (或阵列), 可以是用分水岭演算法或其他 影像处理来进行位置分析。 零交会处的双差值可以是直接相邻的两个差值来产生,例如零交会 处位于第 k-1 个差值与第 k个差值之间, 零交会处的双差值可以是 DDk = Dk_, -Dk。 零交会处的信号值可以是将整个代表一维度感测资讯的 差值转换成信号值后再产生, 亦可以是以最接近零交会处的多个差值来 产生。 例如, 零交会处最近第 n个信号值, 分别以第 n个信号值向前及 向后分别取第 i个信号值 c„_,.与第 j个信号值 /,,+的平均值作为基础 (Base) 值 C , )(C ) = ^^ ), 以 -c = 来作为信号 值, 贝 iJ
( H,—,) + Ρη-α-2) + ... + Ρη) - ίΡπ+ι + Ρπ+2 + ... + Dn+j)
_ 2 换言之, 由第 n-G-l)个差值至第 n+j个之间的差值, 可判断出零交会处 的信号值。
在本发明的一第七范例中, 初始取得的多个一维度感测资讯是由信号 值与双差值表示, 再转换成为差值, 经由对每一个一维度感测资讯的位置 分析, 判断出每一个零交会处的位置, 配合每个零交会处的位置上的信号 值或双差值, 以构成一二维度感测资讯所呈现的影像 (或阵列), 可以是用分 水岭演算法或其他影像处理来进行位置分析。
在本发明的一第八范例中, 在取得第一轴向上的二维度感测资讯的同 时或过程中, 亦取得第二轴向上的一维度感测资讯。 在进行第一轴向上的 二维度感测资讯的位置分析后, 可获得每一个外部物件在第一轴向上的一 维度位置或二维度位置。 #外, 在进行第二轴向上的一维度感测资讯的位 置分析后, 可获得每一个外部物件在第二轴向上的- -维度位置。 第二轴向 上的一维度位置可与第一轴向上的一维度位置配对成为二维度位置, 亦可 以用来取代或校正第一轴向上的二维度位置中的第二轴向上的位置。
本技术领域的普通技术人员可推知上述的二维度位置分析的作业可以 是由前述控制器 160或主机 170来执行。 此外, 在本发明的一范例中, 相 应于同一外部物件接近或触碰的各一维度质心位置与至少一个其他相应于 相同外部物件接近或触碰的一维度质心位置的一维度距离或二维度距离在 一门槛限值内。 在本发明的另一范例中, 相应于同一外部物件接近或触碰 的各一维度质心位置的加权值大于一门槛限值。
在以下说明中, 一触碰相关感测资讯可以是一感测资讯中的一个触碰 相关感测资讯或多个触碰相关感测资讯之一, 针对一触碰相关感测资讯的 相关操作包括但不限于应用于特定的触碰相关感测资讯, 亦可能应于可适 用于本发明的所有触碰相关感测资讯。
在本发明的一范例中, 零交会处的位置可以是以触碰相关感测资讯的 一对正值与负值来判断。 零交会处是位于一正值与一负值间, 由正值与负 值及相关位置可求出一斜率, 依据斜率可推估零交会处的位置, 即依据斜 率判断正值与负值间的连线位于零值的位置。
在本发明的另一范例中,前述一对正值与负值可以是分别以一正门槛值 Tp与一负门槛值 Tn来判断,如图 5A所示, 正值可以是位于点 a、 点 b, 或 是最接近点 a的值 (如第 N+1个差值)或最接近点 b的值 (如第 N+3个值)。同 理, 负值可以是位于点 c、 点 d, 或是最接近点 c的值 (如第 N+4个差值)或
最接近点 d的值 (如第 N+6个值)。 例如, 正值为第 N+3个值, 并且负值为 第 N+4个值, 由正值的高点与负值的低点间虚拟的一条线, 可判断出一斜 率, 依据斜率可计算出这条线在零值的位置, 即零交会处 Z。
在本发明的一范例中, 零交会处的位置可以是以触碰相关感测资讯的 最大值 (正峰)与最低点 (负峰)来判断, 如图 5B所示。 由最大值与最小值及 相关位置可求出一斜率, 依据斜率可推估零交会处的位置, 即依据斜率判 断最大值与最小值间的连线位于零值的位置。 例如, 触碰相关感测资讯是 位于第 N个差值至第 N+6个差值间,最大值与最小值分别为第 N+2个差值 与第 N+5个差值, 由最大值的高点与最小值的低点间可虚拟出一条线及这 条线的斜率, 零交会处被假设为这条线上位于零值的位置, 可依据斜率来 计算出来。
前述的最大值与最小值可以是以前述的门槛限值判断出来, 例如正门 槛限值 Tp与负门槛限值 Τη可以是固定或动态调整, 让最大值与最小值分 别突出于正门槛限值 Tp与负门槛限值 Tn。 亦可以是分别依据正 槛限值 Tp与负门槛限值 Tn取得大于正门槛限值 Tp的正值群组,及小于负门槛限 值 Τιι的负值群组, 分别由正值群组与负值群组判断出最大值与最小值。 :: 一感测资讯中的触碰相关感测资讯可以是一个或多个, 亦即感测装置 可能受到一个或多个外部物件的接近或触碰。例如图 5C所示, 感测资讯包 含两个触碰相关感测资讯, 每一个触碰相关感测资讯可分别依据正门槛限 值 Tp与负门槛限值 Tn判断出一正值群组 (或最大值)与一负值群组 (或最小 值), 并进一步判断出零交会处 Z1与 Z2。 在本发明中, 零交会处的判断包 括但不限于判断零交会处的位置与数量。
事实上, 对零交会处的判断也等于连带地判断有几个外部物件的接近 或触碰。例如图 5C判断出两个零交会处, 亦等于判断出两个外部物件的接 近或触碰0
当两个外部物件的接近或触碰过于靠近时, 将构成一个触碰相关感测 资讯, 如图 5D所示, 上方的曲线为信号值, 下方的折线为相应的差值, 由 曲线观察, 可能具有两个外部物件的接近或触碰, 但是由折线观察, 却具 有三个零交会处。
在本发明的一范例中, 是依据每一对正值与负值的升降顺序判断零交 会处。 例如只判断先正值后负值的每一对正值与负值间的零交会处, 不判 断先负值后正值的每一对正值与负值间的零交会处。 或者是, 只判断先负 值后正值的每一对正值与负值间的零交会处, 不判断先正值后负值的每一 对正值与负值间的零交会处。如图 5D所示, 是只判断先正值后负值的每一 对正值与负值间的零交会处, 如此可判断出两个零交会处。 亦即, 当单一 物件接近或触碰, 并且触碰相关感测资讯是先正值再负值时, 只判断先正
值后负值的每一对正值与负值间的零交会处, 反之亦然。
在本发明的另一范例中, 是判断位于奇数位置的零交会处。 如图 5E所 示, 是分别判断第一个零交会处 Z3、第三个零交会处 Z4与第五个零交会 处 Z5。 据此, 本发明可以在具有多个零交会处的触碰相关感测资讯分析出 每一个外部物件接近或触碰的位置, 并且本发明可以是在具有奇数个零交 会处的触碰相关感测资讯分析出每一个外部物件接近或触碰的位置, 其中 分析出来的位置数量不同于零交会处数量。
前述分析出来的位置数量不同于零交会处数量包括但不限于零交会处 数量大于分析出来的位置数量, 亦可以零交会处数量小于分析出来的位置 数量, 例如由具有单零交会处的触碰感测资讯判断出两个外部物件的接近 或触碰。
在本发明的一较佳范例中, 是利用一预设范围在多个感测器的信号值 中取得第一个超过预设范围的感测器 I,与第一个未达预设范围的感测器 J 的前一感测器 J-l, 根据感测器 Γ与感测器 J-1来计算两质心或几何中 心, 以计算出两位置。 此外, 在本发明的一较佳范例中, 质心或几何中心 是依据一感测器两侧距离第 κ个的感测器的信号值的平均值来计算基础 值。座标的计算为感测器两侧距离第 K-1个感测器内的每一个感测器的 ((信 号值-基础值 )*座标值)的总和除以感测器两侧距离第 K-1个感测器内的每一 个感测器的座标值或信号值的总和,其中信号值与基础值的差值为负者以 0 表示
请参照图 6A与图 6B, 共有 11个感测器,包含感测器 1~11。 图 6A 中,感测器 1~11 的信号值分别为(0,0,0,3,4,4,5,3,0,0,0), 差值分别为 (0,0,3,1,0,1,-2,-3,0,0), 并且预设范围为 1.9至- 1.9, 因此前述感测器 I与感 测器 J-1分别为感测器 4与感测器 7。 相应于感测器 4的座标是依据距感 测器 4两侧第 2个感测器的平均值来计算,分别为感测器 2的 0与感测器 6 的 4, 其平均值为 2, 因此座标为 5.17(0*3.5+1*4.5+2*5.5)/(0+1+2),同理,相 应于感测器 7的座标值 6.33,两者间距离为 1.17。同样地,如图 6B所示,感测 器 I与感测器 J-1分别为感测器 4与感测器 7, 相应于感测器 4与感测器 7的座标分别为 5.5与 6.04, 两者间的距离为 0.54。 因此当第一门槛限值为 0.8时, 可分辨出图 6A为双指触碰, 并且图 6B单指触碰。
在图 6A的范例中, 可以是以 5.17与 6.33分别作为两指触碰的位置。 在图 6B的范例中,可以是以 5.5与 6.04的平均值或是零交会处的位置作为 单指触碰的位置。 比较图 6A与图 6B, 虽然触碰相关感测资讯的值的数量 相同, 并且都是具单一零交会处, 但是依据本发明提供的判断方式可有效 地区隔出触碰相关感测资讯是单指触碰还是双指触碰。
上述感测器 I与感测器 J-1或 J的决定方式仅为本发明举例之用,并非用
以限定本发明, 本技术 域的普通技术人员可推知其他由触碰相关感测资 讯决定两个位置, 再依据这两个位置在触碰相关感测资讯上的质心位置或 几何中心的距离, 来判断是单指触碰还是双指触碰的方式。 例如, 感测器 I 与感测器 J分别是距触碰相关感测资讯第 K个感测器。 又例如, 感测器 I 与感测器 J是依据双差动感测资讯的一对零交会处来决定,如是依据相应零 交会处的信号值, 或是相应于零交会处距第 K个的信号值。 由触碰相关感 测资讯决定两个位置的方式可以是随感测器间的距离、 信号特性、 配置感 测器的载体或基板的厚度而改变。
请参照图 7, 是依据本发明的第一实施例提出的一种分析位置的方法。 首先, 如步骤 710所示, 取得一感测资讯, 感测资讯包括至少一个零交会 处, 其中每一个零交会处位于一正值与一负值间。 之后, 如步骤 720 所 示, 由感测资讯分析出与零交会处不同数量的多个位置。 换言之, 除了能 在零交会处的数量等于外部物件接近或触碰的数量时, 分析出每一个位 置, 更可以在零交会处的数量不等于外部物件接近或触碰的数量时, 分析 出每 --个位置。
如先前所述, 零交会处的数量可以是大于或小于被分析出来的位置的 数量。 例如, 由奇数个零交会处中判断每一个奇数位置的零交会处, 以分 析出少于零交会处的数量的位置。 又例如, 可以是在具单零交会处的触碰 相关感测资讯判断是单一物件的接近或触碰 (如单触),或是多个物件的接近 或触碰 (如双触)。 -'
零交会处的数量亦可以是偶数个, 例如感测资讯是双差动感测资讯,每 一个位置是依据一对零交会处或是一对零交会处间的峰来分析出来。
感测资讯可以是依据多个感测器的信号产生。 例如, 感测资讯为差动 感测资讯, 差动感测资讯的每一个值是依据这些感测器中的一对感测器的 信号产生。 又例如, 感测资讯为双差动感测资讯, 双差动感测资讯的每一 个值是依据这些感测器中的三个感测器的信号产生。 此外, 感测资讯亦可 以是依据多个信号值、 多个差值或多个双差值组成的另一个感测资讯产生 (如前述的感测资讯的转换)。
前述步骤 710与 720可以是由控制器 160或主机 170来执行。 此外,感 测器的取得可以是先由控制器 160依据多个感测器的信号产生另一个感测 资讯, 再由控制器 160或主机 170依据另一个感测资讯转换步骤 710所述 的感测资讯。 本实施例的其他相关细节已揭示于先前说明中, 在此不再赘 述。
请参照第八图所示, 是依据本发明的第二实施例提供的一种分析位置 的方法。 首先, 如步骤 810所述, 取得一感测资讯。 如先前所述, 感测器 可以由控制器 160依据多个感测器的信号产生, 也可以是由控制器 160依
据多个感测器的信号产生一初始感测资讯后, 再由控制器 160或主机 170 转换成歩骤 810所述的感测资讯。
接下来, 如步骤 820所述, 依据一第一门槛限值在该感测资讯中决定 至少一第一起始位置。 例如图 5A与图 5C及相关叙述所示。 再接下来, 如 步骤 830所述, 由每一个第一起始位置朝一第一方向的一第一范围进行一 零交会处位置分析以分别判断出一零交会处的位置, 其中每一个零交会处 位于一正值与一负值间。
在本发明的一范例中, 是以第一门槛限值决定至少一第一起始范围,每 一个第一起始位置位于第一起始范围内的唯一值或第一起始范围内的最大 值、 最前面的值、 或最后面的值。 第一范围可以是由第一起始位置至零交 会处的前一值、 零交会处、 或零交会处的后一值。.例如, 以正门槛限值 Tp 决定出包括点 a、最大值与点 b的第一起始范围,第一起始位置可以是点 a、 最大值或点 b。此外, 第一方向可以是向后, 并且第一范围为第一起始位置 向后到第一个异号值 (负值)或零值。 又例如, 以正门槛限值 Tn决定出包括 点(:、 最小值与点 d的第一起始范围, 第一起始位置可以是点0、 最小值或 点 d。此外, 第一方向可以是向前, 并且第一范围为第一起始位置向前到第 一个异号值 (正值)或零值。此外, 以第一门槛限值^ ^定第一起始范围或第一 起始位置可以是先前所述利用二值化值的方式来进行,如图 4A及相关说明 所述。
在本发明的另一范例中, 是依据第一个异号值与零交会处相邻另一值 分析出零交会处的位置。 换言之, 是依据零交会处相邻的一对正值与负值 来分析出零交会处的位置。
再本发明的再一范例中, 是以每一个零交会处的位置作为所述至少一 外部物件的位置, 或者是以每一个零交会处的位置分别决定相应于至少一 外部物件之一的位置。 例如, 依据每一个零交会处的位置分别计算出一质 心位置或几何中心, 来作为所述至少一外部物件之一的位置。 质心位置或 几何中心可以是依据零交会处位置, 可以是直接以感测资讯计算得出, 也 可以是以相应于感测资讯的多个信号值、 多个双差值计算得出。
请参照图 5F, 当外部物件相互接近值, 第一门槛限值可能无法找到相 应于每一个外部物件的第一起始位置, 这是因为不同外部物件造成的部份 的正值与负值相互抵消。 为了解决这样的问题, 本发明更包括如步骤 840 及 850所述, 依据一第二门槛限值在感测资讯中决定至少一第二起始位 置,并且由每一个第一起始位置朝一第二方向的一第二范围进行零交会处 位置分析以分别判断出该零交会处的位置。
在本发明的一范例中, 是以第二门槛限值决定至少一第二起始范围,每 一个第二起始位置位于第二起始范围内的唯一值或第二起始范围内的最大
值、 最前面的值、 或最后面的值。 第二范围可以是由第二起始位置至零交 会处的前一值、 零交会处、 或零交会处的后一值。 例如, 以正门槛限值 Tp 决定出包括点 a、最大值与点 b的第二起始范围,第二起始位置可以是点 a、 最大值或点 b。此外, 第二方向可以是向后, 并且第二范围为第二起始位置 向后到第一个异号值 (负值)或零值。 又例如, 以正门槛限值 Tn决定出包括 点(:、 最小值与点 d的第二起始范围, 第二起始位置可以是点0、 最小值或 点 d。此外, 第二方向可以是向前, 并且第二范围为第二起始位置向前到第 一个异号值 (正值)或零值。此外, 以第二门槛限值决定第二起始范围或第二 起始位置可以是先前所述利用二值化值的方式来进行,如图 4A及相关说明 所述。
在本发明的一范例中, 第一门槛限值与第二门槛限值之一为正值, 并 且第一门槛限值与第二门槛限值的另一为负值。 此外, 第一方向与第二方 向相反。
在本发明的另一范例中, 前述步骤 810至 850适用于具奇数个零交会 处的感测资讯或触碰相关感测资讯, 并且分析出来的零交会处为位置奇数 位置的零交会处。 在本发明中, 奇数位置的零交会处是指在全部零交会处 中依序出现的奇数位置的零交会处。
前述步骤 810至 850可以是由控制器 160或主机 170来执行。 此外,感 测器的取得可以是先由控制器 160依据多个感测器的信号产生另一个感测 资讯, 再由控制器 160或主机 170依据另一个感测资讯转换步骤 810所述 的感测资讯。 本实施例的其他相关细节已揭示于先前说明中, 在此不再赘 述。
请参照图 9,为依据本发明的第三实施例所提供的一种在感测装置侦测 指触的方法。 首先, 如步骤 910所示, 取得一感测资讯。 接下来, 如步骤 920所示, 依据一正门槛判断感测资讯中是否存在大于正门槛的正值。再接 下来, 如步骤 930所示, 依据一负门槛判断该感测资讯中是否存在小于负 门槛的负值。 之后, 如步骤 940所示, 当存在大于正门槛的正值与小于负 门槛的负值时判断位于大于正门槛的正值与小于负门槛的负值间的零交会 处。
在本发明的一范例中, 所述零交会处为触碰的位置, 并且零交会处的 数量为触碰的数量。 此外, 零交会处的判断可以是判断位于一第一对正值 与负值间的零交会处, 第一对正值与负值是先正值再负值, 其中零交会处 的判断可以是包括不判断位于一第二对正值与负值间的零交会处, 第二对 正值与负值是先负值再正值。 相反地, 零交会处的判断可以是判断位于一 第一对正值与负值间的零交会处, 第一对正值与负值是先负值再正值, 其 中零交会处的判断可以是包括不判断位于一第二对正值与负值间的零交会
处, 第二对正值与负值是先正值再负值。
前述步骤 910至 940可以是由控制器 160或主机 170来执行。 此外,感 测器的取得可以是先由控制器 160依据多个感测器的信号产生另一个感测 资讯, 再由控制器 160或主机 170依据另一个感测资讯转换步骤 910所述 的感测资讯。 例如, 感测资讯是控制器 160依据多个感测器的信号产生,并 且这些感测器的每一个值是分别依据这些感测器中的一对感测器的信号产 生。 又例如, 感测资讯是依据多个信号值产生, 并且该些信号值是控制器 160依据多个感测器的信号产生。 再例如, 感测资讯是依据多个双差值 产生, 并且每一个双差值是控制器 160依据多个感测器的三个感测器的信 号产生。 本实施例的其他相关细节已揭示于先前说明中, 在此不再赘述。
以上所述, 仅是本发明的较佳实施例而已, 并非对本发明作任何形式 止的限制, 虽然本发明已以较佳实施例揭露如上, 然而并非用以限定本发 明,任何熟悉本专业的技术人员, 在不脱离本发明技术方案范围内,当可利用 上述揭示的技术内容作出些许更动或修饰为等同变化的等效实施例,但凡是 未脱离本发明技术方案内容, 依据本发明的技术实质对以上实施例所作的 任何简单修改、 等同变化与修饰,均仍属于本发明技术方案的范围内。 ' 工业应用性
本发明是有关于一种分析位置的方法与装置, 借由对包括至少一零交 会处的感测资讯进行一分析, 可分析出与零交会处不同数量的多个位置。 当被分析出来的位置数量不同于零交会处的数量时, 分析出来的位置数量 为多个。
Claims
权
1、 一种分析位置的方法, 其特征在于其包括以下步骤:
取得一感测资讯, 该感测资讯包括至少一个零交会处, 其中每一个零 交会处位于一正值与一负值间; 以及
由该感测资讯分析出与该至少一零交会处不同数量的多个位置。
求
2、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的至 少一零交会处的数量大于该至少一位置的数量。
3、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的零 交会处为奇数个。
4、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的至 少一位置是依据位于奇数位置的零交会处分析出来。
5; 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的至 少一零交会处的数量为偶数个。
.6、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的至 少一零交会处的数量小于该至少一位置的数量。
7、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的至 少一零交会处的数量为一个, 并且该至少一位置的数量为两个。
8、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的感 测资讯为双差动感测资讯, 该双差动感测资讯的每一个值是依据该些感测 器中的三个感测器的信号产生。
9、 根据权利要求 1所述的分析位置的方法, 其特征在于其中所述的感 测资讯为差动感测资讯, 该差动感测资讯的每一个值是依据该些感测器中 的一对感测器的信号产生。
10、 根据权利要求 1所述的分析位置的方法, 其特征在于其更包括: 由该感测资讯分析出与该至少一零交会处数量相同的至少一位置。
一种分析位置的装置, 其特征在于其包括:
一控制器或一主机, 执行下列作业: ' 取得一感测资讯, 该感测资讯包括至少一个零交会处,其中每一个零交 会处位于一正值与一负值间; 以及
由该感测资讯分析出与该至少一零交会处不同数量的多个位置。
12、 根据权利要求 11所述的分析位置的装置, 其特征在于其中所述的 至少一零交会处的数量大于该至少一位置的数量。
13、 根据权利要求 11 所述的分析位置的装置,其特征在于其中所述的 零交会处为奇数个。
14、 根据权利要求 11 所述的分析位置的装置,其特征在于其中所述的
至少一位置是依据位于奇数位置的零交会处分析出来。
15、 根据权利要求 11所述的分析位置的装置, 其特征在于其中所述的 至少一零交会处的数量为偶数个。
16、 根据权利要求 11 所述的分析位置的装置,其特征在于其中所述的 至少一零交会处的数量小于该至少一位置的数量。
17、 根据权利要求 11所述的分析位置的装置, 其特征在于其中所述的 至少一零交会处的数量为一个, 并且该至少一位置的数量为两个。
18、 根据权利要求 11所述的分析位置的装置,其特征在于其更包括: 包括多个感测器的一感测装置;
其中该感测资讯为双差动感测资讯, 该双差动感测资讯的每一个值是 依据该些感测器中的三个感测器的信号产生。
19、 根据权利要求 11所述的分析位置的装置,其特征在于其更包括: 包括多个感测器的一感测装置;
其中该感测资讯为差动感测资讯, 该差动感测资讯的每一个值是依据 该些感测器中的一对感测器的信号产生。
20、 根据权利要求 11 所述的分析位置的装置,其特征在于其中所述的 控制器或该主机, 更包括执行下列作业:
由该感测资讯分析出与该至少一零交会处数量相同的至少一位置。
21、 一种分析位置的方法, 其特征在于其包括以下步骤:
取得一感测资讯;
依据一第一门槛限值在该感测资讯中决定至少一第一起始位置; 以及 由每一个第一起始位置朝一第一方向的一第一范围进行- 零交会处位 置分析以分别判断出一零交会处的位置, 其中每一个零交会处位于一正值 与一负值间。
22、 根据权利要求 21所述的分析位置的方法, 其特征在于其中所述的 第一范围是由该第一起始位置至该零交会处的前一值、 该零交会处、 或该 零交会处的后一值。
23、 根据权利要求 21所述的分析位置的方法, 其特征在于其中所述的 第一门槛限值决定至少一第一起始范围, 每一个第一起始位置位于该第一 起始范围内的唯一值或该第一起始范围内的最大值、 最前面的值、 或最后 面的值。
24、 根据权利要求 23所述的分析位置的方法, 其特征在于其中位于该 第一门槛限值为一正值或一负值, 并且该第一方向为向前或向后。
25、 根据权利要求 21所述的分析位置的方法, 其特征在于其中所述的 零交会处位置分析是依据该零交会处前与后的相邻值来分析出该零交会处 的位置。
26、 根据权利要求 21所述的分析位置的方法, 其特征在于其更包括: 依据每一个零交会处的位置分别决定相应于至少一外部物件之一的位 置。 .
27、 根据权利要求 21所述的分析位置的方法, 其特征在于其更包括. - 依据一第二门槛限值在该感测资讯中决定至少一第二起始位置; 以及 由每一个第二起始位置朝一第二方向的一第二范围进行该零交会处位 置分析以分别判断出该零交会处的位置。
28、 根据权利要求 21所述的分析位置的方法, 其特征在于其中所述的 第二范围是由该第二起始位置至该零交会处的前一值、 该零交会处、 或该 零交会处的后一值。
29、 根据权利要求 21所述的分析位置的方法, 其特征在于其中所述的 第二门槛限值决定至少一第二起始范围, 每一个第二起始位置位于该第二 起始范围内的唯一值或该第二起始范围内的最大值、 最前面的值、 或最后 面的值。
30、 根据权利要求 23所述的分析位置的方法, 其特征在于其中位于该 '第二门槛限值为一正值或一负值,: 并且该第二方向为向前或向后, 其中该 第一方向与该第二方向相反。 : :
31、 一种分析位置的装置, 其特征在于其包括:
一控制器或一主机, 执行下列作业:
取得一感测资讯; '
依据一第一门槛限值在该感测资讯中决定至少一第一起始位置; 以及 由每一个第一起始位置朝一第一方向的一第一范围进行一零交会处位 置分析以分别判断出一零交会处的位置, 其中每一个零交会处位于一正值 与一负值间。
32、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 第一范围是由该第一起始位置至该零交会处的前一值、 该零交会处、 或该 零交会处的后一值。
33、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 第一门槛限值决定至少一第一起始范围, 每一个第一起始位置位于该第一 起始范围内的唯一值或该第一起始范围内的最大值、 最前面的值、 或最后 面的值。
34、 根据权利要求 33所述的分析位置的装置, 其特征在于其中位于该 第一门槛限值为一正值或一负值, 并且该第一方向为向前或向后。
35、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 零交会处位置分析是依据该零交会处前与后的相邻值来分析出该零交会处 的位置。
36、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 控制器或该主机, 更包括执行下列作业:
依据每一个零交会处的位置分别决定相应于至少一外部物件之一的位 置。
37、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 控制器或该主机, 更包括执行下列作业:
依据一第二门槛限值在该感测资讯中决定至少一第二起始位置; 以及 ^ 由每一个第二起始位置朝一第二方向的一第二范围进行该零交会处位 置分析以分别判断出该零交会处的位置。
38、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 第二范围是由该第二起始位置至该零交会处的前一值、 该零交会处、 或该 零交会处的后一值。
39、 根据权利要求 31所述的分析位置的装置, 其特征在于其中所述的 第二门槛限值决定至少一第二起始范围, 每一个第二起始位置位于该第二 起始范围内的唯一值或该第二起始范围内的最大值、 最前面的值、 或最后 面的值。
40、 根据权利要求 33所述的分析位置的装置, 其特征在于其中位于该 第二门槛限值为一正值或一负值', 并且该第二方向为向前或向后, 其中该 第一方向与该第二方向相反。
41、 一种在感测装置侦测指触的方法, 其特征在于其包括以下步骤: 取得一感测资讯; Λ
依据一正门槛判断该感测资讯中是否存在大于正门槛的正值;
依据一负门槛判断该感测资讯中是否存在小于负门槛的负值; 以及 当存在大于正门槛的正值与小于负门槛的负值时判断位于大于正门槛 的正值与小于负门槛的负值间的零交会处。
42、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的零交会处为触碰的位置。
43、 根据权利要求 42所述的在感测装置侦测指触的方法, 其特征在于 其中所述的零交会处的数量为触碰的数量。
44、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的零交会处的判断是判断位于一第一对正值与负值间的零交会 处, 该第一对正值与负值是先正值再负值。
45、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的零交会处的判断包括不判断位于一第二对正值与负值间的零交 会处, 该第二对正值与负值是先负值再正值。
46、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于
其中所述的零交会处是位于一第一对正值与负值间, 该第一对正值与负值 是先负值再正值。
47、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的零交会处的判断包括不判断位于一第二对正值与负值间的零交 会处, 该第二对正值与负值是先正值再负值。
48、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的感测资讯是依据多个感测器的信号产生, 并且该些感测器的每 一个值是分别依据该些感测器中的一对感测器的信号产生。
49、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的感测资讯是依据多个信号值产生, 并且该些信号值是依据多个 感测器的信号产生。
50、 根据权利要求 41所述的在感测装置侦测指触的方法, 其特征在于 其中所述的感测资讯是依据多个双差值产生, 并且每一个双差值是依据多 个感测器的三个感测器的信号产生。
51、 一种在感测装置侦测指触的装置, 其特征在于其包括:
一控制器或一主机, 执行下列作业:
取得一感测资讯;
依据一正门槛判断该感测资讯中是否存在大于正门槛的正值; 依据一负门槛判断该感测资讯中是否存在小于负门槛的负值; 以及 当存在大于正门槛的正值与小于负门槛的负值时判断位于大于正门槛 的正值与小于负门槛的负值间的零交会处。
52、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的零交会处为触碰的位置。
53、根据权利要求 52所述的在感测装置侦测指触的装置,其特征在于其 中所述的零交会处的数量为触碰的数量。
54、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的零交会处的判断是判断位于一第一对正值与负值间的零交会 处,该第一对正值与负值是先正值再负值。
55、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的零交会处的判断包括不判断位于一第二对正值与负值间的零交会 处, 该第二对正值与负值是先负值再正值。 、
56、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的零交会处是位于一第一对正值与负值间, 该第一对正值与负值是 先负值再正值。
57、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的零交会处的判断包括不判断位于一第二对正值与负值间的零交会
处, 该第二对正值与负值是先正值再负值。
58、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的感测资讯是依据多个感测器的信号产生, 并且该些感测器的每一 个值是分别依据该些感测器中的一对感测器的信号产生。
59、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的感测资讯是依据多个信号值产生, 并且该些信号值是依据多个感 测器的信号产生。
60、根据权利要求 51所述的在感测装置侦测指触的装置,其特征在于其 中所述的感测资讯是依据多个双差值产生, 并且每一个双差值是依据多个 感测器的三个感测器的信号产生。
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP10821557.5A EP2527958A4 (en) | 2009-10-09 | 2010-10-08 | METHOD AND APPARATUS FOR LOCAL ANALYSIS |
CN2010105026512A CN102043509B (zh) | 2009-10-09 | 2010-10-08 | 分析位置的方法与装置 |
PCT/CN2010/001562 WO2011041948A1 (zh) | 2009-10-09 | 2010-10-08 | 分析位置的方法与装置 |
Applications Claiming Priority (7)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US25005109P | 2009-10-09 | 2009-10-09 | |
US61/250,051 | 2009-10-09 | ||
US29825210P | 2010-01-26 | 2010-01-26 | |
US29824310P | 2010-01-26 | 2010-01-26 | |
US61/298,243 | 2010-01-26 | ||
US61/298,252 | 2010-01-26 | ||
PCT/CN2010/001562 WO2011041948A1 (zh) | 2009-10-09 | 2010-10-08 | 分析位置的方法与装置 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2011041948A1 true WO2011041948A1 (zh) | 2011-04-14 |
Family
ID=50483234
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/CN2010/001562 WO2011041948A1 (zh) | 2009-10-09 | 2010-10-08 | 分析位置的方法与装置 |
Country Status (3)
Country | Link |
---|---|
EP (1) | EP2527958A4 (zh) |
CN (1) | CN102043509B (zh) |
WO (1) | WO2011041948A1 (zh) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109256111A (zh) * | 2017-07-13 | 2019-01-22 | 卡西欧计算机株式会社 | 检测装置、电子乐器及检测方法 |
Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI503701B (zh) | 2012-07-20 | 2015-10-11 | 接近感測方法 | |
CN107967083B (zh) * | 2017-12-18 | 2021-06-01 | 海信视像科技股份有限公司 | 触摸点的确定方法及装置 |
Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4639720A (en) | 1981-01-12 | 1987-01-27 | Harris Corporation | Electronic sketch pad |
TW200401222A (en) * | 2002-05-17 | 2004-01-16 | 3M Innovative Properties Co | Correction of memory effect errors in force-based touch panel systems |
CN101105733A (zh) * | 2007-05-16 | 2008-01-16 | 广东威创日新电子有限公司 | 一种多点触摸定位方法 |
US20080158175A1 (en) * | 2007-01-03 | 2008-07-03 | Apple Inc. | Minimizing mismatch during compensation |
CN101261553A (zh) * | 2007-03-07 | 2008-09-10 | 三星电子株式会社 | 显示装置及驱动该显示装置的方法 |
CN101470556A (zh) * | 2007-12-26 | 2009-07-01 | 三星电子株式会社 | 显示装置和驱动所述显示装置的方法 |
Family Cites Families (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5051545A (en) * | 1990-04-06 | 1991-09-24 | Summagraphics Corporation | Digitizer with serpentine conductor grid having non-uniform repeat increment |
US5113041A (en) * | 1990-12-28 | 1992-05-12 | At&T Bell Laboratories | Information processing |
TW408277B (en) * | 1996-11-15 | 2000-10-11 | Alps Electric Co Ltd | Small current detector circuit and locator device using the same |
JP3910019B2 (ja) * | 2000-07-04 | 2007-04-25 | アルプス電気株式会社 | 入力装置 |
US7254775B2 (en) * | 2001-10-03 | 2007-08-07 | 3M Innovative Properties Company | Touch panel system and method for distinguishing multiple touch inputs |
CN100419655C (zh) * | 2005-04-08 | 2008-09-17 | 鸿富锦精密工业(深圳)有限公司 | 触摸式感应装置 |
CN100419657C (zh) * | 2005-06-20 | 2008-09-17 | 义隆电子股份有限公司 | 电容式触控板的多物件检测方法 |
US8111243B2 (en) * | 2006-03-30 | 2012-02-07 | Cypress Semiconductor Corporation | Apparatus and method for recognizing a tap gesture on a touch sensing device |
US20080036473A1 (en) * | 2006-08-09 | 2008-02-14 | Jansson Hakan K | Dual-slope charging relaxation oscillator for measuring capacitance |
US7777732B2 (en) * | 2007-01-03 | 2010-08-17 | Apple Inc. | Multi-event input system |
JP4945345B2 (ja) * | 2007-07-03 | 2012-06-06 | 株式会社 日立ディスプレイズ | タッチパネル付き表示装置 |
-
2010
- 2010-10-08 WO PCT/CN2010/001562 patent/WO2011041948A1/zh active Application Filing
- 2010-10-08 EP EP10821557.5A patent/EP2527958A4/en not_active Withdrawn
- 2010-10-08 CN CN2010105026512A patent/CN102043509B/zh active Active
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4639720A (en) | 1981-01-12 | 1987-01-27 | Harris Corporation | Electronic sketch pad |
TW200401222A (en) * | 2002-05-17 | 2004-01-16 | 3M Innovative Properties Co | Correction of memory effect errors in force-based touch panel systems |
US20080158175A1 (en) * | 2007-01-03 | 2008-07-03 | Apple Inc. | Minimizing mismatch during compensation |
CN101261553A (zh) * | 2007-03-07 | 2008-09-10 | 三星电子株式会社 | 显示装置及驱动该显示装置的方法 |
CN101105733A (zh) * | 2007-05-16 | 2008-01-16 | 广东威创日新电子有限公司 | 一种多点触摸定位方法 |
CN101470556A (zh) * | 2007-12-26 | 2009-07-01 | 三星电子株式会社 | 显示装置和驱动所述显示装置的方法 |
Non-Patent Citations (1)
Title |
---|
See also references of EP2527958A4 * |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109256111A (zh) * | 2017-07-13 | 2019-01-22 | 卡西欧计算机株式会社 | 检测装置、电子乐器及检测方法 |
CN109256111B (zh) * | 2017-07-13 | 2023-09-01 | 卡西欧计算机株式会社 | 检测装置、电子乐器及检测方法 |
Also Published As
Publication number | Publication date |
---|---|
EP2527958A1 (en) | 2012-11-28 |
CN102043509A (zh) | 2011-05-04 |
EP2527958A4 (en) | 2014-09-10 |
CN102043509B (zh) | 2013-11-06 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
TWI464624B (zh) | 分析位置的方法與裝置 | |
TWI585621B (zh) | 分辨單觸或雙觸的方法與裝置 | |
TWI464634B (zh) | 雙差動感測的方法與裝置 | |
TWI407347B (zh) | 位置偵測的方法與裝置 | |
TWI427523B (zh) | 電容式位置偵測的方法與裝置 | |
TWI446233B (zh) | 轉換感測資訊的方法與裝置 | |
TWI552024B (zh) | 二維度感測資訊分析的方法與裝置 | |
TWI579797B (zh) | 影像分割的處理器 | |
TWI516993B (zh) | 訊號量測的方法與裝置 | |
WO2011041948A1 (zh) | 分析位置的方法与装置 | |
WO2011041940A1 (zh) | 分辨单触或多触的方法与装置 | |
WO2011041942A1 (zh) | 位置侦测的方法与装置 |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 10821557 Country of ref document: EP Kind code of ref document: A1 |
|
WWE | Wipo information: entry into national phase |
Ref document number: 2010821557 Country of ref document: EP |
|
NENP | Non-entry into the national phase |
Ref country code: DE |