KR102292238B1 - Electronic device including power-on button and inductive touch force sensor - Google Patents

Abstract

An electronic device is disclosed. According to an embodiment of the present invention, an electronic device includes: an enclosure for enclosing the electronic device; a first area disposed on the enclosure and operating as a power-on button; and a plurality of second regions arranged to be elastically deformable along the Z-axis direction by an external force applied in the Z-axis direction among regions other than the first region on the enclosure. A pressure-sensing variable resistor in response to external pressure is disposed in the first region, and the pressure-sensing variable resistor and an internal power source of the electronic device are connected to a power button on/off detection circuit. The plurality of inductive coils disposed to be spaced apart from the second regions and disposed to face each of the second regions are elastically elastic along the Z-axis direction by an external force applied to each of the second regions in the Z-axis direction. Forming an individual channel resonance frequency deviating from a reference resonance frequency based on the deformed individual channel displacement, the determination circuit determines the individual channel displacement based on the individual channel resonance frequency, and an external force applied in the Z-axis direction to each of the second regions can be determined.

Description

ELECTRONIC DEVICE INCLUDING POWER-ON BUTTON AND INDUCTIVE TOUCH FORCE SENSOR

The present invention relates to an electronic device including an inductive touch force sensor, and specifically, is formed on a target layer and a printed circuit board (PCB), or a flexible printed circuit board (FBCB) by an external force. , a power button ( It relates to an electronic device including a Power-On Button).

Recent touch recognition technology has made rapid development, and in the two-dimensional touch recognition technology that recognizes the touch position using coordinates on the X and Y axes, the intensity of the touch (the force applied in the Z-axis direction) 3D touch recognition function, which detects size) to enrich the user interface, has emerged.

APPLE INC's 3D Touch combines a touch sensor and a pressure sensor, and introduces a technology that differentiates and recognizes the intensity of the touch. However, the method of combining the pressure sensor with the touch sensor increases the hardware manufacturing cost, and since the sensitivity of the pressure sensor is not high, it is difficult to accurately recognize the user's touch intensity.

Texas Instruments Inc's US Patent Publication US 2017/0269754 "Dual Touch Sensor Architecture With XY-Position And Z-Force Sensing For Touch-On-Surface Button" combines a capacitive touch sensor and an inductive sensor, The position on the XY plane of is recognized by the capacitive touch sensor, and the touch force in the Z-axis direction at the touch position is recognized by the inductive sensor.

Texas Instruments Inc.'s other US Patent Publication US 2018/0180450 "Inductive Touch Input" uses a plurality of inductive touch sensors to detect touch presence and touch force at different locations, and a movement pattern of touch presence and touch force to recognize the touch scroll gesture.

As a prior art that detects a user's intention to lock or unlock a car door by detecting a force applied to the car door by applying such 3D touch force recognition technology, Korean Patent Application Laid-Open No. KR 10-2017-0007127 and US Patent Publication US 2017 /0016255 "Device for Detecting a User's Intention to Lock or Unlock a Motor Vehicle Door", etc., and the prior literature implementing an inductive touch force sensor by implementing a coil on a flexible printed circuit board (FPCB) As such, Korean Patent Registration KR 10-1920440 "Self-Inductive Force Sensor Module for 3D Touch Implementation" and Korean Patent Registration KR 10-1954368 "Mutual Inductive Force Sensor Module for 3D Touch Implementation" have been introduced.

Prior documents for sensing touch force using an inductive sensor introduce a technology for recognizing touch force by selecting a new material or component such as arrangement of parts and elements, FPCB, etc. However, when using only an inductive sensor, the touch position and touch There is a problem in that the precision of detecting a force is low, and hardware cost increases when an inductive sensor is combined with another sensor.

In addition, due to the recent rise of mobile devices and smart devices, there are various needs for user interfaces and user experiences. Densely arranged, but a technology to recognize each sensor separately is also required, it is difficult to meet this demand with the prior technologies.

US Patent Publication US 2017/0269754 "Dual Touch Sensor Architecture With XY-Position And Z-Force Sensing For Touch-On-Surface Button" (September 21, 2017) US Patent Publication US 2018/0180450 "Inductive Touch Input" (June 28, 2018) Korean Patent Laid-Open Patent KR 10-2017-0007127 "Device for detecting user's intention to lock or unlock a car door" (January 18, 2017) US Patent Publication US 2017/0016255 "Device for Detecting a User's Intention to Lock or Unlock a Motor Vehicle Door" (January 19, 2017) Korean Patent Registration KR 10-1920440 "Self-inductive force sensor module for 3D touch realization" (November 14, 2018) Korean Patent Registration KR 10-1954368 "Mutual Inductive Force Sensor Module for 3D Touch Realization" (February 26, 2019)

In the prior art, the sensitivity of the sensor is improved through the arrangement of parts and elements, the selection of parts or materials, the inductive sensor and other sensors are combined to detect by sharing the touch force and the touch position, or a plurality of inductive sensors are used. These are technologies that implement and recognize user gesture patterns by tracking sensing information of inductive sensors.

In addition, the prior art scans the magnitude of the output electrical signal formed in the resonance circuit in response to the input electrical signal by varying the frequency of the input electrical signal applied to the resonance circuit, calculating the frequency when the maximum magnitude is calculated as the resonance frequency. take the configuration Due to this, the prior art has an error as much as the resolution of the variable frequency of the input electrical signal, and the accuracy of the indirect method of calculating the resonant frequency by detecting the size of the electrical signal is lowered, and the frequency of the input electrical signal must be varied. There is a problem that it takes a considerable amount of time.

In addition, the prior art detects the magnitude of an electrical signal and calculates the resonance frequency and inductance, so it is difficult to accurately measure it. Due to this, it is mainly used to determine whether the inductance change exceeds a certain threshold, and quantitatively analyze the change in inductance. It doesn't provide enough accuracy.

The present invention has been derived to solve the problems of the prior art, and it is possible to reduce the hardware cost by using only the inductive touch sensor, and precisely detect the touch position and the touch force even when only the inductive touch sensor is used. An object of the present invention is to provide an inductive touch force sensor and an operating method thereof.

In addition, the present invention detects a change in inductance with only a single measurement without a change in frequency or input of different frequency components, so that even in the case of a multi-channel inductive touch force sensor, the touch position and touch force are quickly detected, and the user's intention An object of the present invention is to provide a recognizable inductive touch force sensor and an operating method thereof.

The present invention not only uses the inductive touch sensor, but also does not require a change in frequency or input of different frequency components, thereby reducing power consumption for sensing the touch position and touch force, and multi-channel inductive touch force. An object of the present invention is to provide an inductive touch force sensor capable of significantly reducing power consumption even in the case of a sensor and an operating method thereof.

An object of the inductive touch force sensor according to the present invention is to propose a circuit and an operation method capable of effectively detecting a shift of a resonant frequency. In addition, since the inductive touch force sensor according to the present invention does not require a process of changing the frequency of an input electrical signal, it is an object of the inductive touch force sensor to shorten the sensing time of the touch position and the touch force.

The inductive touch force sensor according to the present invention aims to shorten the sensing time and reduce power consumption during sensing by simultaneously recognizing the touch position and the touch force only with the inductive touch sensor without the capacitive sensor.

Meanwhile, when all buttons disposed in an external enclosure surrounding an electronic device (eg, a smart device, or a wearable device) are implemented as an inductive touch force sensor, a means for externally turning on/off power I need this. Since the inductive touch force sensor operates on the premise that an alternating current is applied to the coil, the internal power must be turned on in advance for the inductive touch force sensor to operate.

The present invention can recognize various user gestures by implementing a plurality of user buttons as an inductive touch force sensor in an electronic device having an enclosure that does not require a cutout, and driving the inductive touch force sensor Another object of the present invention is to propose an electronic device including a stable power-on button for

The present invention is a configuration derived to achieve the above object, and according to an embodiment of the present invention, an electronic device includes: an enclosure for enclosing the electronic device; a first area disposed on the enclosure and operating as a power-on button; and a plurality of second regions arranged to be elastically deformable along the Z-axis direction by an external force applied in the Z-axis direction among regions other than the first region on the enclosure. A pressure-sensing variable resistor in response to external pressure is disposed in the first region, and the pressure-sensing variable resistor and an internal power source of the electronic device are connected to a power button on/off detection circuit. The plurality of inductive coils disposed to be spaced apart from the second regions in the electronic device and disposed to face each of the second regions change the Z-axis direction by an external force applied to each of the second regions in the Z-axis direction. form an individual channel resonant frequency deviating from the reference resonant frequency based on the individual channel displacement elastically deformed according to the can determine the applied external force.

A plurality of individual channel resonance circuits are coupled to each of the plurality of inductive coils, and based on a respective channel displacement in the Z-axis direction of each of the plurality of second regions with respect to each of the plurality of inductive coils, the plurality of individual channel resonance circuits are provided. Each of the inductive coils has an individual channel resonant frequency due to the individual channel inductance formed in it. The reference resonance circuit is set to have the same impedance as a predetermined first state among states that the plurality of individual channel resonance circuits may have. In the first state, a reference resonance circuit and a plurality of individual channel resonance circuits may be designed on the assumption that an external force applied from the Z-axis direction to each of the plurality of second regions is zero.

The determination circuit may include a reference electric signal formed in the reference resonant circuit under the influence of the reference AC signal applied to the reference resonant circuit, and the plurality of individual channel AC signals applied to each of the plurality of individual channel resonant circuits. Receive each of a plurality of individual channel electrical signals formed in each of the individual channel resonant circuits, and based on a reference resonance frequency of the reference electrical signal, and respective individual channel resonance frequencies of each of the plurality of individual channel electrical signals Thus, it is possible to determine the individual channel displacement, a position at which an external force applied in the Z-axis direction is input among the plurality of second regions, and an external force applied in the Z-axis direction.

In the power button on/off detection circuit, if the resistance value change of the pressure sensing variable resistor is greater than or equal to a first threshold value due to external pressure on the first region, the internal power supply is configured to supply the plurality of inductive coils and the plurality of inductive coils. It can be controlled to be applied to the individual channel resonance circuits, the reference resonance circuit, and the determination circuit.

A determination circuit may be configured to determine a degree to which each of the plurality of individual channel resonant circuits deviates from the first state based on a degree to which each of the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits deviates from the reference resonant frequency; It is possible to obtain quantified sensing information on individual channel displacements in the Z-axis direction of each of the two second regions and an external force applied in the Z-axis direction to each of the plurality of second regions.

The determination circuit determines that the first individual channel resonance frequency among the individual channel resonance frequencies of each of the plurality of individual channel resonant circuits is significantly changed when the degree of deviation from the reference resonance frequency is greater than or equal to a second threshold value It may be determined that the external force applied in the Z-axis direction is input to the first individual region corresponding to the first individual channel resonance circuit in which the first individual channel resonance frequency is formed.

The determination circuit is configured in the first individual region covered by the first inductive coil coupled to the first individual channel resonance circuit based on a change pattern of a difference between the reference resonance frequency and the first individual channel resonance frequency appearing in the time domain. A user gesture intended by the quantified sensing information on the external force applied in the Z-axis direction and the external force applied in the Z-axis direction may be recognized.

The determination circuit is configured to include: a first change pattern appearing in the time domain with respect to a difference between a first individual channel resonance frequency of a first individual channel resonance circuit among the plurality of individual channel resonance circuits and the reference resonance frequency, and the plurality of individual channel resonance circuits; A first inductance coupled to the first individual channel resonant circuit based on a second variation pattern appearing in the time domain with respect to a difference between a second individual channel resonant frequency of a second individual channel resonant circuit among circuits and the reference resonant frequency First quantified sensing information about the external force applied in the Z-axis direction in the first individual region covered by the coil, in the second individual region covered by the second inductive coil to which the second individual channel resonance circuit is coupled A user gesture intended by the quantified second sensing information on the external force applied in the Z-axis direction and the external force applied in the Z-axis direction may be recognized.

The determination circuit is configured to include: a first change pattern appearing in the time domain with respect to a difference between a first individual channel resonance frequency of a first individual channel resonance circuit among the plurality of individual channel resonance circuits and the reference resonance frequency, and the plurality of individual channel resonance circuits; A first inductance coupled to the first individual channel resonant circuit based on a second variation pattern appearing in the time domain with respect to a difference between a second individual channel resonant frequency of a second individual channel resonant circuit among circuits and the reference resonant frequency First quantified sensing information about the external force applied in the Z-axis direction in the first individual region covered by the coil, in the second individual region covered by the second inductive coil to which the second individual channel resonance circuit is coupled Extracting quantified second sensing information on the external force applied in the Z-axis direction, and the external force applied in the Z-axis direction based on the first sensing information and the second sensing information is an input intended by the user It can be determined whether or not

The determination circuit may include: an operator for obtaining quantified information about the degree to which each of the individual channel resonance frequencies of each of the plurality of individual channel resonance circuits deviates from the reference resonance frequency; a low pass filter connected to the output terminal of the calculator to remove a high frequency component; And it is connected to the output terminal of the low-pass filter to digitally count the frequency of the differential frequency component signal corresponding to the degree to which each of the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits deviates from the reference resonant frequency time-to - May include a digital converter (Time-to-Digital Converter).

The determination circuit determines that each of the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits deviates from the reference resonant frequency in a state in which each of the plurality of individual channel resonant circuits is externally forcibly adjusted to be in the first state. A calibration process for each of the plurality of individual channel resonance circuits may be performed based on the quantified information on the degree.

According to the present invention, it is possible to implement the inductive touch force sensor using only the inductive sensor, thereby reducing hardware cost.

According to the present invention, even when the inductive touch force sensor is implemented using only the inductive sensor, the touch position, the touch force, the touch pattern, and the gesture can be precisely detected. In this case, the touch position and/or the touch force may be simultaneously represented by one output value.

According to the present invention, a change in inductance can be detected by a single measurement without scanning the frequency component, thereby reducing power consumption and shortening the sensing time.

According to the present invention, since changes in inductance can be precisely detected by a single measurement for each sensor without scanning frequency components, even when an inductive sensor array or inductive sensor matrix is formed and operated, power consumption and sensing time are relatively free. and can accurately determine various touch patterns, touch gestures, and touch situations using an array or matrix.

According to an embodiment of the present invention, a change in the time domain may be detected and a gesture may be recognized using a single channel or single coil inductive sensor.

According to an embodiment of the present invention, it is possible to verify whether there is an error in the sensing result by combining sensing results simultaneously detected for a plurality of channels or coils. In consideration of the sensing result simultaneously detected for a plurality of coils and the positional relationship between the regions covered by the coils, it may be verified whether the touch force derived from the sensing result is the intention of the user or whether it is due to an error.

Since the prior art detects the amplitude of the resonance signal or the amplitude of the analog AC signal, it is only possible to detect whether the detected result exceeds a predetermined threshold. However, the present invention calculates the resonance frequency difference of the differential signal and digitally counts it, so that quantified sensing information can be obtained, and a change in the touch force in time-space can be precisely detected using this.

According to the present invention, various user gestures can be recognized by realizing a plurality of user buttons as an inductive touch force sensor in an electronic device having an enclosure that does not require a cutout, and the inductive touch force sensor is driven It is possible to implement an electronic device including a stable power-on button for this purpose.

When a plurality of user buttons disposed in an external enclosure surrounding the electronic device are implemented as an inductive touch force sensor, internal power must be supplied to the inductive touch force sensor in advance for operation of the inductive touch force sensor. do. In this case, always turning on the internal power supply will shorten the operating life of the electronic device, so a means for turning on/off the internal power from the outside is required. The present invention has a long operating life and can be applied to a wide range of applications by implementing an electronic device including a power button that can stably turn on/off internal power from the outside and a user button implemented as an inductive touch force sensor. It is possible to implement an electronic device with The electronic device of the present invention is physically robust because it has a high IP rating. The electronic device of the present invention may be used in an underwater environment, and may be applied to a wearable device even in a dusty or sweaty situation.

1 is a diagram illustrating an inductive touch force sensor according to an embodiment of the present invention.
2 is a diagram illustrating an inductive touch force sensor according to an embodiment of the present invention.
3 is a diagram illustrating an inductive touch force sensor and an operating method thereof according to an embodiment of the present invention.
4 is a diagram illustrating an inductive touch force sensor and an operating method thereof according to an embodiment of the present invention.
5 is a diagram illustrating a coil structure of an inductive touch force sensor according to an embodiment of the present invention.
6 is a diagram illustrating a coil structure of an inductive touch force sensor according to an embodiment of the present invention.
7 is a diagram illustrating a circuit and an operation method of an inductive touch force sensor according to an embodiment of the present invention.
8 is a diagram illustrating a circuit and an operating method of an inductive touch force sensor according to an embodiment of the present invention.
9 is an operation flowchart illustrating a method of operating an inductive touch force sensor according to an embodiment of the present invention.
10 is an operation flowchart illustrating a method of operating an inductive touch force sensor according to an embodiment of the present invention.
11 is a diagram illustrating an inductive touch force sensor according to an embodiment of the present invention.
12 is a diagram illustrating an inductive touch force sensor according to an embodiment of the present invention.
13 is a diagram illustrating an electronic device including an inductive touch force sensor and a power-on button according to an embodiment of the present invention.

In addition to the above objects, other objects and features of the present invention will become apparent through the description of the embodiments with reference to the accompanying drawings. A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, an inductive touch force sensor and an operating method thereof according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 12 .

1 is a diagram illustrating an inductive touch force sensor 100 according to an embodiment of the present invention. 1 shows an inductive touch force sensor 100 assuming a single button/channel/coil.

Referring to FIG. 1 , the inductive touch force sensor 100 according to an embodiment of the present invention is exposed to an external force 150 in the Z-axis direction, and the Z-axis is caused by the external force 150 in the Z-axis direction. a first part 130 elastically deformable along a direction; a target layer 140 disposed to be movable along the Z-axis direction based on the deformation of the first part 130; an inductive coil 112 formed on the substrate 110 spaced apart from the target layer 140; and a spacer layer 160 supporting the first component 130 and separating the inductive touch force sensor 100 from other sensors or sensing channels.

The inductive touch force sensor 100 shown in FIG. 1 forms a single channel. According to an embodiment, an array or a matrix may be implemented by arranging a plurality of inductive touch force sensors 100 as shown in FIG. 1 in parallel.

When the first part 130 is elastically deformed by the external force 150 applied along the Z-axis direction, the target layer 140 may move along the Z-axis direction according to the degree of deformation of the first part 130 . have. In this case, the inductive coil 112 and the target layer 140 formed on the printed circuit board 110 are inductively coupled.

In this case, a material having an elastic restoring force, for example, foam, may be disposed between the target layer 140 and the inductive coil 112 . When the external force 150 is applied, the target layer 140 approaches the inductive coil 112 , and accordingly, the inductance formed in the inductive coil 112 inductively coupled to the target layer 140 changes.

When the external force 150 is removed, the target layer 140 returns to the position before deformation by the elastic restoring force of the foam. That is, the change in inductance appears only while the external force 150 is applied, and when this is sensed, the external force 150 in the Z-axis direction can be detected.

In the first state to which the external force 150 is not applied, the distance at which the target layer 140 is separated from the inductive coil 112 is d0, and the target layer 140 is inductive in the state where the external force 150 is applied. Assuming that the distance from the coil 112 is d, the displacement Δd = |d-d0| causes a change in inductance formed in the inductive coil 112 inductively coupled to the target layer 140 . Accordingly, when the change in inductance is detected, the displacement Δd can be detected and the magnitude of the external force 150 can be quantified.

In the present specification, for convenience of description, one inductive coil 112 and a unit for sensing the external force 150 in a region covered by the inductive coil 112 will be referred to as a channel. The target layer 140 may be disposed for each channel separately from other channels as shown in FIG. 1 , or may be disposed in common in a group consisting of a plurality of channels as shown in FIG. 2 , which will be described later. 1 shows an embodiment in which a target layer 140 is disposed for each individual channel, and each channel is physically separated from other channels by a spacer layer 160 .

The target layer 140 may be a non-magnetic metal or a magnetic metal. The target layer 140 is preferably a conductive conductor so that an eddy current can be formed. Depending on whether the target layer 140 has magnetism, it may be determined whether the inductance increases or decreases when the external force 150 is applied. A material in which variables such as displacement versus inductance detection sensitivity are optimized based on the magnetic/non-magnetic of the target layer 140 and the hardware design of the channel may be selected as the target layer 140 .

The inductive coil 112 of the inductive touch force sensor 100 according to an embodiment of the present invention may be formed by overlapping a plurality of unit coil windings in a concentric structure.

Although the target layer 140 is moved in the Z-axis direction by the external force 150, the target layer 140 may be implemented to maintain a state parallel to the inductive coil 112, but according to an embodiment of the present invention may move while forming a slight inclination with the inductive coil 112 according to a position on the XY plane where the external force 150 is concentrated in a state where the target layer 140 is not parallel to the inductive coil 112 . In this case, in the prior art, it becomes an error factor in measurement, making it difficult to accurately sense the touch force. However, in the present invention, the change in inductance can be precisely quantified based on the differential detection of the inductance, so it is difficult to accurately detect the touch force. Of course, depending on the embodiment, the position on the XY plane where the external force 150 is concentrated may be precisely detected. This embodiment will be described later with reference to FIGS. 5 and 6 .

Most wearable devices use mechanical buttons that require cutouts in the enclosure that forms the boundary with the outside, making it difficult to seal the device and lowering its IP rating, which means dust and water resistance. Mechanical buttons also use moving parts, metallic contacts, and gaskets, which have long-term reliability problems, increase cost, and reduce tolerance to environmental factors. It has low problems.

If a cut out free enclosure can be implemented, a high IP rating can be implemented, and a wearable device having a higher IP rating can be utilized for various purposes that were not previously utilized. If gasket-less and no moving parts, wearable devices can become physically more robust and embedded in wearable elements such as gloves, for example. It can also be used under water.

In order to achieve such a high IP rating, there is an attempt to utilize an electromagnetic device that recognizes a touch pressure instead of a mechanical button. As one of these attempts, there is a movement to use a capacitive proximity sensor, but the capacitive proximity sensor is affected by an electric field and is affected by whether the surrounding is energized. .

An inductive touch sensor that measures inductance by generating a change in a magnetic field in a way to recognize touch pressure by measuring a change in impedance instead of a capacitive proximity sensor has been proposed. The fact that inductive sensors are less sensitive to external disturbances than capacitive sensors also contributes to the widespread use of inductive sensors.

A method of implementing an inductive touch force sensor using an inductive touch sensor is already described in the aforementioned prior documents, for example, US Patent Publication US 2018/0180450 "Inductive Touch Input", US Patent Publication US 2017/0016255 " Device for Detecting a User's Intention to Lock or Unlock a Motor Vehicle Door", or Korea Patent KR 10-1920440 "Self-inductive touch force sensor module for 3D touch implementation", etc. are mentioned.

On the other hand, compared to a capacitive sensor capable of precise detection using an electrical signal, an inductive sensor that uses a change in a magnetic field is not easy to increase detection accuracy. The inductive sensing technology of the prior documents is also mainly used for the purpose of detecting a specific event to the extent of detecting whether it is above a certain threshold value rather than precise measurement.

The configuration of FIG. 1 and the preceding documents may be included as part of the configuration of the present invention, and the unique effects of the present invention will be achieved in combination with the novel configurations of the present invention to be mentioned later. In particular, recently combined with mobile devices, smart devices, virtual reality, and augmented reality, the user interface aims to recognize precise touch force, accurately recognize user gestures, and understand user intentions. The present invention improves the inductive sensing of the prior art to precisely measure and quantify the touch force, the displacement of the target caused by the touch force, and the change in inductance, thereby identifying the user's intention and suggesting a technology for accurately recognizing the user's gesture do.

According to one of the embodiments of the present invention, when a separate coil is not disposed on the target layer 140 , the eddy currents of the inductive coil 112 and the target layer 140 respond to each other in a self-inductive manner. The displacement of the target layer 140 may be measured.

According to another embodiment of the present invention, a mutual inductive coil (not shown) is disposed on the target layer 140 , and the mutual inductive coil of the target layer 140 and the inductive coil 112 on the substrate 110 . In response to this, the displacement of the target layer 140 may be measured in a mutual inductive manner.

2 is a diagram illustrating an inductive touch force sensor 200 according to an embodiment of the present invention.

Referring to FIG. 2 , the inductive touch force sensor 200 according to an embodiment of the present invention is exposed to an external force in the Z-axis direction, and elastically along the Z-axis direction by the external force in the Z-axis direction. a second part 230 comprising a plurality of individual deformable regions 232 ; a target layer 240 disposed to be movable along the Z-axis direction when the second part 230 deforms at least one of the plurality of individual regions 232; and formed on the substrate 210 spaced apart from the target layer 240 , corresponding to each of the plurality of individual regions 232 , and disposed to face each of the plurality of individual regions 232 . It includes a plurality of inductive coils 212 .

The second part 230 may be made of an elastically deformable material, and the individual regions 232 may be made of the same material as the remaining regions except for the individual regions 232 of the second part 230 . That is, since the second component 230 may surround the entire area of the inductive touch force sensor 200 shown in FIG. 2 with one shell, the IP rating of the inductive touch force sensor 200 may be increased. . For example, assuming a smart watch in which the individual regions 232 have independent numbers as shown in FIG. 2 , the individual regions 232 exposed in the smart watch are surrounded by a single shell, so that excellent dust-proof and waterproof performance is obtained. It is expected. Since the individual regions 232 are disposed to correspond to the holes of the spacer layer 260 , when an external force is applied to any one or more of the individual regions 232 , the corresponding region is burnt based on the elasticity of the second part 230 . can be sexually transformed.

According to an embodiment of the present invention, the inductive touch force sensor 200 of FIG. 2 may be located on the bezel, side, or back of the mobile device, and the individual areas 232 are small in size so that they are not identified by the user. It may be arranged densely with At this time, the inductive touch force sensor 200 may be used as a means for determining whether the user is holding the corresponding device or whether a predetermined user gesture is input to the inductive touch force sensor 200 area of the corresponding device. .

Unlike in FIG. 1 , in FIG. 2 , the target layer 240 is commonly disposed in a module including a plurality of individual regions 232 and inductive coils 212 . Assuming that the spacer layer 260 also has a weak elastic restoring force, the target layer 240 is twisted in XYZ space depending on which region of the individual regions 232 is applied with the touch force, and is asymmetric to the inductive coils 212 . will provide a negative displacement. For example, the inductance distribution formed in the inductive coils 212 when button 1 is pressed and when button 6 is pressed will be different. 200) can be stored by the controller. The inductive touch force sensor 200 compares the distribution of the inductance that appears in the plurality of inductive coils 212 when an external force is actually applied and the inductance distribution pattern stored in advance to extract what the user intended input is. have.

In the prior art, it is not easy to simultaneously detect the inductance of a plurality of channels. In the present invention, the inductance of a plurality of channels can be detected simultaneously without substantially time difference, and quantified data can be obtained, so that the spatial distribution of the touch force within the area covered by the inductance force sensor 200 can be obtained, and accurate user's intention can be discerned.

According to one of the embodiments of the present invention, when a separate coil is not disposed on the target layer 240 , the eddy currents of the inductive coil 212 and the target layer 240 respond to each other in a self-inductive manner. The displacement of the target layer 240 may be measured.

According to another embodiment of the present invention, a mutual inductive coil (not shown) is disposed on the target layer 240 , and the mutual inductive coil of the target layer 240 and the inductive coil 212 on the substrate 210 . In response to this, the displacement of the target layer 240 may be measured in a mutual inductive manner.

3 is a diagram illustrating an inductive touch force sensor 300 and an operating method thereof according to an embodiment of the present invention.

Referring to FIG. 3 , one module 310a is illustrated as a set including a set of a plurality of coils 312 in the inductive touch force sensor 300 .

By tracing the spatial distribution on the XY plane of the inductance in the plurality of coils 312 in the module 310a in the time domain, the user's touch force within the area covered by the module 310a is temporally-spatially changed. pattern can be traced.

The inductive touch force sensor 300 tracks the spatial distribution on the XY plane of the external force in the Z-axis direction recognized in individual areas covered by each of the plurality of coils 312 in the time domain, so that the center of the external force is XY The direction and speed of movement in the time domain on a plane can be analyzed. According to this, the inductive touch force sensor 300 provides a pattern of a touch force applied by the user in the area covered by the inductive touch force sensor 300, for example, tapping, sliding/scrolling/swiping, zooming in/ A user gesture such as zooming out may be recognized as an inductive sensing technique.

The inductive touch force sensor 300 combines X-axis movement information in which the center position of the touch force moves along the X-axis direction and Y-axis movement information in which the center position of the touch force moves along the Y-axis direction to combine the XY plane It is also possible to derive movement information on the XY plane in which the center position of the touch force moves. In another embodiment, the inductive touch force sensor 300 is a gesture in which the center position of the touch force is moved on the XY plane directly from the variation pattern of the touch force obtained in individual areas covered by each of the plurality of coils 312 . You can also get information. In addition, since each channel information is obtained independently, the inductive touch force sensor 300 recognizes a user gesture without confusion even if a user gesture by multi-touch is input within the sensing area covered by the plurality of coils 312 . can

4 is a diagram illustrating an inductive touch force sensor 400 and an operating method thereof according to an embodiment of the present invention.

Referring to FIG. 4 , one module 410a is illustrated as a set including a set of a plurality of coils 412 in the inductive touch force sensor 400 .

For example, in the case where the module 410a is an interface displayed externally by assigning a number to each individual region, as shown in FIG. 4 , the external force is difficult to specify within the range 452 to which the external force is input. In the case of uniform measurement, the user does not intend to touch a specific number area, but the device may be measured only by holding the device in his hand or by applying pressure from an external factor, thereby preventing malfunction of the device.

To this end, it is necessary to detect an inductance distribution pattern at substantially the same time for individual regions and a plurality of coils 412 included in the module 410a. In the present invention, the inductance of the inductance is It achieves this by detecting the change and touch force of the individual regions associated with each of the coils 412 . Matters related thereto will be described later with reference to FIGS. 7 and 8 .

5 is a diagram illustrating a coil structure of an inductive touch force sensor 500 according to an embodiment of the present invention.

Referring to FIG. 5 , the inductive channel coil 512 of the inductive touch force sensor 500 according to an embodiment of the present invention consists of a set of a plurality of unit coil windings, and the plurality of unit coil windings are It may have a structure arranged to be spaced apart from each other as the distance from the position increases.

The target layer 140 shown in FIG. 1 causes displacement in the Z-axis direction when an external force in the Z-axis direction is applied. no. Accordingly, the target layer 140 may cause displacement in the Z-axis direction while being warped in the XYZ space. At this time, the displacement of the target layer 140 may appear differently according to a position on the XY plane where an external force is concentrated within the channel region 514 covered by one inductive channel coil 512 . At this time, as shown in FIG. 5 , as the coil structure of the inductive coil 512 increases from the center of the inductive touch force sensor 500, the spacing between the unit coil windings in the inductive coil 512 increases or decreases. , a change in inductance sensed by the inductive coil 512 will vary according to a position on the XY plane where the external force is concentrated in the channel region 514 . Therefore, by comparing the previously tested and stored inductance quantification pattern with the actually measured inductance quantification pattern, the position on the XY plane where the external force is concentrated in the channel region 514 can be identified.

At this time, by identifying and tracking the position on the XY plane where the external force is concentrated within the channel region 514 in the time domain, a user gesture of tapping or sliding/scrolling/swiping can be recognized even with a single-channel inductive touch force sensor. .

In FIG. 5 , the structure of each inductive coil 512 is asymmetrical, but when it is formed as a set of inductive coils 512 to constitute one module, the module is symmetrical to the inductive touch force sensor ( 500) can be implemented.

6 is a diagram illustrating a coil structure of an inductive touch force sensor 600 according to an embodiment of the present invention.

Referring to FIG. 6 , the inductive channel coil 612 of the inductive touch force sensor 600 according to an embodiment of the present invention consists of a set of a plurality of unit coil windings, and the plurality of unit coil windings are It may have a structure arranged to be spaced apart from each other as the distance from the position increases.

At this time, the position on the XY plane where the external force is concentrated within the channel region 614 covered by one inductive channel coil 612 can be identified, and when the position on the XY plane where the external force is concentrated in the time domain is tracked, a single The fact that a user gesture can be recognized even within the channel region 614 is as described above with reference to FIG. 5 .

In FIG. 6 , the structure of each inductive coil 612 is asymmetrical, and when it is formed by a set of inductive coils 612 to form one module, the module maintains the asymmetry, but the regularity is inductive touch. A force sensor 600 may be implemented.

7 is a diagram illustrating a circuit and an operation method of the inductive touch force sensor 700 according to an embodiment of the present invention.

Referring to the inductive touch force sensor 100 of FIG. 1 and the circuit of FIG. 7 according to an embodiment of the present invention, the inductive touch force sensors 100 and 700 are coupled to the inductive coils 112 and 712. and a first resonant frequency ω1 due to the first inductance formed in the inductive coils 112 and 712 based on the displacement of the target layers 140 and 740 with respect to the inductive coils 112 and 712. The branch includes a first resonant circuit 720 .

In this case, the inductive touch force sensors 100 and 700 according to an embodiment of the present invention include: a first oscillator 722 for applying a first AC signal to the first resonance circuit 720; A reference resonance circuit (not shown in FIG. 7 ) having the same impedance as a predetermined first state (a state in which external forces 150 and 750 are not applied is preferred) among states that the first resonance circuit 720 may have ); a reference oscillator (not shown in FIG. 7 ) having the same characteristics as the first oscillator 722 and applying a reference AC signal to the reference resonance circuit; and receiving a first electrical signal formed in the first resonance circuit 720, receiving a reference electrical signal formed in the reference resonance circuit, and the first resonance frequency ω1 of the first electrical signal and the Displacement of the target layers 140 and 740 based on the reference resonance frequency ω_ref of the reference electrical signal Δd = |d-d0| and a determination circuit 770 for determining the external forces 150 and 750 in the Z-axis direction.

The determination circuit 770 of the inductive touch force sensors 100 and 700 according to an embodiment of the present invention has the reference electrical signal formed in the reference resonance circuit under the influence of the reference AC signal applied to the reference resonance circuit. detects a difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 of The degree of deviation from the first state, the relative displacement of the target layers 140 and 740 relative to the inductive coils 112 and 712 Δd = |d-d0|, and the external force in the Z-axis direction ( 150, 750) quantified sensing information may be obtained.

The first resonant circuit 720 shown in FIG. 7 is an equivalent circuit and does not necessarily include a lumped RLC element. For example, the capacitance C (716) and the resistor R (718) may be independent elements or may represent parasitic components. Also, even when the first resonant circuit 720 is implemented using an independent element, the arrangement of the elements does not necessarily follow FIG. 7 , and it is sufficient if it can equivalently correspond to the first resonant circuit 720 .

If the difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 is equal to or greater than a first threshold, the determination circuit 770 of the inductive touch force sensors 100 and 700 according to an embodiment of the present invention Considering that the first resonant frequency ω1 has caused a significant change, it may be determined that the external force 150 in the Z-axis direction is input. That is, when a change in the first resonant frequency ω1 is detected due to noise, unintentional movement, unintentional contact, or unintentional vibration, but is less than the first threshold, the first resonant frequency ω1 causes a significant change. can be considered as non-existent.

The determination circuit 770 of the inductive touch force sensors 100 and 700 according to an embodiment of the present invention is in a state in which the first resonant circuit 720 is forcibly adjusted from the outside so that it is in the first state (externally). A state in which the pressures 150 and 750 are not applied is preferred) A calibration process may be performed based on a difference between the first resonant frequency ω1 and the reference resonant frequency ω_ref.

The determination circuit 770 may perform a calibration process. The determination circuit 770 may perform a calibration process in a state in which the external forces 150 and 750 are not applied. In this case, the first resonant circuit 720 or the reference resonant circuit may be adjusted so that the difference between the first resonant frequency ω1 and the reference resonant frequency ω_ref becomes zero through the calibration process. In addition, the difference between the first resonant frequency (ω1) and the reference resonant frequency (ω_ref) detected in the first state to which the external forces 150 and 750 are not applied through the calibration process are stored in a separate memory or storage in the future. It may be processed as offset information in the inductive force sensing process. After calibration, the adjustment of the difference between the first resonant frequency ω1 and the reference resonant frequency ω_ref is performed using means such as adjusting the value of the variable resistor R′ that may be added to the first resonant circuit 720 . can be executed.

In general, the inductive sensing technology known to date is to measure the change in impedance after sequentially inputting a plurality of frequency signals through a variable frequency scan. there was However, in a general inductive sensor, it is very difficult to accurately detect the magnitude of signals despite noise.

The present invention takes the change of the resonance frequency as the main detection object instead of the amplitude of the signals as the main detection object, and the means for applying the AC signal of the same frequency without adopting a method such as variable frequency scan is sufficient enough for the desired purpose can be achieved Therefore, using this method, the present invention can quickly detect a change in inductance at a corresponding point in time and quantify it. A real-time change in the first resonance frequency ω1 may be detected regardless of the amplitude of the resonance signal by the method of FIG. 8 , which will be described later. In addition, since the first resonant frequency ω1 is detected directly rather than indirectly, it is easy to digitize using it, and the change in inductance and change in touch force can be precisely measured using the digitized value. It has the advantage of being able to detect quickly. In addition, since there is no process such as variable frequency scanning, the sensing process is fast and power consumption is low. Since the inductive sensing process for one coil and channel is fast and the sensing result is obtained as a digitized value, changes in inductance and changes in touch force can be detected substantially simultaneously even when multiple channels are implemented. When each channel and coil correspond to a position on the XY plane, the spatial change of the quickly obtained touch force on the XY plane can easily identify whether the touch force is due to the user's intention, error or other cause. let there be In addition, by tracking the spatial change of the touch force on the XY plane in the time domain, the user's intentional gesture can be easily recognized.

Referring to the inductive touch force sensor 200 of FIG. 2 and the circuit of FIG. 7 according to another embodiment of the present invention, the inductive touch force sensors 200 and 700 according to an embodiment of the present invention are It is coupled to a first inductive coil among the plurality of inductive coils 212 and 712 and is attached to the first inductive coil based on a first displacement of the target layer 240 and 740 with respect to the first inductive coil. a first channel resonant circuit 720 having a first resonant frequency ω1 due to the formed first inductance; a first oscillator 722 for applying a first AC signal to the first channel resonance circuit 720; The second inductive coil is coupled to a second inductive coil of the plurality of inductive coils 212 and 712 and is based on a second displacement of the target layer 240 and 740 with respect to the second inductive coil. a second channel resonant circuit (not shown) having a second resonant frequency ω2 due to a second inductance formed in ; a second oscillator (not shown) for applying a second AC signal to the second channel resonance circuit; a reference resonance circuit having the same impedance as a predetermined first state among states that the first channel resonance circuit 720 may have and a second predetermined state among states that the second channel resonance circuit may have; a reference oscillator having the same characteristics as the first oscillator 722 and the second oscillator and applying a reference AC signal to the reference resonance circuit; and a first electrical signal formed in the first channel resonance circuit 720, a second electrical signal formed in the second channel resonance circuit, and a reference electrical signal formed in the reference resonance circuit, the first displacement, the second based on the first resonant frequency ω1 of the electrical signal, the second resonant frequency ω2 of the second electrical signal, and the reference resonant frequency ω_ref of the reference electrical signal and a determination circuit 770 for determining a displacement, a position to which the external force 750 in the Z-axis direction is input, and the external force 750 .

The determination circuit 770 of the inductive touch force sensors 200 and 700 according to an embodiment of the present invention has the reference electrical signal formed in the reference resonance circuit under the influence of the reference AC signal applied to the reference resonance circuit. detects a difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 of The degree to which 720 deviates from the first state, the first displacement of the targets 240 and 740, and the external force 750 in the Z-axis direction appearing in a first individual region corresponding to the first inductive coil ), and detects a difference between the reference resonant frequency (ω_ref) and the second resonant frequency (ω2), and between the reference resonant frequency (ω_ref) and the second resonant frequency (ω2) The degree to which the second channel resonance circuit deviates from the second state based on the difference, the second displacement of the targets 240 and 740, and the Z appearing in a second discrete region corresponding to the second inductive coil. Quantified sensing information about the external force 750 in the axial direction may be obtained.

The determination circuit 770 of the inductive touch force sensors 200 and 700 according to an embodiment of the present invention determines the difference between the reference resonant frequency ω_ref and the first resonant frequency ω1, or the reference resonant frequency ( If at least one of the difference between ω_ref) and the second resonant frequency ω2 is greater than or equal to the first threshold, at least one of the first resonant frequency ω1 or the second resonant frequency ω2 causes a significant change. It can be determined that the external force 750 in the Z-axis direction is input.

With reference to the inductive touch force sensor 300 of FIG. 3 and the circuit of FIG. 7 according to another embodiment of the present invention, determination of the inductive touch force sensors 300 and 700 according to an embodiment of the present invention The circuit 770 includes a first change pattern of a difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 appearing in the time domain, and the reference resonant frequency ω_ref and the second resonant frequency appearing in the time domain. Based on the second change pattern of the difference (ω2), quantified sensing information about the external force 750 in the Z-axis direction in the first region covered by the first inductive coil, the second inductive coil In the second area covered by the quantified sensing information about the external force 750 in the Z-axis direction, and the user gesture intended by the external force 750 in the Z-axis direction can be recognized.

At this time, even if a determination circuit is not allocated to each individual coil 312 of one module 310a and one determination circuit is allocated to one module 310a, the inductance distribution of the individual coils 312 is substantially time difference can be measured without

With reference to the inductive touch force sensor 400 of FIG. 4 and the circuit of FIG. 7 according to another embodiment of the present invention, determination of the inductive touch force sensors 400 and 700 according to an embodiment of the present invention Based on the difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 , and the difference between the reference resonant frequency ω_ref and the second resonant frequency ω2 , the circuit 770 performs the first Quantified sensing information on the external force 750 in the Z-axis direction in a first region covered by the inductive coil, and the external force 750 in the Z-axis direction in a second region covered by the second inductive coil ) may be extracted, and it may be determined whether the external force in the Z-axis direction is an input intended by the user.

At this time, even if a determination circuit is not allocated to each individual coil 412 of one module 410a and one determination circuit is allocated to one module 410a, the inductance distribution of the individual coils 412 is substantially time difference can be measured without

With reference to the inductive touch force sensor 500 of FIG. 5 and the circuit of FIG. 7 according to another embodiment of the present invention, determination of the inductive touch force sensors 500 and 700 according to an embodiment of the present invention The circuit 770 operates the circuit 770 in the channel region 514 covered by the inductive coil 512 based on a change pattern of the difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 appearing in the time domain. A user gesture intended by the quantified sensing information on the external force 750 in the Z-axis direction and the external force 750 in the Z-axis direction may be recognized. That is, the position change on the XY plane of the external force 750 can be recognized even within the single channel region 514, and the user's intended gesture can be recognized by tracking the position change on the XY plane of the external force 750 on the time domain. have.

8 is a diagram illustrating a circuit and an operation method of the inductive touch force sensor 800 according to an embodiment of the present invention.

1 and 8 together, the inductive touch force sensors 100 and 800 according to an embodiment of the present invention include a first resonance circuit 820 , a first oscillator 822 , and a reference resonance circuit 820a. ), and a reference oscillator 822a. Operations of the first resonance circuit 820 , the first oscillator 822 , the reference resonance circuit 820a , and the reference oscillator 822a of FIG. 8 are similar to those described in the embodiments of FIG. 7 , and thus overlapping descriptions is omitted.

The determination circuit 870 of the inductive touch force sensors 100 and 800 according to an embodiment of the present invention calculates a difference between the first resonant frequency ω1 and the reference resonant frequency ω_ref. An operator circuit 872, a low-pass filter 874 connected to an output terminal of the operator circuit 872 to remove a high-frequency component, and an output terminal of the low-pass filter 874 connected to the first resonant frequency A time-to-digital converter for digitally counting the frequency of the differential frequency component signal corresponding to the difference between (ω1) and the reference resonance frequency (ω_ref) (outputting a digitized value proportional to the frequency of the differential frequency component signal) ( Time-to-Digital Converter) 876 .

The operator circuit 872 may immediately obtain a differential frequency component signal by using an arithmetic operation (addition, subtraction, multiplication) between the first electrical signal and the reference electrical signal. The time-to-digital converter 876 counts the number of pulses of a pulse signal having a differential frequency (or a frequency proportional to the differential frequency) for a predetermined time period, or a pulse having a differential frequency (or a frequency proportional to the differential frequency) You can create a digital count value for the pulse width or period of the signal.

According to an embodiment of the decision circuit 870, it may include a sampler and a comparator for the differential frequency component signal, in which case the sampler and comparator are sufficiently higher than the first threshold for smooth operation of the decision circuit 870. It can be designed by selecting an operating frequency that is large and sufficiently larger than the operating range of the resonance frequency component corresponding to the displacement to be sensed.

In this case, the reference resonant circuit 820a is managed to keep the initialized settings blocked from external influences.

Referring to FIG. 8 together with the inductive touch force sensor 200 of FIG. 2, which is another embodiment of the present invention, a determination circuit 870 of the inductive touch force sensor 200, 800 according to an embodiment of the present invention. Calculator circuit 872 for obtaining the difference between the first resonant frequency ω1 and the reference resonant frequency ω_ref, and for obtaining the difference between the second resonant frequency ω2 and the reference resonant frequency ω_ref. A low-pass filter 874 connected to an output terminal of 872 to remove high-frequency components, and an output terminal of the low-pass filter 874 connected to the first resonant frequency ω1 and the reference resonance The frequency of the first differential frequency component signal corresponding to the difference between the frequencies ω_ref is digitally counted, and the second differential frequency component signal corresponding to the difference between the second resonant frequency ω2 and the reference resonant frequency ω_ref. It may include a time-to-digital converter 876 that digitally counts the frequency.

When a plurality of inductive coils 212 and channels are added, one resonance circuit may be added corresponding to each inductive coil 212 and channels. Even when a plurality of inductive coils 212 and channels are added, the reference resonant circuit 820a and the determination circuit 870 need not be added. An electrical signal received from each of the plurality of inductive coils 212 and the channel is received by the determination circuit 870 by a time multiplexing technique, and the channel resonance frequency of each received electrical signal of each channel and the reference resonance frequency ω_ref By detecting the difference, it is possible to detect the inductance of each channel, the displacement generated in each channel, and the touch force generated in each channel. Although not shown, the inductance of each channel detected by the determination circuit 870, the displacement occurring in each channel, and the touch force data generated in each channel are associated with channel identification information capable of identifying each channel and are associated with memory or storage. can be stored in

In the embodiments of the present invention, since the differential frequency component between the resonant frequency of each channel and the reference resonant frequency (ω_ref) can be obtained immediately in the determination circuits 770 and 870, the inductance of a plurality of channels substantially simultaneously without time delay, Displacement and touch force can be identified.

In the embodiments of the present invention, the resonant frequency information of each channel may be detected independently of the amplitudes of the electrical signals and reference electrical signals of the respective channels (without detection of amplitudes) in the determination circuits 770 and 870 . In this case, according to the embodiment, a conventional technique of detecting amplitude independently of the resonance frequency is applied in parallel, and two pieces of detection information obtained independently of each other (first detection information based on detection of amplitude, resonance frequency independent of amplitude) are applied in parallel according to the embodiment. It is also possible to cross-verify the second detection information based on the detection of .

9 is an operation flowchart illustrating a method of operating an inductive touch force sensor according to an embodiment of the present invention.

The operation method of FIG. 9 may be executed in the inductive touch force sensors 100 , 700 , and 800 to which FIGS. 1 , 7 , and 8 are referred together.

In the operating method of the inductive touch force sensors 100, 700, and 800 according to an embodiment of the present invention, the first oscillators 722 and 822 are coupled to the inductive coils 112 and 712 and the inductive coil ( A first resonant circuit having a first resonant frequency ω1 due to a first inductance formed in the inductive coil 112 , 712 based on the displacement of the target 140 , 740 , 840 with respect to 112 , 712 . applying a first AC signal to (720, 820) (S910); The reference oscillator 822a having the same characteristics as the first oscillators 722 and 822 has the same impedance as a predetermined first state among states that the first resonance circuits 720 and 820 may have. applying a reference AC signal to (820a) (S920); Receiving the first electrical signal formed in the first resonant circuit (720, 820) by the determination circuit (770, 870) under the influence of the first AC signal (S930); receiving, by the determination circuits 770 and 870, a reference electrical signal formed in the reference resonance circuit 820a (S930); and the determination circuit (770, 870) determines the displacement of the target (140, 740, 840) based on the first resonant frequency (ω1) of the first electrical signal and the reference resonance frequency (ω_ref) of the reference electrical signal. and determining the external forces 150 and 750 in the Z-axis direction (S960).

At this time, the determination circuits 770 and 870 detect a difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 ( S940 ), and based on the result of step S940 , the second 1 The degree to which the resonant circuit 720, 820 deviates from the first state, the relative displacement of the target 140, 740, 840 with respect to the inductive coil 112, 712, and the Z-axis direction A step (S960) of obtaining quantified sensing information for the external forces 150 and 750 may be performed.

In this case, the determination circuits 770 and 870 may determine whether the result of step S940 exceeds the first threshold value to determine whether a significant change is detected ( S950 ).

In the method of operating the inductive touch force sensors 500 , 700 , and 800 according to another embodiment of the present invention, the reference resonance frequency ω_ref and the first resonance in which the determination circuits 770 and 870 appear in the time domain Quantified sensing information for the external force 750 in the Z-axis direction in the channel region 514 covered by the inductive coils 512 and 712 based on a change pattern of the difference in frequency ω1, and the Z The method may further include recognizing a user gesture assumed to be intended by the user based on the external force 750 in the axial direction.

10 is an operation flowchart illustrating a method of operating an inductive touch force sensor according to an embodiment of the present invention.

The operation method of FIG. 10 may be executed in the inductive touch force sensors 200 , 700 , and 800 to which FIGS. 2 , 7 , and 8 are referred together.

In the method of operating the inductive touch force sensors 200, 700, and 800 according to an embodiment of the present invention, steps S910 to S930 of FIG. 9 are performed for the first channel, and in particular, the determination circuits 770 and 870 are Perform S930. Also, steps S910 to S930 of FIG. 9 are individually performed for the second channel.

a decision circuit (770, 870) determines the first displacement, the first displacement based on the first resonant frequency of the first electrical signal, the second resonant frequency of the second electrical signal, and a reference resonant frequency of the reference electrical signal A second displacement, a position at which the external force in the Z-axis direction is input, and steps S1020 and S1040 of determining the external force are performed.

In this case, the step of the determination circuit determining the position and the external force to which the external force in the Z-axis direction is input may include: detecting a difference between the reference resonance frequency and the first resonance frequency (S1010); detecting a difference between the reference resonant frequency and the second resonant frequency (S1030); a degree to which the first resonant circuit deviates from the first state based on a difference between the reference resonant frequency and the first resonant frequency, the first displacement of the target, and a first individual corresponding to the first inductive coil obtaining quantified sensing information about the external force in the Z-axis direction appearing in the region (S1020, S1060); and a degree to which the second resonant circuit deviates from the second state based on a difference between the reference resonant frequency and the second resonant frequency, the second displacement of the target, and a second corresponding to the second inductive coil The method may further include obtaining quantified sensing information on the external force in the Z-axis direction appearing in individual regions (S1040 and S1060).

The determination circuits 770 and 870 determine whether the sensed touch force for the first channel and the second channel is an input intended by the user, based on the results of steps S1020 and S1040, and determines whether an error or other unintended user input It is determined whether there is a signal fluctuation due to a factor (S1050).

If it is determined that the touch force is an input intended by the user as a result of performing step S1050, the determination circuits 770 and 870 determine the position where the touch force is input and the magnitude of the touch force with respect to the region including the first channel and the second channel. Digitize and quantify (S1060).

11 is a diagram illustrating an inductive touch force sensor 1100 according to an embodiment of the present invention. 11 shows an inductive touch force sensor 1100 assuming a single button/channel/coil.

11 is an embodiment in which the first component 1140 of FIG. 11 performs the functions of the target layer 140 and the first component 130 in the embodiment of FIG. 1 . That is, in FIG. 11 , a separate target layer does not exist, and displacement in the Z-axis direction according to the deformation of the first component 1140 is shown by the inductive coupling of the inductive coil 1112 and the first component 1140 . It can be detected through a change in inductance and a change in resonant frequency.

In FIG. 11 , the external force 1150 , the substrate 1110 , and the spacer layer 1160 are the same as the external force 150 , the substrate 110 , and the spacer layer 160 of FIG. 1 , and thus overlapping descriptions will be omitted.

Conventional inductive sensing technologies are difficult to precisely measure the displacement in the Z-axis direction of the first component 1140 due to the external force 1150, and thus, as part of an effort to increase the accuracy of the measurement, the first The target layer 140 is separately disposed under the component 130 , and when the target layer 140 is displaced in the Z-axis direction based on the deformation of the first component 130 in the Z-axis direction, the displacement is sensed. However, in the embodiment of the present invention, since the change in inductance is detected through the difference in the resonant frequency of the differential signal, the quantification and digitization of the measured value is easy, so that the sensitivity of the displacement is high. Therefore, it is possible to detect and quantify the external force 1150 in the Z-axis direction with only one first part 1140 as shown in FIG. 11 . At this time, according to the distance in the Z-axis direction between the first component 1140 and the inductive coil 1112, the first component 1140 and the inductive coil 1112 are connected to the inductive coil 1112 by inductive coupling. The inductance of the resonant circuit is fluctuated. Accordingly, a change in inductance and a change in resonant frequency are detected only by displacement of the first component 1140 in the Z-axis direction, and it is possible to detect and quantify the external force 1150 in the Z-axis direction. At this time, when the first component 1140 is deformed and an eddy current is induced in a portion closer to the inductive coil 1112 , the change in the combined inductance due to the displacement in the Z-axis direction of the first component 1140 is detected. Accordingly, the first component 1140 may be implemented to be electrically conductive.

12 is a diagram illustrating an inductive touch force sensor 1200 according to an embodiment of the present invention.

12 is an embodiment in which the second component 1230 of FIG. 12 performs the functions of the target layer 240 and the second component 230 in the embodiment of FIG. 2 . That is, in FIG. 12 , a separate target layer does not exist, and displacement in the Z-axis direction according to the deformation of the individual regions 1232 in the second component 1230 is caused by the plurality of inductive coils 1212 and the second component. It may be detected through a change in inductance and a change in resonant frequency indicated by inductive coupling between individual regions 1232 in 1230 .

In FIG. 12 , the substrate 1210 and the spacer layer 1260 are the same as the substrate 210 and the spacer layer 260 of FIG. 2 , and thus overlapping descriptions will be omitted.

Conventional inductive sensing techniques are difficult to precisely measure the displacement in the Z-axis direction of each of the individual regions 1232 in the second part 1230 due to an external force, so as part of an effort to increase the accuracy of measurement, FIG. 2 Separately disposing the target layer 240 under the second part 230 as in, based on the deformation of the second part 230 in the Z-axis direction, when the target layer 240 is displaced in the Z-axis direction, the Displacement is detected. However, in the embodiment of the present invention, since the change in inductance is detected through the difference in the resonant frequency of the differential signal, the quantification and digitization of the measured value is easy, so that the sensitivity of the displacement is high. Therefore, as in FIG. 12 , a target layer is not disposed and each of the individual regions 1232 is formed by inductive coupling between each of the individual regions 1232 in the second component 1230 and the plurality of inductive coils 1212 . Displacement can be detected and quantified.

When an external force is applied to the first individual region among the individual regions 1232 to deform the first individual region and the first individual region is displaced in the Z-axis direction, the first individual region among the plurality of inductive coils 1212 Whether an external force is applied to the first individual region and a magnitude of the external force may be determined based on a change in inductance sensed in the first inductive coil facing the ? Displacement in the Z-axis direction of the first individual region (deformation of the first individual region with respect to the first inductive coil and displacement in the Z-axis direction) of the first individual region by the inductive coupling between the first inductive coil and the first individual region is first It affects the inductance of the first resonant circuit to which the inductive coil is connected. Based on the changed inductance of the first resonant circuit, the change of the first resonant frequency ω1 of the first resonant circuit is determined by the difference between the reference resonant frequency ω_ref and the first resonant frequency ω1 in the determination circuits 770 and 870 . based on the detection, and based on the difference between the reference resonant frequency ω_ref and the first resonant frequency ω1, a change in the first resonant frequency ω1 is quantified. The quantified change in the first resonant frequency ω1 may be digitized and stored in a separate memory or storage.

At this time, the inductance of the resonant circuit connected to each of the inductive coils 1212 is changed by inductive coupling between the respective regions 1232 in the second component 1230 and the opposing inductive coils 1212 . Accordingly, a change in inductance and a change in resonant frequency are detected only by displacement of the individual regions 1232 in the Z-axis direction, and it is possible to detect and quantify an external force in the Z-axis direction. At this time, when an eddy current is induced in a portion of the individual regions 1232 in the second component 1230 that is closer to the inductive coils 1212 by an external force, synthesis by displacement in the Z-axis direction A change in inductance is detected. When the individual regions 1232 are implemented so that the eddy current is easily induced, the change in the combined inductance is more easily seen, and thus the sensitivity of the sensor can be improved. At this time, in order to easily induce an eddy current in the individual regions 1232 , the individual regions 1232 in the second part 1230 may be implemented to have higher electrical conductivity than the remaining regions in the second part 1230 . can For example, by disposing a thin metal film such as aluminum, which is a non-magnetic material and an electrical conductor, in the individual regions 1232 , the electrical conductivity of the individual regions 1232 may be increased, and displacement of the individual regions 1232 in the Z-axis direction sensitivity can be improved.

13 is a diagram illustrating an electronic device 1300 including an inductive touch force sensor and a power button according to an embodiment of the present invention.

As mentioned earlier, if a cut out free enclosure can be implemented, a high IP rating can be implemented, and a wearable device with a higher IP rating can be utilized for various purposes that were not previously utilized. have. If gasket-less and no moving parts, wearable devices can become physically more robust and embedded in wearable elements such as gloves, for example. It can also be used under water.

When the embodiment of FIGS. 7 and 8 is applied to the embodiment of FIG. 13 , the electronic device 1300 according to an embodiment of the present invention includes an enclosure 1330 of an exterior surrounding the electronic device 1300 , and the enclosure. a first area 1380 disposed on 1330 and operating as a Power-On Button; and a plurality of second regions ( 1332). A pressure-sensing variable resistor (not shown) in response to external pressure is disposed in the first region 1380 , and the pressure-sensing variable resistor and the internal power source (not shown) of the electronic device 1300 turn on the power button. It is connected to an off detection circuit (not shown). The plurality of inductive coils 1312 and 712 disposed to be spaced apart from the second regions 1332 in the electronic device 1300 and disposed to face each of the second regions 1332 are formed in the second regions. (1332) the individual channel resonance frequency (ω_i) deviating from the reference resonance frequency (ω_ref) based on the individual channel displacement (Δd_i) each elastically deformed along the Z-axis direction by an external force applied in the Z-axis direction forming, the determination circuits 770 and 870 determine the individual channel displacement Δd_i based on the individual channel resonant frequency ω_i, and the external force F_i applied in the Z-axis direction to each of the second regions 1332 can be determined.

In FIG. 13 , the substrate 1310 is the same as the substrate 1210 of FIG. 12 and the substrate 210 of FIG. 2 , and the spacer layer 1360 includes the spacer layer 1260 of FIG. 12 and the spacer layer of FIG. 2 ( 260), and thus overlapping descriptions will be omitted.

13 , the target layer is not shown. When there is no target layer, the individual channel displacement Δd_i means displacement in the Z-axis direction of the elastic second regions 1332 . An amount of change in a distance d_i between each of the elastic second regions 1332 and each of the plurality of inductive coils 1312 and 712 in the Z-axis direction may be defined as an individual channel displacement Δd_i.

In another embodiment of the present invention in which the embodiment of FIGS. 1 and 2 is applied to the embodiment of FIG. 13 , an embodiment in which the target layers 140 and 240 are arranged to be in contact with the second regions 1332 may also be implemented. It will be apparent to those skilled in the art that there is.

13, 7, and 8 again, a plurality of individual channel resonant circuits 720 and 820 are coupled to the plurality of inductive coils 1312 and 712, respectively, and the plurality of inductive coils are coupled to each other. Formed in each of the plurality of inductive coils 1312 and 712 based on the respective channel displacement Δd_i in the Z-axis direction of each of the plurality of second regions 1332 for each of 1312 and 712 It has an individual channel resonant frequency ω_i due to the individual channel inductance. The reference resonance circuit 820a is set to have the same impedance as a predetermined first state among states that the plurality of individual channel resonance circuits 720 and 820 may have. The first state at this time is assuming that the external force F_i applied from the Z-axis direction to each of the plurality of second regions 1332 is 0, the reference resonance circuit 820a and the plurality of individual channel resonance circuits ( 720, 820) may be designed.

Determination circuits 770 and 870 include a reference electrical signal formed in the reference resonance circuit 820a under the influence of a reference AC signal applied to the reference resonance circuit 820a, and the plurality of individual channel resonance circuits 720, 820) Receives each of a plurality of individual channel electrical signals formed in each of the plurality of individual channel resonance circuits 720 and 820 under the influence of each of the individual channel AC signals applied to each, and the reference resonance of the reference electrical signal The individual channel displacement Δd_i based on each of the frequency ω_ref, and the individual channel resonance frequencies ω_i of each of the plurality of individual channel electrical signals, the Z-axis of the plurality of second regions 1332 A position at which the external force F_i applied in the direction is input and the external force F_i applied in the Z-axis direction may be determined.

In the power button on/off detection circuit, when a change in the resistance value of the pressure sensing variable resistor due to external pressure on the first region 1380 is greater than or equal to a first threshold value, the internal power supply is applied to the plurality of inductive coils ( 1312 and 712 , the plurality of individual channel resonance circuits 720 and 820 , the reference resonance circuit 820a, and the determination circuits 770 and 870 may be controlled to be applied.

The pressure-sensing variable resistor may be implemented using a well-known material, for example, Velostat or Linqstat, well-known as a Pressure-Sensitive Conductive Sheet. In this case, when the pressure in the Z-axis direction is applied to the pressure sensing variable resistor, the resistance value of the pressure sensing variable resistor is lowered, so that the power button on/off detecting circuit may be implemented such that the switch of the power button on/off detecting circuit is turned on.

When the resistance value of the pressure sensing variable resistor is lowered and the change in the resistance value from the OFF state is greater than or equal to the first threshold value, a switching operation in which the switch that has been blocked in the power button on-off detection circuit is turned on occurs, and the power supply is generated by the switching operation The button on-off detection circuit is the internal power source of the plurality of inductive coils 1312 and 712, the plurality of individual channel resonance circuits 720 and 820, the reference resonance circuit 820a, and the determination circuit ( 770 and 870), it is possible to control the peripheral circuit of the internal power supply.

The determination circuits 770 and 870 are configured to determine the plurality of individual channel resonance frequencies ω_i of each of the plurality of individual channel resonance circuits 720 and 820 based on the degree of deviation from the reference resonance frequency ω_ref. The degree to which each of the channel resonance circuits 720 and 820 deviates from the first state, the individual channel displacement Δd_i in the Z-axis direction of each of the plurality of second regions 1332 , and the plurality of second regions It is possible to obtain quantified sensing information on the external force F_i applied in the Z-axis direction to each of the 1332 .

Applying the embodiment of FIG. 9 to the embodiment of FIG. 13 , the determination circuit 770 , 870 is a first individual of the individual channel resonance frequencies ω_i of each of the plurality of individual channel resonance circuits 720 and 820 . If the degree to which the channel resonant frequency ω1 deviates from the reference resonant frequency ω_ref is greater than or equal to the second threshold, it is considered that the first individual channel resonant frequency ω1 has caused a significant change, and the first individual channel resonant frequency ( It may be determined that the external force F1 applied in the Z-axis direction is input to the first individual region corresponding to the first individual channel resonance circuit where ω1 is formed.

According to an embodiment of the present invention in which the embodiment of FIG. 5 or 6 is applied to the plurality of inductive coils 1312 and 712 of FIG. 13 , the determination circuits 770 and 870 are the reference resonant frequencies appearing in the time domain. In the Z-axis direction in the first individual region covered by the first inductive coil coupled to the first individual channel resonance circuit based on a change pattern of the difference between (ω_ref) and the first individual channel resonance frequency (ω1) A user gesture intended by the quantified sensing information on the applied external force F_i and the external force F_i applied in the Z-axis direction may be recognized.

According to an embodiment of the present invention in which the embodiment of FIGS. 3 and 10 is applied to the embodiment of FIG. 13 , the determination circuits 770 and 870 are the first individual among the plurality of individual channel resonance circuits 720 and 820 . A first change pattern appearing in the time domain with respect to the difference between the first individual channel resonance frequency ω1 of the channel resonance circuit and the reference resonance frequency ω_ref, and the second of the plurality of individual channel resonance circuits 720 and 820 . Based on a second change pattern appearing in the time domain with respect to a difference between a second individual channel resonant frequency ω2 of the two individual channel resonant circuit and the reference resonant frequency ω_ref, the first individual channel resonant circuit combined First quantified sensing information about the external force F1 applied in the Z-axis direction in the first individual region covered by the inductive coil, and the second inductive coil to which the second individual channel resonance circuit is coupled A user gesture intended by the quantified second sensing information on the external force F2 applied in the Z-axis direction and the external force F1 and F2 applied in the Z-axis direction in the second individual region can be recognized. .

According to an embodiment of the present invention in which the embodiment of FIGS. 4 and 10 is applied to the embodiment of FIG. 13 , the determination circuits 770 and 870 are the first individual among the plurality of individual channel resonance circuits 720 and 820 . A first change pattern appearing in the time domain with respect to the difference between the first individual channel resonance frequency ω1 of the channel resonance circuit and the reference resonance frequency ω_ref, and the second of the plurality of individual channel resonance circuits 720 and 820 . Based on a second change pattern appearing in the time domain with respect to a difference between a second individual channel resonant frequency ω2 of the two individual channel resonant circuit and the reference resonant frequency ω_ref, the first individual channel resonant circuit combined First quantified sensing information about the external force F1 applied in the Z-axis direction in the first individual region covered by the inductive coil, and the second inductive coil to which the second individual channel resonance circuit is coupled Extracts quantified second sensing information on the external force F2 applied in the Z-axis direction from a second individual region, and an external force applied in the Z-axis direction based on the first sensing information and the second sensing information It can be determined whether (F1, F2) is an input intended by the user.

Referring again to FIGS. 13, 7, and 8 , the determination circuits 770 and 870 determine that each of the individual channel resonance frequencies ω_i of each of the plurality of individual channel resonance circuits 720 and 820 is the reference resonance. an operator 872 for obtaining quantified information about the degree of deviation from the frequency ω_ref; a low pass filter (874) connected to the output terminal of the calculator (872) to remove a high-frequency component; and each of the individual channel resonant frequencies ω_i of each of the plurality of individual channel resonance circuits 720 and 820 connected to the output terminal of the low-pass filter 874 deviate from the reference resonance frequency ω_ref. It may include a time-to-digital converter (876) for digitally counting the frequency of the differential frequency component signal.

The determination circuit (770, 870) is the plurality of individual channel resonant circuits (720, 820) in a state forcibly adjusted from the outside so that each of the plurality of individual channel resonant circuits (720, 820) are in the first state A calibration process is performed for each of the plurality of individual channel resonance circuits 720 and 820 based on quantified information about the degree to which each of the individual channel resonance frequencies ω_i deviate from the reference resonance frequency ω_ref. can do.

According to the present invention, various user gestures can be recognized by realizing a plurality of user buttons as an inductive touch force sensor in an electronic device having an enclosure that does not require a cutout, and the inductive touch force sensor is driven It is possible to implement an electronic device including a stable power-on button for this purpose.

When a plurality of user buttons disposed in an external enclosure surrounding the electronic device are implemented as an inductive touch force sensor, internal power must be supplied to the inductive touch force sensor in advance for operation of the inductive touch force sensor. do. In this case, always turning on the internal power supply will shorten the operating life of the electronic device, so a means for turning on/off the internal power from the outside is required. The present invention has a long operating life and can be applied to a wide range of applications by implementing an electronic device including a power button that can stably turn on/off internal power from the outside and a user button implemented as an inductive touch force sensor. It is possible to implement an electronic device with The electronic device of the present invention is physically robust because it has a high IP rating. The electronic device of the present invention may be used in an underwater environment, and may be applied to a wearable device even in a dusty or sweaty situation.

The circuit operation method according to an embodiment of the present invention may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and carry out program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

However, the present invention is not limited or limited by the examples. Like reference numerals in each figure indicate like elements. Length, height, size, width, etc. introduced in the embodiments and drawings of the present invention may be exaggerated to help understanding.

As described above, the present invention has been described with specific matters such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

100, 200, 300, 400, 500, 600, 700, 800, 1100, 1200: inductive touch force sensor
1300: electronic device
110, 210, 1110, 1210, 1310: PCB
310a, 410a: one module consisting of a set of a plurality of coils
112, 212, 312, 412, 1112, 1212, 1312: inductive coil
512, 612: channel coil
514, 614: channel area
130, 230, 1130, 1230: deformable parts
1330: enclosure
232: individual area
140, 240: target layer
150, 750: external force (external force)
452: range in which external force is input
160, 260, 1160, 1260, 1360: spacer layer
770, 870: judgment circuit

Claims (9)

In an electronic device,
an enclosure for enclosing the electronic device;
a first area disposed on the enclosure and operating as a power-on button;
a plurality of second regions on the enclosure other than the first region, arranged to be elastically deformable along the Z-axis direction by an external force applied in the Z-axis direction;
a pressure sensing variable resistor disposed in the first region and responsive to external pressure;
a power button on/off detection circuit connected to the pressure sensing variable resistor and an internal power source of the electronic device;
a plurality of inductive coils formed in the electronic device on a substrate spaced apart from the plurality of second regions and disposed to face each of the plurality of second regions;
It is coupled to each of the plurality of inductive coils and is formed in each of the plurality of inductive coils based on an individual channel displacement in the Z-axis direction of each of the plurality of second regions with respect to each of the plurality of inductive coils a plurality of individual channel resonant circuits having an individual channel resonant frequency due to an individual channel inductance;
a reference resonance circuit having the same impedance as a predetermined first state among states that the plurality of individual channel resonance circuits may have; and
The plurality of individual channels under the influence of the reference electric signal formed in the reference resonance circuit under the influence of the reference AC signal applied to the reference resonance circuit, and the individual channel AC signal applied to each of the plurality of individual channel resonance circuits. Receive each of a plurality of individual channel electrical signals formed in each of the resonant circuits, and based on a reference resonance frequency of the reference electrical signal and respective respective channel resonance frequencies of each of the plurality of individual channel electrical signals a determination circuit for determining a channel displacement, a position at which an external force applied in the Z-axis direction is input among the plurality of second regions, and an external force applied in the Z-axis direction;
including,
The judgment circuit is
The degree to which each of the plurality of individual channel resonant circuits deviates from the first state based on the degree to which each of the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits deviates from the reference resonant frequency; Obtaining quantified sensing information about the individual channel displacement in the Z-axis direction of each of the regions, and the external force applied in the Z-axis direction to each of the plurality of second regions,
electronic device. In an electronic device,
an enclosure for enclosing the electronic device;
a first area disposed on the enclosure and operating as a power-on button;
a plurality of second regions on the enclosure other than the first region, arranged to be elastically deformable along the Z-axis direction by an external force applied in the Z-axis direction;
a pressure sensing variable resistor disposed in the first region and responsive to external pressure;
a power button on/off detection circuit connected to the pressure sensing variable resistor and an internal power source of the electronic device;
a plurality of inductive coils formed in the electronic device on a substrate spaced apart from the plurality of second regions and disposed to face each of the plurality of second regions;
It is coupled to each of the plurality of inductive coils and is formed in each of the plurality of inductive coils based on an individual channel displacement in the Z-axis direction of each of the plurality of second regions with respect to each of the plurality of inductive coils a plurality of individual channel resonant circuits having an individual channel resonant frequency due to an individual channel inductance;
a reference resonance circuit having the same impedance as a predetermined first state among states that the plurality of individual channel resonance circuits may have; and
The plurality of individual channels under the influence of the reference electric signal formed in the reference resonance circuit under the influence of the reference AC signal applied to the reference resonance circuit, and the individual channel AC signal applied to each of the plurality of individual channel resonance circuits. Receive each of a plurality of individual channel electrical signals formed in each of the resonant circuits, and based on a reference resonance frequency of the reference electrical signal and respective respective channel resonance frequencies of each of the plurality of individual channel electrical signals a determination circuit for determining a channel displacement, a position at which an external force applied in the Z-axis direction is input among the plurality of second regions, and an external force applied in the Z-axis direction;
including,
The power button on-off detection circuit is
When a change in the resistance value of the pressure sensing variable resistor is greater than or equal to a first threshold value due to external pressure on the first region, the internal power supply may include the plurality of inductive coils, the plurality of individual channel resonance circuits, and the A reference resonance circuit, and an electronic device for controlling to be applied to the determination circuit. delete According to claim 1,
The judgment circuit is
If the degree of deviation of the first individual channel resonant frequency from the reference resonant frequency among the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits is greater than or equal to the second threshold, it is determined that the first individual channel resonant frequency has caused a significant change. An electronic device that determines that the external force applied in the Z-axis direction is input to a first individual region corresponding to a first individual channel resonance circuit in which the first individual channel resonance frequency is formed. 5. The method of claim 4,
The judgment circuit is
The Z-axis in the first individual region covered by the first inductive coil coupled to the first individual channel resonance circuit based on a change pattern of the difference between the reference resonance frequency and the first individual channel resonance frequency appearing in the time domain An electronic device for recognizing a user gesture intended by the quantified sensing information on the external force applied in the direction and the external force applied in the Z-axis direction. According to claim 1,
The judgment circuit is
a first change pattern appearing in the time domain with respect to a difference between a first individual channel resonant frequency of a first individual channel resonant circuit among the plurality of individual channel resonant circuits and the reference resonant frequency, and among the plurality of individual channel resonant circuits Based on a second change pattern appearing in the time domain with respect to the difference between the second individual channel resonant frequency of the second individual channel resonant circuit and the reference resonant frequency, the first inductive coil coupled to the first individual channel resonant circuit covers quantified first sensing information on the external force applied in the Z-axis direction in the first individual region to An electronic device for recognizing a user gesture intended by the quantified second sensing information on the external force applied in the direction and the external force applied in the Z-axis direction. According to claim 1,
The judgment circuit is
a first change pattern appearing in the time domain with respect to a difference between a first individual channel resonant frequency of a first individual channel resonant circuit among the plurality of individual channel resonant circuits and the reference resonant frequency, and among the plurality of individual channel resonant circuits Based on a second change pattern appearing in the time domain with respect to the difference between the second individual channel resonant frequency of the second individual channel resonant circuit and the reference resonant frequency, the first inductive coil coupled to the first individual channel resonant circuit covers quantified first sensing information on the external force applied in the Z-axis direction in the first individual region to Extracts quantified second sensing information on the external force applied in the direction, and determines whether the external force applied in the Z-axis direction is an input intended by the user based on the first sensing information and the second sensing information An electronic device for judging. According to claim 1,
The judgment circuit is
an operator for obtaining quantified information on a degree to which each of the individual channel resonance frequencies of the plurality of individual channel resonance circuits deviate from the reference resonance frequency;
a low pass filter connected to the output terminal of the calculator to remove a high frequency component; and
It is connected to the output terminal of the low-pass filter and digitally counts the frequency of the differential frequency component signal corresponding to the degree to which each of the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits deviates from the reference resonant frequency time-to- Time-to-Digital Converter;
An electronic device comprising a. According to claim 1,
The judgment circuit is
The degree to which each of the individual channel resonant frequencies of each of the plurality of individual channel resonant circuits deviate from the reference resonant frequency in a state in which each of the plurality of individual channel resonant circuits is externally forcibly adjusted to be in the first state An electronic device that performs a calibration process for each of the plurality of individual channel resonance circuits based on the quantified information.

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