Abstract: An input apparatus includes a touch plate, a decoration layer, a film sensor, an electrode portion, a wire portion, and a guard layer. The touch plate is a basal plate for finger manipulation. The decoration layer is on a front side of the touch plate to decorate the front side. The film sensor is bonded to a rear side of the touch plate. The electrode portion is on the film sensor. The wire portion is on the film sensor and connected to the electrode portion to transmit a signal outputted from the electrode portion. The guard layer contains a guard layer formation material to suppress an electrostatic capacity between the finger and the wire portion. The guard layer formation material is combined into the decoration layer such that the decoration layer and the guard layer are provided as a single integrated member.

Abstract: An electronic switch, or an electronic equipment having such switch that has a tap-sensing detection region for a user to perform finger-tapping, foot-tapping, or other finger movements on a contact surface in this region and effectuate sending of a signal to turn on, turn off, or perform other contemplated functions of the electronic equipment. This switch emits a radiation, such as infrared light, towards the detection region. The reflection of the radiation off of an object is collected and compared to a predetermined value. If there is a match, the switch would send a signal to the device to perform the predetermined function. In operation, the switch would allow an electrical equipment to have a “virtual switch” where the user can control the device by manipulating his finger or his foot in the designated detection region. The equipment may optionally have a LED illuminator to shine a lit marking indicating where the contact surface is and how it is to be used.

Abstract: An electrode device for a capacitive sensor device and a circuit arrangement for a capacitive sensor device for the operation of an electrode device are provided, wherein the electrode device has a first electrode structure with at least one transmitting electrode and at least one receiving electrode, and a second electrode structure with at least one field sensing electrode, wherein the electrode device or the capacitive sensor device can be operated in a first operation mode and in a second operation mode. In addition a method is provided for approach and/or touch detection with a sensor device.

Abstract: A system includes a capacitively-coupled touch sensor having a conductive first layer and a conductive second layer on a first insulative layer. The width of the second layer varies along an axis of the first layer. A first excitation signal is applied to one of the first and second layers and is capacitively coupled through a touch element to the other layer, producing a first signal that produces a second signal which is digitized. Digitized peak values of the second signal are processed to compute a value for a touch element location. A conductive third layer can be placed on the opposite side of the first layer has width varying oppositely to the second layer. The first excitation signal is applied to the second layer and a non-overlapping second excitation signal is applied to the third layer. The resulting digitized peak values are processed to cancel errors due to variations.

Abstract: A sensing apparatus and method are provided for determining an input point of a touch. A sensing loop unit includes at least one loop. Each of the at least one loop includes two sub-loops separated by a predetermined distance. An area determination loop unit determines one of the two sub-loops of each of the at least one loop that corresponds to the input point. A controller determines a plurality of candidates of the input point based on a first input signal from the sensing loop unit, and determines the input point from among the plurality of candidates of the input point based on a second input signal from the area determination loop unit.

Abstract: In one embodiment, a touch sensor includes a substrate. A plurality of conductive elements are formed on the substrate. A plurality of sacrificial conductive members overlay portions of the plurality of conductive elements. The sacrificial conductive members function as sacrificial anodes for the conductive elements.

Abstract: A touch sensor using a graphene diode and/or a touch panel including the touch sensor. The touch sensor includes a first sensing electrode configured to sense a touch; a first output line configured to transmit an electrical signal; and a first diode device including a first control terminal connected to the first sensing electrode, a first anode terminal connected to a voltage application unit, and a first cathode terminal connected to the first output line.

Abstract: In accordance with one or more example embodiments, wireless communications are facilitated based on user-motion. A portable motion-sensing circuit, carried by a user, indicates that motion is sensed in response to detecting whether the user has been moving for a predetermined period of time. A communication circuit operates in active mode and inactive modes respectively consuming higher and lower power, permits or inhibits access authentication communications in the active and inactive modes, and operates in the active mode in response to the motion being sensed at the motion-sensing circuit.

Abstract: A wireless device for providing specific absorption rate (SAR) control comprising a wireless transmitter, a capacitance sensor, and a processor coupled to the wireless transmitter and the capacitance sensor, wherein the processor is configured to receive a first capacitance measurement from the capacitance sensor, estimate a relative proximity of a human body to the apparatus based on the measurement, determine a target transmission time for the wireless transmitter within a time period based on the estimate, and switch off the wireless transmitter for a portion of the time period if a transmission time of the wireless transmitter during the time period exceeds the target transmission time.

Abstract: Disclosed herein are a touch panel and a method for manufacturing the same. The touch panel 100 according to preferred embodiments of the present invention includes: first electrode patterns 120 containing silver formed by selectively exposing/developing silver salt emulsion layers and formed as fine patterns on one surface of the transparent substrate 110; first wirings 160 that are integrally formed with the first electrode patterns 120; second electrode patterns 130 containing silver formed by selectively exposing/developing the silver salt emulsion layers 150 and formed on the other surface as fine patterns of the transparent substrate 110; second wirings 170 integrally formed with the second electrode patterns 130; and optical filter layers 140 that are formed between one surface of the transparent substrate 110 and the first electrode patterns 120 or between the other surface of the transparent substrate 110 and the second electrode patterns 130 to selectively block light.

Abstract: Disclosed herein is a connection structure between a substrate and a flexible printed circuit board (FPCB) for a touch panel, including: a substrate; first sensing electrodes; second sensing electrodes; first electrode wirings; second electrode wirings; and a flexible printed circuit board connected to the substrate so as to be electrically connected to the first and second electrode wirings, wherein a first connection portion of the first electrode wiring and a second connection portion of the second electrode wiring to which the flexible printed circuit board is electrically connected are formed on the upper and lower surfaces of the substrate, respectively, so as to face each other in a vertical direction. Therefore, the flexible printed circuit substrate may be connected to the substrate by a single assembling process.

Abstract: A detection device includes a resonance unit having a coil and a capacitor, an oscillation unit for oscillating the resonance unit, and a signal processing unit for detecting the oscillation state of the resonance unit and outputting an object detection signal when oscillation is stopped. The signal processing unit intermittently executes a self-diagnosis mode by forcibly oscillating the oscillation unit to determine whether or not an abnormality occurs in the resonance unit.

Abstract: Provided is a touch sensor having a simple structure and enabling a driver to appropriately and quickly manipulate the touch sensor as intended without looking at a manipulation surface of the touch sensor. The touch sensor includes: multiple electrodes; detection means for detecting touch on any of electrodes and for outputting a detection signal for each electrode; touch judgment means for judging whether each of the electrodes is touched or untouched based on the detection signal; a switch having a manipulation button; control mode judgment means for determining a control function for a controlled device in accordance with an input signal transmitted from the switch when the manipulation button is manipulated; and permission means for permitting the touch judgment means to judge touch on each electrode in response to the input signal from the switch.

Abstract: A touch pad capacitive sensor circuit has a signal generator that generates an oscillation signal having an oscillation frequency variable dependent on a capacitance in the sensor circuit. A switch switches a touch pad capacitive sensor of a capacitive touch pad connected to the signal generator in first and second cycles of the switch. A counter counts a first count of cycles of the oscillation signal when the sensor is connected to the signal generator in a first cycle of operation of the switch and a second count of cycles of the oscillation signal when the sensor is connected to the signal generator in a second cycle of operation. A detector detects when the first and second counts are below a low threshold number. The sensor circuit flags a valid user touch depending on an output of the detector.

Abstract: In one embodiment, a method comprises generating, by a control unit, a first drive signal and a second drive signal. The method further comprises emitting, by a conductive wire coupled to a capacitive touch sensor, a first electric field that extends in a plurality of directions in response to reception of the first drive signal. The method further comprises shaping, by a conductive shield that surrounds the conductive wire, at least a portion of the first electric field that extends from the capacitive touch sensor towards the conductive shield by generating a second electric field in response to reception of the second drive signal.

Abstract: A proximity switch assembly and method are provided having wrong touch feedback. The switch includes a plurality of proximity switches each including proximity sensors providing a sense activation field. Control circuitry processes the activation field of each proximity switch to sense activation, detects an allowed activation of one of the proximity switches and further detects an attempted activation that is not allowed. The switch further includes an output coupled to a device to perform a function when an allowed activation is detected. The switch includes one or more user perceived feedback devices for generating user perceived feedback when an attempted activation that is not allowed is detected.

Abstract: A user interface which includes a capacitive measurement circuit with a sense plate covered by an electrically conductive cover member, and wherein said circuit may sense two types of events, said types distinguished by an inverse change in measured capacitance, and wherein user proximity and touches with less than a minimum required force constitute one event type, and touches with more than said minimum force constitute the other event type.

Abstract: In an electrical stimulation device and an electrical stimulation method thereof, electrical stimulation can be adjusted more in real time, and stability and safety of the electrical stimulation can be more improved. An electrical stimulation device includes an electrode an electrical signal supply section, a skin impedance detection section, and an electrical signal controller. The electrical signal supply section supplies an electrical signal for generating the electrical stimulation to the electrode. During the supply of the electrical signal, the electrical signal controller acquires information associated with skin impedance through the skin impedance detection section in a cycle shorter than a supply period of the electrical signal, and adjusts the electrical signal to be supplied to the electrode in the next cycle based on the acquired information associated with skin impedance.

Abstract: Methods, systems and devices are described for detecting a position-based attribute of a finger, stylus or other object with a touchpad or other sensor having a touch-sensitive region that includes a plurality of electrodes. Modulation signals for one or more electrodes are produced as a function of any number of distinct digital codes. The modulation signals are applied to an associated at least one of the plurality of electrodes to obtain a resultant signal that is electrically affected by the position of the object. The resultant signal is demodulated using the plurality of distinct digital codes to discriminate electrical effects produced by the object. The position-based attribute of the object is then determined with respect to the plurality of electrodes from the electrical effects.

Abstract: A touch switch including: at least two of operation faces provided side by side; a detection electrode provided in each of the operation faces and including a wiring pattern of an electric conductor formed on or immediately below the operation face; and a controller connected to each of the detection electrodes to perform a switching operation by detecting variations of capacitance sensed by each of the detection electrodes, the variation of capacitance being generated when a human body part is in proximity to or in contact with each of the operation faces. At least one of the detection electrodes includes a wiring pattern more sparsely formed in a vicinity area of a boundary with another operation face adjacent thereto compared to a wiring pattern of the detection electrode provided in the adjacent operation face. Therefore, detection errors or accidental operations between adjacent switches can be prevented from happening.

Abstract: A touch panel includes a substrate, a transparent conductive layer, a conductive decoration pad, a decoration layer and an opaque conductive layer. The transparent conductive layer is disposed on the substrate, and the conductive decoration pad is disposed on the transparent conductive layer. The decoration layer is disposed on the conductive decoration pad and the transparent conductive layer, and has an opening located on the conductive decoration pad. The opaque conductive layer is disposed on the decoration layer and electrically connected with the transparent conductive layer through the opening and the conductive decoration pad.

Abstract: Provided is a capacitive sensor device capable of detecting the position and magnitude of external force with high accuracy. Employed is a capacitive sensor which comprises pairs of electrodes arranged in a matrix, each of the pairs of electrodes being disposed to face each other with a distance therebetween, and an elastically deformable dielectric layer arranged between each of the pairs of electrodes. A capacitance measuring part measures capacitance of respective electrode pair groups in a plurality of combinations each comprising more than one of the pairs of electrodes including a selected one of the pairs of electrodes. An external force calculating part calculates the magnitude of external force applied to the position of the selected pair of electrodes based on a plurality of measured values of the capacitance.

Abstract: The present invention relates to a switch with multiple trigger function, which comprises: a touch switch having a button thereon; a first sensor having a sensing zone; and a microcontroller coupled to the touch switch and the first sensor; when the button is pressed by an object, the touch switch is conducted, and the microcontroller executes actions corresponding to the touch switch, thereby driving a controlled device; or when the object enters the sensing zone, the first sensor senses the signal change, and the microcontroller enables the touch switch to be conducted according to the signal change, or generates a signal the same as the signal for conducting the touch switch for executing corresponding actions, thereby driving a controlled device.

Abstract: A non-contact sensor switch assembly includes a switching transistor adapted for switching on/off the supply of a power supply to the control unit of an automatic handwash dispenser, automatic water tap or automatic door, a charge induction plate inducible by an approaching body part of a person, and a capacitive proximity sensor electrically coupled between the charge induction plate and the switching transistor for triggering the switching transistor to switch on the supply of the power supply to the control unit of the automatic handwash dispenser, automatic water tap or automatic door upon approach of a body part of a person.

Abstract: For proximity detection, capacitance of a sensing element to ground is measured as one or more objects move into or out of proximity to the sensing element.

Abstract: A user input for an electronic device includes a haptic feedback layer (100) and a touch sensitive user interface (200). The haptic feedback layer (100) provides a tactile response to a user when the user actuates a user actuation target (301) on the touch sensitive user interface (200) to simulate a popple-style button. The haptic feedback layer (100) includes a chassis (101) and a plurality of oppositely facing, interlaced cantilever beams (105,106) emanating therefrom, further separated by a support beam (113), and spanning at least a portion of the haptic feedback layer (100). One or more piezoelectric actuators (119) are coupled to the cantilever beams and are responsive to a controller (201). When the controller detects user actuation of the touch sensitive user interface (200), the controller (201) causes at least one of the piezoelectric actuators to actuate in accordance with an actuation signal.

Abstract: A circuit for converting a measured variable capacitance to an output voltage signal includes a charge amplifier circuit selectively coupled to an integrator circuit. The charge amplifier circuit, in one implementation, is configured as a high pass filter. In another implementation, the charge amplifier circuit is configured as a combination high pass and low pass filter. The charge amplifier circuit is selectively coupled to the integrator circuit when the circuit forces a switch in voltage across a measurement capacitor.

Abstract: A sensor device has at least one first sensor element for detecting a touch and/or an approach, which is configured as a capacitive sensor element and which has a first electrode structure with a transmitting electrode and a reception electrode, wherein a first alternating electrical field emitted by the transmitting electrode may be coupled into the reception electrode,—at least one second sensor element, and—an evaluating device, which is coupled with the at least one first sensor element and with the at least one second sensor element, wherein the evaluating device is configured to evaluate a first signal tapped from the reception electrode of the first sensor element and at least one second signal provided by the second sensor element and to generate at least one detection signal dependent on the evaluation.

Abstract: This disclosure provides systems, methods, and apparatus related to a capacitive touch sensor with light shielding structures. In one aspect, a device includes an array formed by a plurality of row electrodes and a plurality of non-transparent column electrodes, wherein at least a first portion of the row electrodes is non-transparent and coplanar with the column electrodes and at least a second portion of the row electrodes is non-coplanar with the column electrodes. The device further includes light shielding structures that are non-transparent and coplanar with the column electrodes, wherein the light shielding structures substantially overlap the second portion.

Abstract: A fluid delivery apparatus comprises a spout, a fluid supply conduit supported by the spout, a valve assembly to supply fluid through the fluid supply conduit, and a capacitive touch sensor. The capacitive touch sensor is coupled to a controller. The controller is also coupled to the valve assembly. The controller is configured to detect a user touching the sensor and to control flow of fluid through the fluid supply conduit.

Abstract: In one embodiment, an apparatus includes a touch sensor including drive electrodes. The apparatus also includes sense electrodes arranged along a first axis and a second axis. The first and second axes are substantially perpendicular to each other. The apparatus also includes one or more computer-readable non-transitory storage media coupled to the touch sensor that embody logic that drives all the drive electrodes substantially simultaneously with a common drive signal.

Abstract: In one embodiment, an apparatus includes a first capacitor system and a second capacitor system. Each capacitor system comprises one or more engaged capacitors from respective pluralities of selectively engagable capacitors. The first capacitor system and second capacitor system are respectively selectively coupled to a first reference voltage and a second reference voltage. The apparatus further includes a switch configured to transfer charge between the first capacitor system and the second capacitor system when the switch is closed such that the first capacitor system and the second capacitor system each store the same first voltage. The apparatus further includes a node coupled to the first capacitor system, the second capacitor system, and a first input of a differential amplifier of an analog to digital converter. The node is configured to bias the differential amplifier to the first voltage.

Abstract: A sensor panel comprises a flexible film of a thickness having a first surface and a second surface spaced apart from the first surface by the thickness of the film; an array of micro structures in the flexible film, each micro structure including a chamber formed into the flexible film from the first surface; and an array of sensors on the second surface for generating current induced by static electric charge.

Abstract: The present disclosure relates to structure of a capacitive touch panel and further relates to its manufacturing method. The structure comprises of sensing electrodes and peripheral circuits, wherein each sensing electrode comprises of a plurality of conductive units and a plurality of conductive wires for connecting the conductive units, wherein the conductive wires and peripheral circuits are made of a photosensitive material having an electrically conductive property.

Abstract: Disclosed is a touch panel including an upper conductive layer; a lower conductive layer facing the upper conductive layer with an interval between the upper conductive layer; a capacitive sensing unit that detects a coordinate position by a capacitive coupling under a condition where a predetermined electric potential is applied to the upper conductive layer; and a resistive sensing unit that detects a coordinate position based on an electric potential at a position where the upper conductive layer and the lower conductive layer contact under a condition where a potential gradient is generated on either one of the upper conductive layer and the lower conductive layer.

Abstract: A touch panel includes an insulating substrate, a rectangular transparent conductive layer and a number of electrodes. The insulating substrate has two opposite surfaces. The rectangular transparent conductive layer, fixed on one of the surfaces of the insulating substrate, has two opposite long sides and two opposite short sides. The electrodes are disposed at the short sides of the rectangular transparent conductive layer with a regular interval and electrically connected to the rectangular transparent conductive layer. The rectangular transparent conductive layer further has anisotropic impedance and defines an impedance direction substantially perpendicular to the short sides of the rectangular transparent conductive layer.

Abstract: A touch sensing circuit includes an alternative current (AC) source, a voltage division circuit, and a processing circuit. The voltage division circuit receives an AC signal outputted from the AC source and includes a first branch and a second branch on a touch sensing glass, wherein the first and second branches are adjacent to each other. The processing circuit is connected to the voltage division circuit for determining position of a touch point according to the voltages of the first branch and the second branch. In a preferred embodiment, the first branch comprises a first capacitor and a first voltage division resistor connected to the first capacitor, and the second branch comprises a second capacitor and a second voltage division resistor connected to the second capacitor.

Abstract: A touch panel device includes a touch panel and a controller. The touch panel includes a first region and a second region. The first region includes a plurality of first driving conductors extended along a first direction, and a plurality of first sensing conductors extended along a second direction perpendicular to the first direction. The second region includes a plurality of second driving conductors extended along the first direction, and a plurality of second sensing conductors extended along the second direction. The controller is used for outputting a plurality of driving signals in an ordered sequence of the second direction to drive the plurality of first driving conductors and the plurality of second driving conductors, and for receiving a plurality of sensing signals from the plurality of first sensing conductors and the plurality of second sensing conductors in an ordered sequence of the first direction.

Abstract: The present invention relates to an adhesive composition for a touch panel, to an adhesive film, and to a touch panel. The adhesive composition according to the present invention provides an adhesive for a touch panel that has superior chemical resistance, superior durability under high-temperature or high-humidity conditions, and superior wettability or adhesion to a variety of adherends. In addition, the adhesive composition according to the present invention provides an adhesive which maintains superior resistant performance of a conductive layer and effectively prevents the corrosion of electrodes or the like when applied to a touch panel.

Abstract: A sensor has a strip resonator filter that energizes an emitter patch which emits an electric field out from the strip resonator filter (away from the strip resonator filter). The capacitance of the filter, or specifically the coupling capacitance and radiation pattern of the slotted patch, is altered when an object such as a finger is near the sensor. Resulting changes in a signal outputted by the filter can be used to determine how close the object is to the sensor. The strip resonator filter may be a half wavelength strip resonator coupled filter having three separate strips. The patch may have a slot and two accompanying strips. An arrangement of multiple sensors may detect the position of an object in two or three dimensions.

Abstract: Provided is a touch cell structure for a touch panel in which a touch cell is configured into a new pad to gate mode in order to solve a problem of a conventional capacitive-type touch input device. The touch cell structure includes: a conductive pad that forms an electrostatic capacitance with respect to a touch unit when a finger of a human body or the touch unit having an electrical characteristic similar to the finger approaches the conductive pad within a predetermined distance; and a three-terminal type switching device whose gate terminal is connected with the conductive pad and whose output signal is changed in correspondence to a change in electric potential of the gate terminal of the three-terminal type switching device by the electrostatic capacitance between the touch unit and the conductive pad.

Abstract: A vehicle proximity switch and method are provided having learned sensitivity control. The switch includes a proximity sensor, such as a capacitive sensor, installed in a vehicle and providing a sense activation field. Also included is sense control circuitry processing the activation field to sense user activation of the switch by comparing the activation field to a threshold. The switch further includes sensitivity control circuitry learning a user sensitivity based on user activation of a sensor and controlling the sensitivity of one or more proximity switches.

Abstract: A projected capacitive touch panel with impedance adjustment structure has an X-axis sensing layer and a Y-axis sensing layer. The X-axis sensing layer has multiple X-axis electrode strings. Each X-axis electrode string has multiple X-axis electrodes connected in series. The Y-axis sensing layer has multiple Y-axis electrode strings. Each Y-axis electrode string has multiple Y-axis electrodes in series. The Y-axis electrodes and the X-axis electrode are arranged alternately to form a coupling capacitor between an X-axis electrode and a Y-axis electrode. At least one gap is formed on part of or all the X, Y axis electrodes to reduce the electrode area and the impedance of the electrodes, thereby enhancing the sensing sensitivity and being beneficial to enlarge the size of the touch panel.

Abstract: A sensing floor to locate people and devices is described. In an embodiment, the sensing floor (or sensing surface), is formed from a flexible substrate on which a number of distributed sensing elements and connections between sensing elements are formed in a conductive material. In an example, these elements and connections may be printed onto the flexible substrate. The sensing floor operates in one or more modes in order to detect people in proximity to the floor. In passive mode, the floor detects signals from the environment, such as electric hum, which are coupled into a sensing element when a person stands on the sensing element. In active mode, one sensing element transmits a signal which is detected in another sensing element when a person bridges those two elements. In hybrid mode, the floor switches between passive and active mode, for example, on detection of a person in passive mode.

Abstract: A film type apparatus for providing haptic feedback and a touch screen including the same are provided. In the film type apparatus, a plurality of unit haptic feedback providing apparatuses are arranged in an array. Each of the unit haptic feedback providing apparatuses includes a lower electrode, a lower charge capacitive member disposed on the lower electrode, an upper charge capacitive member disposed apart from the lower charge capacitive member, a spacer disposed between the lower and upper charge capacitive members to separate the lower and upper charge capacitive members, an upper electrode disposed on the upper charge capacitive member, and a charge supply unit connected to the lower and upper electrodes to supply electric charge.

Abstract: Disclosed is a touch window according to the present invention in which a FPCB, an IC, a function key area for a connection with a touch sensing sensor electrode are all formed in a single printed circuit board and are formed not to be exposed to the outside by receiving the printed circuit board in a lower part of a transparent window, thereby being capable of simplifying a structure of the touch window.

Abstract: A membrane touch control panel includes a number of female conductors disposed on the basic layer and each having a number of electrodes electrically connected and coupled together, and each having an opening formed in each electrode, and a number of male conductors having a number of electrodes electrically connected and coupled together and received and engaged in the openings of the female electrodes respectively for forming a number of switch members, the membrane touch control panel includes a structure or configuration to be easily and quickly manufactured with greatly reduced manufacturing cost and procedures.

Abstract: A touch interface device includes a touch surface, an actuator, and an electrode. The actuator is coupled with the touch surface and is configured to move the touch surface in one or more directions. The electrode is coupled with the touch surface and is configured to impart a normal electrostatic force on one or more appendages of a human operator that engage the touch surface when an electric current is conveyed to the electrode. Movement of the touch surface by the actuator and the electrostatic force provided by the electrode are synchronized to control one or more of a magnitude or a direction of a shear force applied to the one or more appendages that engage the touch surface.

Abstract: This disclosure provides systems, methods and apparatus for a projected capacitive touch (PCT) sensor that may include thin sensor electrodes coated with additional layers to form an optical cavity that reinforces a wavelength range or color of incident light. The sensor electrodes and a cover glass border and/or decorations may be fabricated simultaneously. In some implementations, the thickness of the optical cavity will be selected such that the “color” of reflected light is black. The sensor electrodes may not be noticeable to a human observer. However, in some other implementations, the thickness of the optical cavity may be selected such that the sensor electrodes and/or the decorative portions will have another color. Routing wires of the touch sensor may be shielded by a grounded conductive layer in the border.

Abstract: A processing system for a capacitive input device comprises sensor circuitry and control logic. The sensor circuitry is configured to be communicatively coupled with sensor electrodes of the capacitive input device. The control logic is configured to operate the capacitive input device in a first mode comprising interference sensing at a first level and input object sensing. The control logic is also configured to operate the capacitive input device in a second mode instead of in the first mode in response to: interference measured in the first mode meeting an interference condition; and a determination that input is in a sensing region of the capacitive input device. While operating in the second mode, interference sensing with the capacitive input device is either not performed or else is performed at a second level that is lower in fidelity than the first level.