Abstract: A processing system includes transmitter module, receiver module, and a demodulating module. The transmitter module comprises transmitter circuitry and is configured to simultaneously transmit a first transmitter signal with a first transmitter electrode and a second transmitter signal with a second transmitter electrode. The first transmitter signal includes a combination of a first heterodyne frequency and a carrier frequency. The second transmitter signal comprises a combination of a second heterodyne frequency and the carrier frequency. The receiver module comprise receiver circuitry and is configured to receive a first resulting signal with a receiver electrode, wherein the first resulting signal comprises first effects corresponding to the first transmitter signal and second effects corresponding to the second transmitter signal.

Abstract: An input device processing system comprises a sensor module that transmits a first transmitter signal with a transmitter electrode and receives a resulting signal with a receiver electrode. The first transmitter signal comprises a first transmitter frequency, and the resulting signal comprises effects corresponding to the first transmitter signal. A demodulation module demodulates the resulting signal to produce a first signal (e.g., an upper sideband signal) and a second signal (a lower sideband signal), selectably determines a first measurement of a change in capacitive coupling between the transmitter electrode and the receiver electrode based on at least one of the first and second signals, and determines positional information for an input object based on the first measurement.

Abstract: A single integrated circuit for operating both a capacitive proximity sensor device and a resistive pointing stick comprises sensor circuitry to drive a first varying voltage signal onto a transmitter electrode of the capacitive proximity sensor device. The sensor circuitry is also configured to drive a second varying voltage signal onto a voltage divider of the pointing stick and a third varying voltage signal onto the voltage divider of the pointing stick. The sensor circuitry is configured to receive a first resulting signal from a receiver electrode of the proximity sensor device and receive a second resulting signal from the pointing stick. The single integrated circuit includes determining circuitry configured to determine positional information for input received in a sensing region of the proximity sensor device based on the first resulting signal; and to determine force information received as input to the pointing stick based on the second resulting signal.

Abstract: A transcapacitive sensing device has and ohmic seam which sections a plurality of transmitter electrodes and also sections a plurality of receiver electrodes. A processing system is communicatively coupled with the transmitter electrodes and the receiver electrodes and configured to: transmit a first transmitter signal with a first transmitter electrode disposed on a first side of the ohmic seam; transmit a second transmitter signal with a second transmitter electrode disposed on a second side of the ohmic seam; receive a first response corresponding to said first transmitter signal with a first receiver electrode disposed on the first side of the ohmic seam; and receive a second response corresponding to said second transmitter signal with a second receiver electrode disposed on the second side of the ohmic seam.

Abstract: A single integrated circuit for operating both a capacitive proximity sensor device and a resistive pointing stick comprises sensor circuitry to drive a first varying voltage signal onto a transmitter electrode of the capacitive proximity sensor device. The sensor circuitry is also configured to drive a second varying voltage signal onto a voltage divider of the pointing stick and a third varying voltage signal onto the voltage divider of the pointing stick. The sensor circuitry is configured to receive a first resulting signal from a receiver electrode of the proximity sensor device and receive a second resulting signal from the pointing stick. The single integrated circuit includes determining circuitry configured to determine positional information for input received in a sensing region of the proximity sensor device based on the first resulting signal; and to determine force information received as input to the pointing stick based on the second resulting signal.

Abstract: A circuit for measuring a change in capacitive coupling between a transmitter electrode and receiver electrode includes a transmitter module that couples with the transmitter electrode and drives it with a plurality of positive and negative measurement cycles. A latched comparator has an input and an output, where the input couples with the receiver electrode. Upon enablement, the latched comparator determines if receiver electrode voltages satisfy an input threshold of the latched comparator and provides an output signal from an output based on this determination. A first counter is adjusted based on a first output signal of the latched comparator output during a positive measurement cycle. A second counter is adjusted based on a second output signal of the latched comparator during a negative measurement cycle. Measurement of change in capacitive coupling between the transmitter electrode and receiver electrode is based on counter values of the first and second counters.

Abstract: In a circuit for measuring a capacitive charge a drive module is configured for coupling with a sensor electrode of a capacitive input device. The drive module is configured to drive the sensor electrode with a plurality of positive and negative measurement cycles. A latched comparator comprises an input for capturing voltages from the sensor electrode. An output of the latched comparator provides output signals based upon the captured voltages from the sensor electrode. A first counter is set based on a first output signal produced by a first voltage captured by the input during a positive measurement cycle. A second counter is set based on a second output signal produced by a second voltage captured by the input during a negative measurement cycle. A determination module is configured to produce a demodulated output signal based on the first counter value and the second counter value.

Abstract: A circuit for measuring a capacitive charge comprises a latched comparator and a determination module. The latched comparator comprises an input and an output. The input is coupled with a sensor electrode of a capacitive input device. An inverted version of the output is coupled with a feedback loop. The feedback loop is configured to provide feedback to the input to maintain the input at a predetermined voltage. The feedback is provided in clocked charge quanta steps based on a clock signal. The determination module is coupled with the output and configured to determine a change in capacitance on the sensor electrode by equating output signals from the output with an amount of charge provided to the input to reach the predetermined voltage.

Abstract: A capacitive imaging sensor device includes a sensor substrate. A first set of sensor electrodes is disposed on a first surface of the sensor substrate, substantially in parallel with a first axis, and with at least two of its sensor electrodes extending for different lengths along the first axis. A second set of sensor electrodes is disposed on the first surface, substantially in parallel with the first axis, and in a common single layer with the first set. A processing system is coupled with the first and second sets and configured for: measuring a first capacitive coupling between a first sensor electrode of the first set and a sensor electrode of the second set; measuring a second capacitive coupling between a second sensor electrode of the first set and the sensor electrode of the second set; and determining a capacitance image using the first and second measurements of capacitive coupling.

Abstract: A capacitive sensor device and method is configured to respond a stimulus provided in a sensing region with an output signal. A signal generator is configured to apply a carrier signal to the capacitive sensor device. The carrier signal is switched between a plurality of phases at a switching rate, where the switching rate is less than a demodulation filter bandwidth. The result of the carrier phase shifting is that effects of interference in the output signal are frequency shifted away from the effects of user applied stimulus. An interference detection filter is configured to filter from the sensor outputs at least one effect produced by the stimulus. An interference measuring device is configured to determine a level of interference in the at least one interference output. Thus, the system can detect interference in the output of the capacitive sensor device.

Abstract: A processing system includes transmitter module, receiver module, and a demodulating module. The transmitter module comprises transmitter circuitry and is configured to simultaneously transmit a first transmitter signal with a first transmitter electrode and a second transmitter signal with a second transmitter electrode. The first transmitter signal includes a combination of a first heterodyne frequency and a carrier frequency. The second transmitter signal comprises a combination of a second heterodyne frequency and the carrier frequency. The receiver module comprise receiver circuitry and is configured to receive a first resulting signal with a receiver electrode, wherein the first resulting signal comprises first effects corresponding to the first transmitter signal and second effects corresponding to the second transmitter signal.

Abstract: A processing system for a capacitive input device is described. The capacitive input device includes a plurality of sensor electrodes configured to detect input objects in a sensing region. The processing system configured to transmit a signal on a transmitter sensor channel of the capacitive input device. The processing system is also configured to receive the signal on a receiver sensor channel of the capacitive input device, wherein the receiver sensor channel is coupled with an amplifier. The processing system is also configured to determine if a level of interference has been received by the receiver sensor channel in conjunction with receipt of the signal.

Abstract: In a method of determining interference in a capacitance sensor, a signal is transmitted on a transmitter sensor channel of the capacitive sensor. The signal is received on a receiver sensor channel of the capacitive sensor, the receiver sensor channel being coupled with an amplifier. Behavior of the amplifier is examined for non-linearity to determine if a level of interference has been received by the receiver sensor channel in conjunction with receipt of the signal.

Abstract: An input device processing system comprises a sensor module that transmits a first transmitter signal with a transmitter electrode and receives a resulting signal with a receiver electrode. The first transmitter signal comprises a first transmitter frequency, and the resulting signal comprises effects corresponding to the first transmitter signal. A demodulation module demodulates the resulting signal to produce a first signal (e.g., an upper sideband signal) and a second signal (a lower sideband signal), selectably determines a first measurement of a change in capacitive coupling between the transmitter electrode and the receiver electrode based on at least one of the first and second signals, and determines positional information for an input object based on the first measurement.

Abstract: An input device processing system comprises a sensor module that transmits a first transmitter signal with a transmitter electrode and receives a resulting signal with a receiver electrode. The first transmitter signal comprises a first transmitter frequency, and the resulting signal comprises effects corresponding to the first transmitter signal. A demodulation module demodulates the resulting signal to produce a first signal (e.g., an upper sideband signal) and a second signal (a lower sideband signal), selectably determines a first measurement of a change in capacitive coupling between the transmitter electrode and the receiver electrode based on at least one of the first and second signals, and determines positional information for an input object based on the first measurement.

Abstract: Methods, systems and devices are described for detecting a measurable capacitance using sigma-delta charge transfer techniques that can be implemented with many standard microcontrollers, and can share components to reduce device complexity and improve performance. In the various implementations of this embodiment, the passive network used to accumulate charge can be shared between multiple measurable capacitances. A switch or IO controlling the charge sharing and/or charge changing can also be shared Likewise, in various implementations a voltage conditioning circuit configured to provide a variable reference voltage can be shared between multiple measurable capacitances. Finally, in various implementations a guarding electrode configured to guard the measurable capacitances can be shared between multiple measurable capacitances. In each of these cases, sharing components can reduce device complexity and improve performance.

Abstract: A transcapacitive sensing device has and ohmic seam which sections a plurality of transmitter electrodes and also sections a plurality of receiver electrodes. A processing system is communicatively coupled with the transmitter electrodes and the receiver electrodes and configured to: transmit a first transmitter signal with a first transmitter electrode disposed on a first side of the ohmic seam; transmit a second transmitter signal with a second transmitter electrode disposed on a second side of the ohmic seam; receive a first response corresponding to said first transmitter signal with a first receiver electrode disposed on the first side of the ohmic seam; and receive a second response corresponding to said second transmitter signal with a second receiver electrode disposed on the second side of the ohmic seam.

Abstract: Methods, systems and devices are described for detecting a measurable capacitance using sigma-delta measurement techniques. According to various embodiments, a voltage is applied to the measurable capacitance using a first switch. The measurable capacitance is allowed to share charge with a passive network. If the charge on the passive network is past a threshold value, then the charge on the passive network is changed by a known amount for a sufficient number of repetitions until the measurable capacitance can be detected. Such a detection scheme may be readily implemented using conventional components, and can be particularly useful in sensing the position of a finger, stylus or other object with respect to a button, slider, touchpad or other input sensor.

Abstract: Methods and apparatus are provided for measuring a ratio of capacitances.

Abstract: A capacitive imaging sensor device includes a sensor substrate. A first set of sensor electrodes is disposed on a first surface of the sensor substrate, substantially in parallel with a first axis, and with at least two of its sensor electrodes extending for different lengths along the first axis. A second set of sensor electrodes is disposed on the first surface, substantially in parallel with the first axis, and in a common single layer with the first set. A processing system is coupled with the first and second sets and configured for: measuring a first capacitive coupling between a first sensor electrode of the first set and a sensor electrode of the second set; measuring a second capacitive coupling between a second sensor electrode of the first set and the sensor electrode of the second set; and determining a capacitance image using the first and second measurements of capacitive coupling.