Abstract: In a method of performing dilution of a droplet in an EWOD device, a parent droplet is provided on an electrode array of the EWOD device, wherein the parent droplet has a first concentration of a species. A diluent droplet also is provided on the electrode array of the EWOD device. The method includes controlling actuation voltages applied to the electrode array of the EWOD device to join the parent droplet and the diluent droplet into a product droplet having a diluted second concentration of the species different from the first concentration in the parent droplet. The actuation voltages then are controlled to split the product droplet into one or more daughter droplets having the second concentration of the species. A dilution ratio may be calibrated based on the volumes of the droplets. Serial dilution steps may be performed to generate daughter droplets of different species concentrations at each step.

Abstract: In a method of performing dilution of a droplet in an EWOD device, a parent droplet is provided on an electrode array of the EWOD device, wherein the parent droplet has a first concentration of a species. A diluent droplet also is provided on the electrode array of the EWOD device. The method includes controlling actuation voltages applied to the electrode array of the EWOD device to join the parent droplet and the diluent droplet into a product droplet having a diluted second concentration of the species different from the first concentration in the parent droplet. The actuation voltages then are controlled to split the product droplet into one or more daughter droplets having the second concentration of the species. A dilution ratio may be calibrated based on the volumes of the droplets. Serial dilution steps may be performed to generate daughter droplets of different species concentrations at each step.

Abstract: A limb positioning and support device for achieving and maintaining reduction of a human bone in connection with surgical procedures involving orthopedic and other surgical fracture tables. The limb positioning and support device includes an articulating and rotating positioning and support arm coupled between a surgical table and a limb saddle. The positioning and support arm is configured to selectively allow translation and/or rotation of the limb saddle in three degrees of freedom. Actuation mechanisms drive the limb saddle vertically and horizontally. A pivot joint coupled between the limb saddle and the positioning and support arm permits rotation of the limb saddle about a vertical axis, and the limb saddle can be angularly displaced about the longitudinal axis of the subject limb. The limb saddle can be positioned and adjusted to bring fractured bone ends into alignment and hold the fracture stationary during the surgical procedure.

Abstract: A capacitive touch sensor includes an array of electrode elements, each electrode element including a drive electrode and a sense electrode, the drive electrode and the sense electrode forming at least one mutual coupling capacitor in each electrode element. A controller is operatively coupled to the array of electrode elements, the controller configured to measure the at least one mutual coupling capacitance over at least one measurement period. In addition, excitation signals applied during the at least one measurement period are balanced to reduce the effect of baseline capacitance.

Abstract: An EWOD (or AM-EWOD) device includes a reference electrode and a plurality of array elements, each array element including an array element electrode, and control electronics. In a first mode optimized for EWOD actuation, the control electronics is configured to control a supply of time varying voltages to the array element electrodes and the reference electrode, thereby generating an actuation voltage as a potential difference between voltages at the array element electrodes and the reference electrode. The reference electrode includes a first electrical connection and a second electrical connection. In a second mode, the control electronics further is configured to supply an electrical current flow between the first electrical connection and the second electrical connection to generate resistance heat for controlling temperature of the EWOD device. Control may include sensing a temperature of the EWOD device, and switching between operating in the first or second mode based on the sensed temperature.

Abstract: Embodiments are directed towards employing a configuration management system to report one or more assumptions based on whether or not prerequisites for a resource are satisfied. The configuration management system may determine at least one prerequisite that corresponds to a provided resource. The prerequisites may indicate what the resource requires in order to put the system into the target state. If the prerequisites are unsatisfied, then assumptions regarding the system may be determined and reported to a user of the system. The assumptions may include at least a state transition that upon occurrence puts the system into the target state. If the system is in a non-operational mode, such that state actions and state transitions are simulated, rather than being executed, the system may be enabled to perform other actions as if the prerequisites were satisfied and the state transition occurred, even if it is not.

Abstract: Embodiments are directed towards employing a configuration management system to report one or more assumptions based on whether or not prerequisites for a resource are satisfied. The configuration management system may determine at least one prerequisite that corresponds to a provided resource. The prerequisites may indicate what the resource requires in order to put the system into the target state. If the prerequisites are unsatisfied, then assumptions regarding the system may be determined and reported to a user of the system. The assumptions may include at least a state transition that upon occurrence puts the system into the target state. If the system is in a non-operational mode, such that state actions and state transitions are simulated, rather than being executed, the system may be enabled to perform other actions as if the prerequisites were satisfied and the state transition occurred, even if it is not.

Abstract: An active matrix LCD display of the multi-pixel drive (MPD) type, in which a pixel comprises a plurality of sub-pixels with each sub-pixel of a pixel being associated with a respective storage capacitor address lines so that the voltage applied across an individual sub-pixel depends on both the signal voltage and the voltage applied to the associated storage capacitor address line, is driven such that the relationship between at least a first one of the capacitor line voltages and a second one of the capacitor line in a first display refresh period of the frame is different to the relationship between the first of the capacitor line voltages and the second of the capacitor line voltages in a second display refresh period of the frame. This allows the root-mean-square (RMS) voltage applied over the frame across a first of the sub-pixels to be controlled at least partially independently of the RMS voltage applied over the frame across a second of the sub-pixels, thereby providing increased resolution.

Abstract: A mutual capacitance touch panel device includes a substrate, and an array of electrode elements formed on the substrate. Each electrode element includes a drive electrode, a sense electrode and a reference electrode, the reference electrode arranged between the drive electrode and the sense electrode. A first mutual coupling capacitance is formed between the drive electrode and the reference electrode of each electrode element, wherein the drive electrode and reference electrode are configured such that the first mutual coupling capacitance is substantially insensitive to an object touching the surface of the touch panel.

Abstract: A hand-held electronic device includes a display for outputting visual information and a proximity-sensitive touch panel. The display is arranged on a first side of the electronic device, while the proximity-sensitive touch panel is arranged on a second side of the electronic device that is opposite the first side.

Abstract: A reflective pixel for a display device includes a first substrate, a membrane formed relative to the first substrate, and a fluid arranged between the first substrate and the membrane. An actuator mechanism is operative to move the membrane between at least a first and second position that differ in average separation distance relative to the first substrate to produce a low reflective state and a high reflective state of the pixel.

Abstract: A tactile feedback actuator includes a first electrode and a second electrode separated by a gap, and a surface layer above the first and second electrodes. The first electrode receives a first stimulus voltage at a first frequency and the second electrode receives a second stimulus voltage at a second frequency, and the first and second electrodes superimpose the first and second stimulus voltages to generate a total voltage that has a beat frequency less than a perception threshold frequency. An object in contact with a portion of the surface layer is caused to vibrate at the beat frequency. The first electrode and the second electrode may constitute an electrode array including a plurality of column electrode segments, and a plurality of row electrode segments. An object in contact with a portion of the surface layer above one or more electrode segments is caused to vibrate at the beat frequency.

Abstract: Methods and apparatus for ultrasound imaging using ultrasound sensor elements comprising thin film transistors. Specifically, ultrasound elements for use in a two dimensional array of ultrasound elements, two dimensional arrays of ultrasound elements, ultrasound sensor element array assemblies, ultrasound imaging devices and methods of performing an ultrasound scan using a two dimensional array of ultrasound elements. A sensor element comprises: an ultrasound transducer, a transmit circuit configured to provide an electrical signal to the transducer for output of an ultrasound signal; and a receive circuit configured to receive an electrical signal from the transducer, based on a received reflected ultrasound signal, wherein the transmit and receive circuits each comprise one or more thin film transistors.

Abstract: A display comprises independently addressable pixels, a pixel comprising first and second electrodes (12a,12b) disposed on a first substrate and spaced apart from one another. A counter electrode (22) is provided on a second substrate, with an electro-optical material provided between the first substrate and the second substrate. A controller, in use, applies a first voltage to the first electrode of the pixel, a second voltage different to the first voltage to the second electrode of the pixel, and a third voltage to the counter electrode of the pixel to define in the pixel at least one of a first region (18a), a second region (18c) and a third region (18b). The first, second and third voltages are selected such that an area of the first region, second region and third region or each of the first, second region and third region defined in the pixel produces a desired greyscale level for the pixel.

Abstract: A capacitive type touch sensing device includes a first electrode array including a plurality of drive electrodes and a plurality of sense electrodes, and a second electrode array spaced apart from the first electrode array and including a plurality of discrete, electrically floating conductive regions. At least part of the second electrode array positionally overlaps with at least part of the first electrode array to define a separation distance therebetween, the separation distance varying with a force applied to a surface of the touch sensing device. Further, each conductive region is positioned relative to a respective drive electrode and sense electrode of the first electrode array so that a capacitance between certain pairs of drive and sense electrodes is more sensitive to a variation in the separation distance than a capacitance between other pairs of drive and sense electrodes.

Abstract: A capacitive touch panel includes a first substrate and a second substrate arranged relative to the first substrate. A plurality of drive electrodes are arranged on the first substrate, wherein each drive electrode comprises a first drive electrode section and a second drive electrode section. In addition, a plurality of sense electrodes are arranged on the second substrate, the plurality of sense electrodes including touch sensing electrodes and force sensing electrodes. At least part of a sense electrode of the plurality of sense electrodes forms a force sensitive coupling capacitance with a second drive electrode section and not with a first drive electrode section.

Abstract: An image sensor, for example for incorporation within an active matrix display, comprises an array of sensor elements 10. Each sensor element (10) comprise an amplifying transistor (M1) whose gate is connected to an integrating node (11). The integrating node (11) is connected to one plate of an integrating capacitor (C1) and to one electrode of a photodiode (D1), whose other electrode is connected to a resetting line (RST). The sensor element (10) performs a repeating sensing cycle comprising a resetting phase, an integrating phase and a reading phase. During the resetting phase, the resetting line (RST) receives a voltage which forward-biases the photodiode (D1) so as to charge the integrating node (11) to a predetermined voltage. The resetting line (RST) is then returned to a voltage for reverse-biasing the photodiode (D1) so that the integrating and reading phases may be performed.

Abstract: A mutual capacitance touch sensor includes a substrate, and an array of electrode elements formed on the substrate. Each electrode element includes at least one of a first electrode group having at least two drive electrodes and at least one sense electrode, or a second electrode group having at least two sense electrodes and at least one drive electrode. The respective electrodes of the first or second group are arranged to form multiple capacitances over different coupling distances. A controller is operatively coupled to the array of electrode elements, the controller configured to assign an input object as a conductive object when measurements of the multiple capacitances decrease as the input object approaches the touch sensor, and assign the input object as non-conductive object when measurements of at least one of the multiple capacitances increase as the input object approaches the touch sensor.

Abstract: A mutual capacitance touch sensor includes a substrate, and an array of electrode elements formed on the substrate. Each electrode element includes at least one of a first electrode group having at least two drive electrodes and at least one sense electrode, or a second electrode group having at least two sense electrodes and at least one drive electrode. The respective electrodes of the first or second group are arranged to form multiple capacitances over different coupling distances. A controller is operatively coupled to the array of electrode elements, the controller configured to assign an input object as a conductive object when measurements of the multiple capacitances decrease as the input object approaches the touch sensor, and assign the input object as non-conductive object when measurements of at least one of the multiple capacitances increase as the input object approaches the touch sensor.

Abstract: A mutual capacitance touch panel device includes a substrate and an array of electrode elements formed on the substrate, each electrode element including a drive electrode and a pair of dual-function electrodes. In addition, the pair of dual-function electrodes of each electrode element are arranged substantially symmetrically around the drive electrode of the respective electrode element such that a first dual-function electrode of the pair is adjacent to the drive electrode and the second dual function electrode of the pair is separated from the drive electrode by the first dual-function electrode.