Abstract: A touch sensing device comprising a plurality of individually operable touch sensing elements having first and second overlapping and spaced conductive layers (12, 15) with the second conductive layer being displaceable towards the first conductive layer in response to a touch input. The device is fabricated by forming on a support a thin film multi-layer structure comprising the first and second conductive layers with an insulating layer (16) therebetween and in which the second conductive layer is provided with apertures at predetermined regions, and subjecting the structure to an etching process which removes insulating material between the conductive layers at the apertured regions via the apertures to form gaps (19). This leaves the second conductive layer (15) at each region supported in spaced relationship to the first conductive layer by the insulating layer around the periphery of the region.

Abstract: Signatures from MPEG or Motion JPEG encoded video clips are extracted based on the luminance, chrominance, and motion vector values. The signatures are stored in a database, along with corresponding location, size, and time length information. The signature of a query video clip, also encoded in the MPEG or Motion JPEG format, is extracted. The signature of the query video clip is compared with the signatures stored in the meta database, with video clips having signatures similar to the signature of the query video clip identified. The video clips are then retrieved and displayed by selection of a user.

Abstract: A circuit arrangement for operating a discharge lamp. Input terminals are coupled to the poles of a supply voltage source which delivers a low frequency supply voltage. A rectifier is coupled to the input terminals for rectifying the low frequency supply voltage. A branch interconnects output terminals of the rectifier and includes a series arrangement of a first diode, a second diode, and a third diode. The first and second diodes are shunted by a first capacitor. The second and third diodes are shunted by a second capacitor. A resistor passes current during lamp operation with which the first and second capacitors are charged. Lamp current is generated based on the voltages across the first and second capacitors. The resistor is placed in a branch which passes a low frequency alternating current during lamp operation and which connects an input terminal to an input of the rectifier. The circuit arrangement has a high power factor.

Abstract: A drive circuit for supplying drive signals to a plurality of windings of a multi-phase d.c. motor. The drive circuit comprises a multi-phase inverter which supplies the drive signals to the motor windings; a phase detector which samples the back-emf signal of a winding in order to obtain a phase-error signal; a low-pass filter which generates a control signal dependent upon the phase-error signal; and a controllable oscillator which generates a frequency signal whose phase and frequency depend on the control signal. The timing with which the multi-phase inverter supplies the drive signals to the windings is dependent on the frequency signal. The drive circuit further comprises a masking circuit for temporarily inhibiting the further processing of the phase-error signal by the low-pass filter, at least during the presence of a flyback signal in the phase-error signal, as a result of which the processing of the flyback pulses present in the phase-error signal is inhibited.

Abstract: A display apparatus includes the switching unit for switching between an operating mode and a standby mode. The apparatus generates a picture on a display screen in the standby mode. The apparatus includes, for example a microphone for measuring a sound volume in the vicinity of the apparatus. The microphone is coupled to the picture-generating unit in order to change the picture in the standby mode in response to a change of the measured sound volume.

Abstract: A data processing apparatus comprises apparatus arranged to model a number of modules (302,314) with each module containing a number of interconnected behaviours (320-325). A behaviour identified as a marker (304) is able to access a behaviour (321) within another module via an identify link (306) and from information denoting that behaviour within a look-up table (312) held in a further behaviour (310). Having established access, a direct identify link (316) can be set up between the selected behaviour (321) and a nominated behaviour (318) within the module containing the marker. This direct identify link is maintained when the identify link between the marker and the further behaviour is terminated, allowing the marker to go on and establish other direct links (330) to the internal behaviours of other modules (336).

Abstract: In a self-oscillating power-supply circuit for charging a battery, a switching transistor (T2) is turned off if the voltage across a sensing resistor (R3) exceeds the threshold voltage of a zener diode (D5). The zener diode is arranged in parallel with the series arrangement of the base-emitter junction of the switching transistor and the sensing resistor, so that the voltage of the battery does not influence the peak current at which the switching transistor is turned off. A diode (D6) is arranged in series with the zener diode and can be short-circuited by means of a switch (T3) in order to switch the power-supply circuit from slow charging to rapid charging. A voltage sensor (R8, R9, T4) monitors the battery voltage and eliminates the short-circuit of the diode (D6) when a given battery voltage is reached so that the power-supply circuit changes over to slow charging.

Abstract: A circuit arrangement for igniting and supplying a discharge lamp by means of a substantially square-wave voltage at a frequency f1. It is possible to dim the lamp by adjusting the frequency of the substantially square-wave voltage to a value f2 which is different from f1. A protection circuit prevents damage to the lamp and to the circuit arrangement if the lamp current does not flow any more at the frequency f2.

Abstract: In a self-oscillating power-supply circuit for charging a battery, the main switching transistor is turned off by a second switching transistor (T2) of an opposite conductivity type, which is arranged in series with the main switching transistor (T1) via a sensing resistor (R8). This configuration allows rapid switching of the main switching transistor (T1). The power-supply circuit can be turned on and off in a simple manner (R7, T4). Moreover, it is simple to provide a compensation (R4) for varying mains voltages, an auxiliary voltage (D6, C4) for powering additional circuits (R9, R10), which auxiliary voltage also remains available when the power-supply circuit is turned off.

Abstract: An electrical heating apparatus, for example, a fan heater, comprises at least an electrical heating element (14) and a motor (14) for driving a fan. The apparatus also comprises a switch device arranged to provide the apparatus with two operating modes. In the first mode the heating element and the motor are connected in parallel, and in the second mode the heating element and the motor are connected in series. The first mode provides a relatively high heat output and/or high airflow to distribute the heat quickly. The second mode provides quieter operation at a similar or lower output power level, for example, to maintain a given temperature while causing less disturbance to people in the vicinity of the fan heater. A further heating element may be arranged in parallel with the motor in the second mode of operation so as to provide a potential divider for supplying the motor.

Abstract: A reference voltage source comprises a first current branch (16, 36) and a second current branch (30, 34, 12). The voltage on a first terminal (6) in the first current branch (16, 26) is one junction voltage higher than the voltage on a second terminal (8) in the second current branch (30, 34, 12) owing to the presence of a transistor (80). The ratio between the current I.sub.1 through the first current branch (16, 36) and the current I.sub.2 through the second current branch (30, 34, 12) is thus determined by two non-linear characteristics having opposite temperature coefficients. A reference voltage (v.sub.z) with a small temperature coefficient and with a value which can be chosen freely can be generated by an appropriate choice of the resistance values for the resistors (58, 30, 16, 12) and by scaling the emitter areas of the transistors (34, 36, 70, 80).

Abstract: A recording and/or reproducing apparatus (1) which accepts two different sizes of magnetic-tape cassettes (15, 16) each having two juxtaposed reels (21, 22, 23, 24) comprises four drive devices (25, 26, 27, 28) mounted stationarily in the apparatus and each comprising a reel spindle (31, 32, 39, 40) and a reel disc (33, 34, 41, 42). Both the reel spindles (31, 32, 39, 40) and the reel discs (33, 34, 41, 42) are axially movable and, when a magnetic-tape cassette (15, 16) is loaded into the apparatus (1) in its operating position, the reel spindles (39, 40, 31, 32) and the reel discs (41, 42, 33, 34) which are not adapted to enter into driving engagement with the inserted magnetic-tape cassette (15, 16) are moved into an area situated outside the area occupied by the inserted magnetic-tape cassette (15, 16).

Abstract: A current mirror arrangement comprising at least one input transistor of a first conductivity type, whose emitter is connected to a current supply line and whose collector is arranged to carry an input current. At least one output transistor of the first conductivity type has its emitter connected to the current supply line and its base to the base of the input transistor and from whose collector an output current can be taken. A follower transistor of the first conductivity type has its emitter connected to the bases of the input transistor and the output transistor and its base to the collector of the input transistor, and has its collector coupled to a reference potential. In order to ensure a well-defined load of the current supply line in any operating condition, the current mirror arrangement also includes a control transistor of a second conductivity type opposite to the first conductivity type.

Abstract: Apparatus for recharging a battery, comprising a compartment which holds the battery so that its electrical terminals are in contact with a pair of electrodes. The electrodes are connectable to the poles of a controllable source of electrical energy. In the compartment a ferromagnetic body is positioned so as to be subjected to mechanical stress in response to mechanical deformation of the battery. An electrical device monitors the magnetic permeability .mu. of the ferromagnetic body by measuring the self-inductance of a coil surrounding at least a portion of the ferromagnetic body. The .mu. of the ferromagnetic body changes by magnetostrictive effects arising from mechanical stress of the ferromagnetic body in response to mechanical deformation of the battery (5) during charging. Expansion of the battery can be used as an indicator that charging has been completed, and that the battery should be disconnected from the source of electrical energy.

Abstract: A transconductance amplifier having a digitally variable transconductance includes a differential stage having a first differential output coupled to an output terminal via a first current mirror and a second differential output coupled to the output terminal via a second and third current mirror. The first and third current mirrors have multiple output branches for selectively supplying output currents to the output terminal in response to a binary transconductance control signal. In this way a digital control of the variable transconductance is realised, which can be used advantageously in a variable gain stage and in an automatic gain control circuit including such a variable gain stage.

Abstract: A current memory for balanced current inputs comprises two coarse and two fine current memory cells each of which comprises a field effect transistor having a switch between its gate and source electrodes. Parasitic gate-drain capacitances are neutralised by capacitors connected between the gate and drain electrodes of opposite pairs of transistors. Other current transport errors can be compensated by providing appropriately dimensioned extra capacitance added to each of the neutralising capacitors.

Abstract: System for processing digital images includes a system of n fixed real cameras whose individual fields of view merge for recording a panoramic scene. An image construction system simulates a mobile, virtual camera continuously scanning the panoramic scene (Iv) to furnish an arbitrary sub-image, referred to as a digital target image (Iv) constructed from adjacent source images of the real cameras. A luminance equalizing system includes modules which apply correction laws (Gi, Gj), respectively, to the sets (R and F(R)) of the corresponding luminance levels, in portions (Ivi, Ivj) of a digital target image (Iv) constructed from two adjacent digital source images (Ii, Ij) to equalize these corresponding levels in accordance with the relation Gi(R)=Gj[F(R)].

Abstract: A simple circuit arrangement for amplifying the effect of a capacitance. The input of the circuit arrangement is connected to an output of a current mirror circuit and, via the capacitance, to an input of the current mirror circuit to which a constant current (I) of known magnitude is applied. The degree of amplification of the effect of the capacitance is dependent on the area ratio n between the input transistor and the output transistor of the current mirror circuit. A constant current (n.multidot.I) is applied to the output of the current mirror circuit and is equal to the current applied to the input of the current mirror circuit multiplied by the area ratio n.

Abstract: A control system for controlling consumer apparatus. In the system, a command item is generated in one apparatus and supplied to another apparatus via a bus. The command item includes an operation code followed by zero or more operand codes for, in an addressee apparatus, addressing a command table. The latter thereupon outputs appropriate information for the addressee apparatus, without the addressor apparatus needing to specify the latter information.

Abstract: A circuit arrangement having an input arranged to receive an input signal (U20) and an output for providing an output signal (U22). The circuit has an overall transfer function defined as the ratio between the output signal and the input signal and which is obtained by adding individual transfer functions of at least two different amplifiers with different slopes in their linear ranges and/or different limit values in their saturation ranges and/or different zero points alternately with positive and negative signs in a manner such that, at least partly, it corresponds substantially to a function of at least the third degree. This circuit arrangement generates, in a simple manner, an overall transfer function of at least the third degree, which can be used advantageously, for example, for the compensation of the temperature-verses-resonant-frequency characteristic function of a quartz crystal.