Abstract: A transmission system comprising: an output-terminal configured to provide an output-signal; a phase-shift oscillator comprising a plurality of phase-shifters, each configured to provide one of a plurality of phase-shifted-signals; and a controller configured to provide a selected one of the phase-shifted-signals to the output-signal as a transition in the output-signal, at an instant in time that is based on one or more of the plurality of phase-shifted-signals.

Abstract: An integrated circuit includes a load circuit having multiple functional modules, a first voltage regulator configured to provide a supply voltage to the multiple functional modules, and a supply current monitoring circuit including a second voltage regulator and a current monitor, the second voltage regulator being configured to provide a test supply voltage. A switch matrix is interconnected between the first voltage regulator, the supply current monitoring circuit, and the functional modules. Each of the functional modules in successive order is a module under test, and the switch matrix is configured to disconnect the first voltage regulator from the module under test and connect the supply current monitoring circuit to the module under test such that the second voltage regulator provides the test supply voltage to the module under test and the current monitor measures a supply current of the module under test in response to the test supply voltage.

Abstract: A transmission system comprising: an output-terminal configured to provide an output-signal; a phase-shift oscillator comprising a plurality of phase-shifters, each configured to provide one of a plurality of phase-shifted-signals; and a controller configured to provide a selected one of the phase-shifted-signals to the output-signal as a transition in the output-signal, at an instant in time that is based on one or more of the plurality of phase-shifted-signals.

Abstract: A piezoresistive MEMS oscillator uses an output circuit to control the voltage across the resonator body. This results in a DC bias of the resonator. A current path is provided between the output of the output circuit and the resonator body, such that changes in current through or voltage across the resonator body, resulting from changes in resistance of the resonator body, are coupled to the output. This arrangement uses the bias current flowing through the resonator to derive the output. In this way, the same DC current is used to provide the required DC resonator bias and to drive the output circuit to its DC operating point.

Abstract: A piezoresistive MEMS oscillator comprises a resonator body, first and second drive electrodes located adjacent the resonator body for providing an actuation signal; and at least a first sense electrode connected to a respective anchor point. The voltages at the electrodes are controlled and/or processed such that the feedthrough AC current from one drive electrode to the sense electrode is at least partially offset by the feedthrough AC current from the other drive electrode to the sense electrode.

Abstract: A piezoresistive MEMS oscillator uses an output circuit to control the voltage across the resonator body. This results in a DC bias of the resonator. A current path is provided between the output of the output circuit and the resonator body such that changes in current through or voltage across the resonator body, resulting from changes in resistance of the resonator body, are coupled to the output. This arrangement uses the bias current flowing through the resonator to derive the output. In this way, the same DC current is used to provide the required DC resonator bias and to drive the output circuit to its DC operating point. The benefit of this arrangement is a reduced power-consumption. In addition, when using an arrangement where a virtual-earth for the resonator to amplifier connection is employed, a reduced sensitivity for bond pad capacitances and other stray capacitances is obtained.

Abstract: A piezoresistive MEMS oscillator comprises a resonator body, first and second drive electrodes located adjacent the resonator body for providing an actuation signal; and at least a first sense electrode connected to a respective anchor point. The voltages at the electrodes are controlled and/or processed such that the feedthrough AC current from one drive electrode to the sense electrode is at least partially offset by the feedthrough AC current from the other drive electrode to the sense electrode.

Abstract: A balanced transformer-less amplifier includes a system for detecting and correcting DC offset across the output terminals of the amplifier. The output signal is digitized, counted during a predetermined period, and the result of the counting is used to derive a DC correction signal which is fed back to the input of the amplifier.

Abstract: A balanced transformer-less amplifier comprising a system for detecting and correcting DC offset across the output terminals of the amplifier. The output signal is digitized, preferably in a sigma delta modulator, the digitized signal is counted during a predetermined period and the result of the counting is used to derive a DC correction signal which is fed back to the input of the amplifier.