Abstract: Methods, devices and algorithms for the linearization of nonlinear time variant systems and the synchronization of a plurality of such systems. One embodiment includes a transmit path, including the power amplifier, as used in wireless transmit systems. Advances made in CMOS technology, digital to analog converter (DAC) technology make it possible to implement a substantial part of such a system in the digital domain. Additional embodiments include the integration of a substantial part of such a transmit system in a single integrated circuit (IC). A digital implementation allows for linearization of a broad range of nonlinear and time variant effects. Another aspects is the reuse of methods, devices, components and algorithms used for the linearization of a transmit system to synchronize and time align multiple transmit systems.

Abstract: Converter circuits and methods herein describe mechanisms for converting a digital input signal to an analog output signal using a series of transmission lines. The circuits and methods described herein convert to analog signal using very little power, due to inter-coupling of wave propagation media.

Abstract: Converter circuits and methods herein describe mechanisms for converting a digital input signal to an analog output signal using a series of transmission lines. The circuits and methods described herein convert to analog signal using very little power, due to inter-coupling of wave propagation media.

Abstract: Methods and devices for power conversion. High frequency electromagnetic waves traveling in coupled transmission lines and their reflective properties are used to perform the power conversion. The use of high frequency operation allows for physically small transmission lines. The high operating frequencies also allow for small filter capacitors at the outputs of the power converter and hence allowing for fast response times in load changes or fast signal changes in case of a gate driver. The transmission lines can be implemented on the printed circuit board, laminate or even on chip. In case of a step up converter the switching elements are not subjected to the higher output voltage levels of the power converter and can therefore be implemented in a lower voltage process technology. Further, embodiments with and without galvanic isolation are described and physical embodiments to reduce undesired electromagnetic emissions are disclosed.

Abstract: Methods and devices for an energy efficient digital to analog conversion are disclosed. With the achievable sampling rates and output voltage levels, high power RF signals can be synthesized. A plurality of pulses are generated and coupled onto transmission lines. On the other end of the transmission line the pulses are either reflected or transmitted to a load line depending on the status of a termination element. In one embodiment the reflected pulses are collected and sent to a load. The energy in the transmitted pulses can be recovered and reused. In another embodiment the transmitted pulses are collected and transmitted to a load and the energy in the reflected pulses is recovered and reused.

Abstract: Methods and devices for an energy efficient digital to analog conversion are disclosed. With the achievable sampling rates and output voltage levels, high power RF signals can be synthesized. A plurality of pulses are generated and coupled onto transmission lines. On the other end of the transmission line the pulses are either reflected or transmitted to a load line depending on the status of a termination element. In one embodiment the reflected pulses are collected and sent to a load. The energy in the transmitted pulses can be recovered and reused. In another embodiment the transmitted pulses are collected and transmitted to a load and the energy in the reflected pulses is recovered and reused.

Abstract: Methods and devices for the generation of high frequency clock signals. In a transmission line a signal is reflected back and forward. The electric length of the transmission line determines the frequency of the oscillation. A start signal at the switching device initiates a signals traveling down the transmission line. At the other end of the transmission line the signals is reflected back. At the tapping point along the transmission line, part of the energy of the signal in the transmission line is coupled out to form the feedback signal. The feedback signal activates the switching device. The switching device injects energy into the transmission line and sustains the oscillation on the transmission line. The position of the tapping point on transmission line determines the shape of the feedback signals and can hence be used as a design parameter optimize the performance of the system.

Abstract: Methods and devices for the calibration of digital to analog converters (DAC) and analog to digital converters (ADC) are disclosed. In a first step the DAC is calibrated and in a second step the calibrated DAC is used to calibrate the ADC. Averaging techniques and/or equation based techniques are used to further improve the calibration of both components in an iterative process. Embodiments of the invention allow for a very compact physical implementations of the converter. The invention reduces of analog circuitry in favor of digital circuits. Embodiments of the invention are suitable for the implementation in fine line CMOS processes and can operate in a low supply voltage environment.