Described herein are systems and methods that provide for asymmetric image splitter image stream applications. In one embodiment, a system supporting image multi-streaming comprises an asymmetric image splitter engine that splits super-frame image streams into two or more image streams and a fractional clock divider circuit. The fractional clock divider may comprise a digital feedback control loop and a one-bit sigma delta modulator. The fractional clock divider circuit may provide compatible display clock frequencies for each of the two or more image streams. When a multi-image stream comprises the two image streams, the asymmetric image splitter engine adjusts a vertical asymmetry of a first image stream with a shortest height to same height as a second image stream by adding vertical padding to the first image stream. The super-frame image streams may comprise image streams from video, LIDAR, radar, or other sensors.

Examples relate to a digitally controlled oscillator circuit arrangement, a digitally controlled oscillation means, a method for a digitally controlled oscillator, a digital loop filter circuit arrangement, a digital loop filtering means, a method for a digital loop filter, a phase locked loop circuit arrangement and phase locked loop, a user device and a base station. The digitally controlled oscillator circuit arrangement comprises input circuitry for obtaining a frequency setting signal, the frequency setting signal comprising a plurality of signal components, selection circuitry for selecting one signal component of the plurality of signal components of the frequency setting signal based on an oscillation signal of the digitally controlled oscillator circuit arrangement, wherein the selection circuitry comprises counting circuitry and multiplexing circuitry, signal generation circuitry for generating the oscillation signal based on the selected signal component of the frequency setting signal, and output circuitry for providing the oscillation signal.

A plasma generation system includes a reference clock, a plurality of solid state generator modules, and a processing chamber. The reference clock is configured to generate a reference signal. Each solid state generator module is linked to an electronic switch and each electronic switch is linked to the reference clock. The solid state generator modules are each configured to generate an output based on the reference signal from the reference clock. The processing chamber is configured to receive the output of at least two of the solid state generator modules to combine the outputs of said solid state generator modules therein.

An oscillator includes a tunable resonant circuit having an inductance and a variable capacitance coupled between first and second nodes, and a set of capacitances selectively coupleable between the first and second nodes. An input control node receiving an input control signal is coupled to the variable capacitance and set of capacitances. The tunable resonant circuit is tunable based on the input control signal. A biasing circuit biases the tunable resonant circuit to generate a variable-frequency output signal between the first and second nodes. A voltage divider generates a set of different voltage thresholds, and a set of comparator circuits with hysteresis compares the input control signal to the set of different voltage thresholds to generate a set of control signals. The capacitances in the set of capacitances are selectively coupleable between the first and second nodes as a function of control signals in the set of control signals.

An oscillator includes a tunable resonant circuit having an inductance and a variable capacitance coupled between first and second nodes, and a set of capacitances selectively coupleable between the first and second nodes. An input control node receiving an input control signal is coupled to the variable capacitance and set of capacitances. The tunable resonant circuit is tunable based on the input control signal. A biasing circuit biases the tunable resonant circuit to generate a variable-frequency output signal between the first and second nodes. A voltage divider generates a set of different voltage thresholds, and a set of comparator circuits with hysteresis compares the input control signal to the set of different voltage thresholds to generate a set of control signals. The capacitances in the set of capacitances are selectively coupleable between the first and second nodes as a function of control signals in the set of control signals.

Disclosed herein is a tunable resonant circuit including an inductance directly electrically connected in series between first and second nodes, a variable capacitance directly electrically connected between the first and second nodes, and a set of switched capacitances coupled between the first and second nodes. The set of switched capacitances includes a plurality of capacitance units, each capacitance unit comprising a first capacitance for that capacitance unit directly electrically connected between the first node and a switch and a second capacitance for the capacitance unit directly electrically connected between the switch and the second node. Control circuitry is configured to receive an input control signal and connected to control the switches of the set of switched capacitances. A biasing circuit is directly electrically connected to the tunable resonance circuit at the first and second nodes.

Disclosed herein is a tunable resonant circuit including an inductance directly electrically connected in series between first and second nodes, a variable capacitance directly electrically connected between the first and second nodes, and a set of switched capacitances coupled between the first and second nodes. The set of switched capacitances includes a plurality of capacitance units, each capacitance unit comprising a first capacitance for that capacitance unit directly electrically connected between the first node and a switch and a second capacitance for the capacitance unit directly electrically connected between the switch and the second node. Control circuitry is configured to receive an input control signal and connected to control the switches of the set of switched capacitances. A biasing circuit is directly electrically connected to the tunable resonance circuit at the first and second nodes.

A variable frequency divider arrangement is arranged to divide a frequency of an incoming signal by a variable number D to provide a resultant signal. The arrangement comprises: a first counter having a first clock input and a first output undergoing a single cycle for P cycles of said first clock if a first control input is in a first state or undergoing a single cycle for P+1 cycles of said first clock if said first control input is in a second state; a second counter in series with said first counter 108 and having a second clock input and a second output undergoing a single cycle for every N cycles of said second clock, wherein N is an integer predetermined by a second control input; and a controller arranged to determine said first and second control inputs.

A variable frequency divider arrangement is arranged to divide a frequency of an incoming signal by a variable number D to provide a resultant signal. The arrangement comprises: a first counter having a first clock input and a first output undergoing a single cycle for P cycles of said first clock if a first control input is in a first state or undergoing a single cycle for P+1 cycles of said first clock if said first control input is in a second state; a second counter in series with said first counter 108 and having a second clock input and a second output undergoing a single cycle for every N cycles of said second clock, wherein N is an integer predetermined by a second control input; and a controller arranged to determine said first and second control inputs.

Performance indicator circuitry is provided for characterizing performance of a phase locked loop (PLL) in a phase path of a polar modulator or polar transmitter that is used to generate a phase modulated RF signal. The PLL includes an oscillator, a high pass path, and a low pass path. The low pass path includes a loop filter. The performance indicator circuitry includes first input circuitry and parameter calculation circuitry. The first input circuitry is configured to input a loop filter signal from the loop filter. The parameter calculation circuitry is configured to compute a value for a performance indicator based on the loop filter signal and control or characterize an aspect of operation of the PLL based on the value.