A non-overlapping clock generator generating an in-phase output clock signal and a reversed-phase output clock signal which are non-overlapped with each other, includes: a first and a second XOR gates, a first and a second load transistors, which are cross coupled, and includes: a first and a second delay circuits. The first delay circuit is coupled between the in-phase output clock signal and a control terminal of the first load transistor. The second delay circuit is coupled between the reversed-phase output clock signal and a control terminal of the second load transistor. Each of the XOR gates includes at least one pass transistor logic circuit configured to execute XOR logic operation and coupled to a first control voltage. A non-overlapping period is determined according to the first control voltage and/or a first delay period of the first delay circuit and a second delay period of the second delay circuit.

Sub-threshold current reduction circuit (SCRC) switches and related apparatuses and methods are disclosed. An apparatus includes a first set of SCRC switches and a second set of SCRC switches electrically connected between power supply lines and power reception lines. The first set of SCRC switches is configured to electrically connect the power supply lines to the power reception lines in the first operational mode and the second operational mode. The second set of SCRC switches is configured to electrically connect the power supply lines to the power reception lines in the first operational mode and electrically isolate the power supply lines from the power reception lines in the second operational mode. Activation of the first set of SCRC switches is staggered in time with activation of the second set of SCRC switches. The second set of SCRC switches is spaced among the first set of SCRC switches.

A phase interpolator is provided. The phase interpolator includes a plurality of first interpolation cells each configured to supply a first current to a common node of the phase interpolator. Further, the phase interpolator includes a plurality of second interpolation cells each configured to supply a second current to the common node. The second current is lower than the first current, wherein a sum of the plurality of second currents supplied to the common node by the plurality of second interpolation cells is substantially equal to the first current.

The disclosure relates to technology for generating multi-phase signals. An apparatus includes 2{circumflex over ()}n phase signal generation stages. The apparatus also includes a controller configured to provide a mode input of each of the 2{circumflex over ()}n stages with an active periodic binary signal with remaining inputs of each of the 2{circumflex over ()}n stages provided with another periodic binary signal to collectively generate a 2{circumflex over ()}n phase signal in a first mode. The controller is further configured to provide the mode input of each of 2{circumflex over ()}(n1) odd stages with a first steady state signal and the mode input of each of 2{circumflex over ()}(n1) even stages with a second steady state signal with remaining inputs of each of the 2{circumflex over ()}n stages provided with the same periodic binary signal as in the first mode to cause either the 2{circumflex over ()}(n1) odd stages or the 2{circumflex over ()}(n1) even stages to collectively generate a 2{circumflex over ()}(n1) phase signal in a second mode.

A sensor system includes a pixel array, a DC/DC converter, and a photodiode stack. The pixel array is configured to operate in an image capturing mode or an energy harvesting mode. The DC/DC converter is configured to convert energy captured by the pixel array while in energy harvesting mode. The photodiode stack is located adjacent to the pixel array and configured to provide power to the DC/DC converter.

An interleaved ring oscillator includes a first ring oscillator having n stages, and a second ring oscillator having n stages, wherein each stage includes a n.sup.th first gated inverter in the first ring oscillator and a n.sup.th second gated inverter in the second ring oscillator, such that output from the n.sup.th first gated inverter enables the n.sup.th second gated inverter, and output from the n.sup.th second gated inverter enables the n.sup.th first gated inverter.

The disclosure relates to technology for generating multi-phase signals. An apparatus includes 2{circumflex over ()}n phase signal generation stages. The apparatus also includes a controller configured to provide a mode input of each of the 2{circumflex over ()}n stages with an active periodic binary signal with remaining inputs of each of the 2{circumflex over ()}n stages provided with another periodic binary signal to collectively generate a 2{circumflex over ()}n phase signal in a first mode. The controller is further configured to provide the mode input of each of 2{circumflex over ()}(n1) odd stages with a first steady state signal and the mode input of each of 2{circumflex over ()}(n1) even stages with a second steady state signal with remaining inputs of each of the 2{circumflex over ()}n stages provided with the same periodic binary signal as in the first mode to cause either the 2{circumflex over ()}(n1) odd stages or the 2{circumflex over ()}(n1) even stages to collectively generate a 2{circumflex over ()}(n1) phase signal in a second mode.

Various embodiments of the present technology may comprise methods and apparatus for an amplifier circuit. Methods and apparatus for an amplifier circuit according to various aspects of the present invention may provide a first cross-connect circuit responsive to a first clock signal having a first phase and the third clock signal having a third phase. The amplifier circuit may provide a second cross-connect circuit responsive to a second clock signal having a second phase and a fourth clock signal having a fourth phase. The clock signals have a same frequency with offset phases.

An oscillator includes an oscillator circuit and a voltage circuit. The oscillator circuit includes a first transistor. The voltage circuit is configured to, in a small signal mode, provide a voltage swing at a source of the first transistor, a gate-to-source voltage of the first transistor being associated with whether the oscillator is able to generate an oscillator signal.

A signal generation circuit generates first and second non-overlapping digital signals from an input pulse signal. A first digital circuit includes: a first logical OR gate receiving the second digital signal and the input pulse signal to generate a third digital signal; and a second logical OR gate receiving the input pulse signal and a delayed version of the third digital signal to generate the first digital signal. A second digital circuit includes: a first logical AND gate receiving the first digital signal and the input pulse signal to generate a fourth digital signal; and a second logical AND gate receiving the input pulse signal and the fourth digital signal to generate the second digital signal.