A programmable device comprises one or more programming regions, each comprising a plurality of configurable logic blocks, where each of the plurality of configurable logic blocks is selectively connectable to any other configurable logic block via a programmable interconnect fabric. The programmable device further comprises configuration logic configured to, in response to an instruction in an instruction stream, reconfigure hardware in one or more of the configurable logic blocks in a programming region independently from any of the other programming regions.

There is provided a reconfigurable semiconductor device including a plurality of circuit blocks each including a reconfigurable logic unit, and an analog circuit configured to convert an analog signal from the outside into a digital signal to output the digital signal to the reconfigurable logic unit, and convert a digital signal outputted from the reconfigurable logic unit into an analog signal to output the analog signal to the outside. The circuit block has a rectangular shape, is connected to the two adjacent circuit blocks from one side with a plurality of analog lines, and is connected to the other two adjacent circuit blocks from the other side on a side opposite to the one side with a plurality of analog lines.

It is an object to provide a semiconductor device in which power consumption can be reduced. It is another object to provide a highly reliable semiconductor device using a programming cell, such as a programmable logic device (PLD). In accordance with a change in a configuration of connections between basic blocks, power supply voltage furnishing to the basic blocks is changed. That is, when the structure of connections between the basic blocks is such that a basic block does not contribute to a circuit, the supply of the power supply voltage to this basic block is stopped. Further, the supply of the power supply voltage to the basic blocks is controlled using a programming cell formed using a field effect transistor whose channel formation region is formed using an oxide semiconductor, the field effect transistor having extremely low off-state current or extremely low leakage current.

Methods and apparatus permit body biasing to be controlled for transistors of a logic device. By controlling the body biasing, transistor threshold voltages can be controlledincreased during standby modes of the logic device to reduce leakage current and decreased during active modes and to increase switching speed during the active modes. The change in the body biasing can be made relatively slowly to reduce wasted energy that would otherwise be dissipated as heat. In a method embodiment, the method includes obtaining first and second body bias slope parameters, each slope parameter defining, at least in part, a slope of a body bias voltage signal. The method includes charging a body of a transistor with a bias voltage signal per the first body bias slope parameter to lower a threshold voltage, and discharging the body per the second body bias slope parameter to decrease leakage current of the transistor.

Provided herein may be an interface device and a method of operating the same. The interface device may include a first port configured to enable communication with a host, a second port configured to enable communication with the host, and a function manager including a plurality of variable functions that are selectively assignable to at least one of the first port and the second port.

A control circuit including a quadrature encoder circuit, a counter circuit, and a cutoff circuit is provided. The quadrature encoder circuit generates a first edge signal and a first direction signal according to a first external signal and a second external signal. The counter circuit performs a counting operation according to the first edge signal and the first direction signal. In response to the timer signal being enabled, the cutoff circuit prevents the first edge signal and the first direction signal from entering the counter circuit and provides a second edge signal and a second direction signal to the counter circuit so that the counter circuit performs the counting operation according to the second edge signal and the second direction signal.