An integrated circuit device having insulated gate field effect transistors (IGFETs) having a plurality of horizontally disposed channels that can be vertically aligned above a substrate with each channel being surrounded by a gate structure has been disclosed. The integrated circuit device may include a temperature sensor circuit and core circuitry. The temperature senor circuit may include at least one portion formed in a region other than the region that the IGFETs are formed as well as at least another portion formed in the region that the IGFETs having a plurality of horizontally disposed channels that can be vertically aligned above a substrate with each channel being surrounded by a gate structure are formed. By forming a portion of the temperature sensor circuit in regions below the IGFETs, an older process technology may be used and device size may be decreased and cost may be reduced.

An integrated circuit device having insulated gate field effect transistors (IGFETs) having a plurality of horizontally disposed channels that can be vertically aligned above a substrate with each channel being surrounded by a gate structure has been disclosed. The integrated circuit device may include a temperature sensor circuit and core circuitry. The temperature senor circuit may include at least one portion formed in a region other than the region that the IGFETs are formed as well as at least another portion formed in the region that the IGFETs having a plurality of horizontally disposed channels that can be vertically aligned above a substrate with each channel being surrounded by a gate structure are formed. By forming a portion of the temperature sensor circuit in regions below the IGFETs, an older process technology may be used and device size may be decreased and cost may be reduced.

A control arrangement is disclosed for providing a plurality of phase-coherent oscillating signals. It comprises a reference clock signal arrangement for providing a high-frequency reference clock signal and a plurality of modules each comprising a plurality of channels for providing the plurality of phase-coherent oscillating signals.

A control arrangement is disclosed for providing a plurality of phase-coherent oscillating signals. It comprises a reference clock signal arrangement for providing a high-frequency reference clock signal and a plurality of modules each comprising a plurality of channels for providing the plurality of phase-coherent oscillating signals.

A circuit and a method for eliminating a spurious signal are provided. The circuit includes a phase detector, a spurious estimation and regeneration device, and a phase shifter. After an actual clock signal containing a spurious signal is obtained, the contained spurious signal is estimated based on the reference clock signal that does not contain the spurious signal. Reverse adjustment is performed on the actual clock signal based on the estimated spurious signal to eliminate the spurious signal in the actual clock signal, ensuring eliminating the generated spurious signal by performing reverse adjustment, improving the signal transmission quality, thereby solving the problem of reduced signal quality due to that the spurious signal cannot be suppressed in generation according to the conventional technology.

A circuit and a method for eliminating a spurious signal are provided. The circuit includes a phase detector, a spurious estimation and regeneration device, and a phase shifter. After an actual clock signal containing a spurious signal is obtained, the contained spurious signal is estimated based on the reference clock signal that does not contain the spurious signal. Reverse adjustment is performed on the actual clock signal based on the estimated spurious signal to eliminate the spurious signal in the actual clock signal, ensuring eliminating the generated spurious signal by performing reverse adjustment, improving the signal transmission quality, thereby solving the problem of reduced signal quality due to that the spurious signal cannot be suppressed in generation according to the conventional technology.

A system includes a transmitter to transmit a set of bits associated with signaling having one or more levels. The system includes a receiver coupled to the transmitter, the receiver to receive the set of bits and generate a first plurality of digital values, each digital value generated at a first timing value and a plurality of reference voltages, the reference voltage incremented based at least in part on generating a digital value of the first plurality of digital values. The receiver is to generate a second plurality of digital values at a second timing value and the plurality of reference voltages, the first timing value incremented to the second timing value based at least in part on generating the first plurality of digital values. The system includes a controller to determine an amplitude associated with each the first and second plurality of digital values.

A system includes a transmitter to transmit a set of bits associated with signaling having one or more levels. The system includes a receiver coupled to the transmitter, the receiver to receive the set of bits and generate a first plurality of digital values, each digital value generated at a first timing value and a plurality of reference voltages, the reference voltage incremented based at least in part on generating a digital value of the first plurality of digital values. The receiver is to generate a second plurality of digital values at a second timing value and the plurality of reference voltages, the first timing value incremented to the second timing value based at least in part on generating the first plurality of digital values. The system includes a controller to determine an amplitude associated with each the first and second plurality of digital values.

An electronic device according to various embodiments may include a memory storing a table containing a delay time in a process of receiving a network packet and an operation corresponding to the delay time, and a processor operatively connected to the memory. The memory may store instructions, which upon execution, control the processor to measure a delay time for each step based on a time when the network packet reaches each network processing step in the process of receiving the network packet, calculate an average delay time by accumulating a given number of network packets for each step, determine whether network performance of the electronic device is sufficient for receiving the network packet by comparing, with a pre-configured first time, the average delay time calculated by accumulating the network packets, and improve the network performance of the electronic device so that the network performance is sufficient for receiving the network packet based on the network performance of the electronic device being determined to be insufficient.

An electronic device according to various embodiments may include a memory storing a table containing a delay time in a process of receiving a network packet and an operation corresponding to the delay time, and a processor operatively connected to the memory. The memory may store instructions, which upon execution, control the processor to measure a delay time for each step based on a time when the network packet reaches each network processing step in the process of receiving the network packet, calculate an average delay time by accumulating a given number of network packets for each step, determine whether network performance of the electronic device is sufficient for receiving the network packet by comparing, with a pre-configured first time, the average delay time calculated by accumulating the network packets, and improve the network performance of the electronic device so that the network performance is sufficient for receiving the network packet based on the network performance of the electronic device being determined to be insufficient.