Abstract: Apparatuses and methods for refreshing memory cells of a semiconductor device are described. An example apparatus includes: a memory cell array including a plurality of memory groups each having a plurality of memory cells, the memory groups being selected by mutually different addresses; a first control circuit periodically executing a refresh operation on the memory groups in response to a first refresh command; and a second control circuit setting a cycle of executing the refresh operation by the first control circuit. The second control circuit sets the cycle to a first cycle until executing the refresh operation to all the memory groups after receiving the first refresh command, and the second control circuit sets the cycle to a second cycle that is longer than the first cycle after executing the refresh operation to all the memory groups.

Abstract: A method for prophylactically or therapeutically treating an inflammatory disease and/or degenerative intervertebral disk disease in a subject is disclosed. The method includes administering to the subject an effective amount of a coumarin derivative represented by formula (I), or a pharmaceutically acceptable salt or hydrate thereof: Each of R1 and R2 is independently (a) phenyl optionally substituted with alkoxy, alkyl, cyano, nitro, hydroxy, trifluoromethyl, amino, carboxy, alkoxycarbonyl, phenyl, or one or two halogen(s), (b) pyridyl, (c) alkyl, or (d) thienyl.

Abstract: Apparatuses and methods for refreshing memory cells of semiconductor device are described. An example apparatus includes: a memory cell array including a plurality of memory groups each having a plurality of memory cells, the memory groups being selected by mutually different addresses; a first control circuit periodically executing a refresh operation on the memory groups in response to a first refresh command; and a second control circuit setting a cycle of executing the refresh operation by the first control circuit. The second control circuit sets the cycle to a first cycle until executing the refresh operation to all the memory groups after receiving the first refresh command, and the second control circuit sets the cycle to a second cycle that is longer than the first cycle after executing the refresh operation to all the memory groups.

Abstract: A device includes a first data terminal, a second data terminal, a first switching buffer coupled between a data node and the first data terminal and a second switching buffer coupled between the data node and the second data terminal. The first switching buffer and the second switching buffer are arranged such that a distance between the first switching buffer and the second data terminal is shorter than a distance between the second switching buffer and the second data terminal and that a distance between the first switching buffer and the first data terminal is shorter than a distance between the second switching buffer and the first data terminal.

Abstract: A device includes a first data terminal, a second data terminal, a first switching buffer coupled between a data node and the first data terminal and a second switching buffer coupled between the data node and the second data terminal. The first switching buffer and the second switching buffer are arranged such that a distance between the first switching buffer and the second data terminal is shorter than a distance between the second switching buffer and the second data terminal and that a distance between the first switching buffer and the first data terminal is shorter than a distance between the second switching buffer and the first data terminal.

Abstract: An apparatus includes a first terminal configured to communicate data with an outside of the apparatus, a second terminal configured to receive a first power source potential, a third terminal configured to receive a second power source potential lower than the first power source potential, a fourth terminal configured to be coupled to a calibration resistor, an output buffer including first to third nodes coupled to the first to third terminals respectively, and a replica circuit including fourth and fifth nodes coupled to the second and third terminals respectively, and sixth node coupled to the fourth terminal.

Abstract: An apparatus includes a first terminal configured to communicate data with an outside of the apparatus, a second terminal configured to receive a first power source potential, a third terminal configured to receive a second power source potential lower than the first power source potential, a fourth terminal configured to be coupled to a calibration resistor, an output buffer including first to third nodes coupled to the first to third terminals respectively, and a replica circuit including fourth and fifth nodes coupled to the second and third terminals respectively, and sixth node coupled to the fourth terminal.

Abstract: An apparatus includes a first terminal configured to communicate data with an outside of the apparatus, a second terminal configured to receive a first power source potential, a third terminal configured to receive a second power source potential lower than the first power source potential, a fourth terminal configured to be coupled to a calibration resistor, an output buffer including first to third nodes coupled to the first to third terminals respectively, and a replica circuit including fourth and fifth nodes coupled to the second and third terminals respectively, and sixth node coupled to the fourth terminal.

Abstract: Apparatuses for controlling latencies on input signal paths in semiconductor devices are disclosed. An example apparatus includes: a clock input buffer that provides a reference clock signal and a system clock signal based on an external clock signal; a command decoder that latches command signals with the system clock signal and further provides a signal based on the command signals; and a command delay adjustment circuit including: a clock synchronizing circuit that receives the signal, latches the signal with the system clock signal and provides a clock-synchronized read signal responsive to a shift cycle parameter.

Abstract: Apparatuses for controlling latencies on input signal paths in semiconductor devices are disclosed. An example apparatus includes: a clock input buffer that provides a reference clock signal and a system clock signal based on an external clock signal; a command decoder that latches command signals with the system clock signal and further provides a signal based on the command signals; and a command delay adjustment circuit including: a clock synchronizing circuit that receives the signal, latches the signal with the system clock signal and provides a clock-synchronized read signal responsive to a shift cycle parameter.

Abstract: Apparatuses for controlling latencies on input signal paths in semiconductor devices are disclosed. An example apparatus includes: a clock input buffer that provides a reference clock signal and a system clock signal based on an external clock signal; a command decoder that latches command signals with the system clock signal and further provides a signal based on the command signals; and a command delay adjustment circuit including: a clock synchronizing circuit that receives the signal, latches the signal with the system clock signal and provides a clock-synchronized read signal responsive to a shift cycle parameter.

Abstract: Disclosed herein is a semiconductor device that includes: a memory cell array including a plurality of memory groups each having a plurality of memory cells, the memory groups being selected by mutually different addresses; a first control circuit periodically executing a refresh operation on the memory groups in response to a first refresh command; and a second control circuit setting a cycle of executing the refresh operation by the first control circuit. The second control circuit sets the cycle to a first cycle until executing the refresh operation to all the memory groups after receiving the first refresh command, and the second control circuit sets the cycle to a second cycle that is longer than the first cycle after executing the refresh operation to all the memory groups.

Abstract: Disclosed herein is a semiconductor device that includes: a memory cell array including a plurality of memory groups each having a plurality of memory cells, the memory groups being selected by mutually different addresses; a first control circuit periodically executing a refresh operation on the memory groups in response to a first refresh command: and a second control circuit setting a cycle of executing the refresh operation by the first control circuit. The second control circuit sets the cycle to a first cycle until executing the refresh operation to all the memory groups after receiving the first refresh command, and the second control circuit sets the cycle, to a second cycle that is longer than the first cycle after executing the refresh operation to all the memory groups.

Abstract: To decrease the circuit scale necessary for the calibration of the output circuit and to decrease the time required for the calibration operation. The invention includes a first output buffer and a second output buffer that are connected to a data pin, and a calibration circuit that is connected to a calibration pin. The first output buffer and the second output buffer include plural unit buffers. The unit buffers have mutually the same circuit structures. With this arrangement, the impedances of the first output buffer and the second output buffer can be set in common, based on the calibration operation using the calibration circuit. Consequently, both the circuit scale necessary for the calibration operation and the time required for the calibration operation can be decreased.

Abstract: A device includes a first data terminal, a second data terminal, a first switching buffer coupled between a data node and the first data terminal and a second switching buffer coupled between the data node and the second data terminal. The first switching buffer and the second switching buffer are arranged such that a distance between the first switching buffer and the second data terminal is shorter than a distance between the second switching buffer and the second data terminal and that a distance between the first switching buffer and the first data terminal is shorter than a distance between the second switching buffer and the first data terminal.

Abstract: An apparatus includes a first terminal configured to communicate data with an outside of the apparatus, a second terminal configured to receive a first power source potential, a third terminal configured to receive a second power source potential lower than the first power source potential, a fourth terminal configured to be coupled to a calibration resistor, an output buffer including first to third nodes coupled to the first to third terminals respectively, and a replica circuit including fourth and fifth nodes coupled to the second and third terminals respectively, and sixth node coupled to the fourth terminal.

Abstract: A method for prophylactically or therapeutically treating an inflammatory disease and/or degenerative intervertebral disk disease in a subject is disclosed. The method includes administering to the subject an effective amount of a coumarin derivative represented by formula (I), or a pharmaceutically acceptable salt or hydrate thereof: Each of R1 and R2 is independently (a) phenyl optionally substituted with alkoxy, alkyl, cyano, nitro, hydroxy, trifluoromethyl, amino, carboxy, alkoxycarbonyl, phenyl, or one or two halogen(s), (b) pyridyl, (c) alkyl, or (d) thienyl.

Abstract: To decrease the circuit scale necessary for the calibration of the output circuit and to decrease the time required for the calibration operation. The invention includes a first output buffer and a second output buffer that are connected to a data pin, and a calibration circuit that is connected to a calibration pin. The first output buffer and the second output buffer include plural unit buffers. The unit buffers have mutually the same circuit structures. With this arrangement, the impedances of the first output buffer and the second output buffer can be set in common, based on the calibration operation using the calibration circuit. Consequently, both the circuit scale necessary for the calibration operation and the time required for the calibration operation can be decreased.

Abstract: A device includes a first data terminal, a second data terminal, a first switching buffer coupled between a data node and the first data terminal and a second switching buffer coupled between the data node and the second data terminal. The first switching buffer and the second switching buffer are arranged such that a distance between the first switching buffer and the second data terminal is shorter than a distance between the second switching buffer and the second data terminal and that a distance between the first switching buffer and the first data terminal is shorter than a distance between the second switching buffer and the first data terminal.

Abstract: An apparatus includes a first terminal configured to communicate data with an outside of the apparatus, a second terminal configured to receive a first power source potential, a third terminal configured to receive a second power source potential lower than the first power source potential, a fourth terminal configured to be coupled to a calibration resistor, an output buffer including first to third nodes coupled to the first to third terminals respectively, and a replica circuit including fourth and fifth nodes coupled to the second and third terminals respectively, and sixth node coupled to the fourth terminal.