Abstract: A computer system for managing analysis source data receives and executes an analysis program. The computer system calculates one or more types of deviations, based on a behavior of the analysis program. The computer system controls whether or not to output, to the outside of the computer system, output data that is data output as a result of analysis by the analysis program, based on the one or more types of calculated deviations.

Abstract: It has been difficult to carry out a test and an analysis with respect to combinational logic circuits mounted across plural chips, and therefore, there is provided a flip-flop (31b) by use of which either of a scan chain within a semiconductor chip (LSI_B), and a scan chain across plural semiconductor chips (LSI_A and LSI_B) can be made up.

Abstract: It has been difficult to carry out a test and an analysis with respect to combinational logic circuits mounted across plural chips, and therefore, there is provided a flip-flop (31b) by use of which either of a scan chain within a semiconductor chip (LSI_B), and a scan chain across plural semiconductor chips (LSI_A and LSI_B) can be made up.

Abstract: A highly flexible semiconductor device of a stacked-type semiconductor device which transfers information by inductive coupling between inductors, in which LSI chips can be stacked even when a transmitter circuit and a receiver circuit are arranged at different positions from each other when viewed in a stacking direction. The semiconductor device has an interposer including a first inductor which is inductively coupled with a transmitter circuit of a first LSI chip to be stacked, and a second inductor which is inductively coupled with a receiver circuit of a second LSI chip to be stacked, the first inductor and the second inductor being electrically connected. An interchip communication is made from the first LSI chip to the second LSI chip.

Abstract: A video encoder for evaluating a prediction error by using a prediction technique include: an image encoding section which encodes a prediction image; and an encoding control device which selects any one of a plurality of prediction modes in prediction used by the image encoding section. The image encoding section performs clipping of higher-order bits of the prediction error input to the encoding control device and reduction of lower-order bits thereof for each of the prediction modes to control prediction mode selection, thus reducing the prediction error bit width to a predetermined bit width. The encoding control device sets to the image encoding section the number of higher-order bits to be clipped and the number of lower-order bits to be reduced. The predetermined bit width of the prediction error after bit width reduction is matched with the bus width used for prediction error transmission by the encoding control device and the image encoding section.

Abstract: This invention provide a data processor capable of multiplexing data transfers with desired data transfer characteristics guaranteed, without multiplexing buses. The data processor includes: a transfer path that mutually connects plural processors and plural transfer element circuits such as memory; an arbitration circuit that controls data transfer in the transfer path; and a control register that defines the priority and minimum guaranteed bandwidth of data transfer. The arbitration circuit decomposes data packets sent from plural data transfer sources into subunits, and reconstructs plural data packets having the same data transfer target, based on priority and minimum guaranteed bandwidth stored in a control register. Thereby, the one reconstructed data packet can include subunits of plural data packets from transfer sources having different priorities, and data amounts of subunits contained in it can satisfy minimum guaranteed bandwidth of data transfer.

Abstract: There is provided at least one processor block including a plurality of load store interfaces (801, 804), a plurality of memory banks (821), an input/output port having at least one of an input port (850) and an output port (860), and a crossbar switch (810), and the crossbar switch connects the load store interface, the memory bank and the input/output port to each other and the load store interface constitutes a data processor in order to control a data transfer to the memory bank. Consequently, there is implemented a data processor having a high transfer throughput and a flexibility and efficiently treating stream data.

Abstract: To realize a software radio processing with a reduced circuit area by hardware and software which can process transmission and reception, or synchronization and demodulation in time division. There are provided a circuit DRC that can dynamically change a configuration with a structure that can change the configuration at a high speed, a general processor, and an interface for connection with an external device such as an AD converter or a DA converter. Software radio is realized by using a software radio chip that conducts plural different processing such as transmission and reception, or synchronization and demodulation in time division. The different processing during the radio signal processing can be conducted in time division. As a result, the software radio can be realized with a circuit of a reduced area in a software radio system that allocates regions of an FPGA to the respective processing.

Abstract: The present invention relates to a video transmission system that uses an encoding/decoding technique. An object of the present invention is to refrain from using a memory for storing decoded image data, avoid a decoder input buffer problem (buffer overflow or underflow) with ease, achieve cost reduction, and provide enhanced image quality. In the video transmission system with an encoding/decoding device, a reference signal for adjusting a synchronization schedule of the entire system is generated and supplied to various sections. In addition, a timing adjustment amount for adjusting the synchronization schedule for the reference signal is generated by a decoder and supplied to a camera.

Abstract: Provided is a multiprocessor configured by stacking a plurality of unit chips each having, at least, a processor core and a memory, and the unit chip has a configuration including: a plurality of processor cores; a plurality of memories; a construction controlling unit setting connection relations between the processor core and the memory and between the processor core and the outside of the chip; and a chip connecting unit transmitting transaction between the processor, the memory, or the construction controlling unit and another stacked unit chip to be connected. The chip connecting units are arranged so as to be rotationally symmetric to each other on side portions of the unit chip, so that any of the unit chips configured by stacking is rotationally connected.

Abstract: A highly flexible semiconductor device of a stacked-type semiconductor device which transfers information by inductive coupling between inductors, in which LSI chips can be stacked even when a transmitter circuit and a receiver circuit are arranged at different positions from each other when viewed in a stacking direction. The semiconductor device has an interposer including a first inductor which is inductively coupled with a transmitter circuit of a first LSI chip to be stacked, and a second inductor which is inductively coupled with a receiver circuit of a second LSI chip to be stacked, the first inductor and the second inductor being electrically connected. An interchip communication is made from the first LSI chip to the second LSI chip.

Abstract: A data processing apparatus has a memory element array (330) having a plurality of entries each formed by a memory element of more than one bit having a data shift function and a data comparison function, and the memory element array is arranged so that data can be shifted between corresponding bit positions of adjacent entries. Further, the data processing apparatus has a priority-judging circuit (340) for identifying one of the entries according to predetermined priorities based on results of comparison between data input to the entries in common and contents held by the memory elements constituting the entries. Even when the data held by an entry located halfway is nullified, data shift between entries can avoid that the entry with nullified data remains halfway, and enables the entries to hold valid data in order with the data densely aligned. The time sequence when data are held can be made coincident with the alignment of entries readily.

Abstract: A basic cell capable of a fixed operating frequency regardless of the configuration information, which is also capable of effectively utilizing the arithmetic logic circuit within the cell in a LSI semiconductor integrated circuit, is capable of dynamic changes in configuration information. The circuit has an input switch ISW connected to multiple data input nodes, an output switch OSW connected to multiple data output nodes, a first data path containing an arithmetic logic circuit ALU and a result storage flip-flop CFF0 between the input switch ISW and output switch OSW. The second data path containing a data transfer flip-flop between an input switch ISW and an output switch OSW, and the result storage flip-flop CFF stores the calculated result data from the arithmetic logic circuit ALU, and the data transfer flip-flop holds data input from any of the multiple data input nodes.

Abstract: A dynamically reconfigurable processor is provided having a wiring structure which enables flexible mapping of a program to the processor with a small wiring area. A first wire permits a first arrangement of circuit blocks and a second wire provided for changing the arrangement order of the circuit blocks. A switch is provided to switch between the first wire and the second wire. By virtue of this arrangement, a greater variety of calculations can be performed in the circuit without the necessity for increasing the number of operation blocks.

Abstract: A basic cell capable of a fixed operating frequency regardless of the configuration information, which is also capable of effectively utilizing the arithmetic logic circuit within the cell in a LSI semiconductor integrated circuit, is capable of dynamic changes in configuration information. The circuit has an input switch ISW connected to multiple data input nodes, an output switch OSW connected to multiple data output nodes, a first data path containing an arithmetic logic circuit ALU and a result storage flip-flop CFF0 between the input switch ISW and output switch OSW. The second data path containing a data transfer flip-flop between an input switch ISW and an output switch OSW, and the result storage flip-flop CFF stores the calculated result data from the arithmetic logic circuit ALU, and the data transfer flip-flop holds data input from any of the multiple data input nodes.

Abstract: A method and apparatus are provided for event detection for a multiple instruction-set processor. In one example of the apparatus, a data processing device comprises an instruction execution device configured to execute a first instruction set as specific instructions; an instruction conversion circuit configured to convert instructions of a second instruction set into a first instruction string of the first instruction set, and further configured to supply the first instruction string to the instruction execution device; and a counter device configured to count a prescribed event, wherein the instruction conversion circuit is further configured to output a prescribed instruction when the counter device is satisfied by a prescribed condition.

Abstract: This invention provide a data processor capable of multiplexing data transfers with desired data transfer characteristics guaranteed, without multiplexing buses. The data processor includes: a transfer path that mutually connects plural processors and plural transfer element circuits such as memory; an arbitration circuit that controls data transfer in the transfer path; and a control register that defines the priority and minimum guaranteed bandwidth of data transfer. The arbitration circuit decomposes data packets sent from plural data transfer sources into subunits, and reconstructs plural data packets having the same data transfer target, based on priority and minimum guaranteed bandwidth stored in a control register. Thereby, the one reconstructed data packet can include subunits of plural data packets from transfer sources having different priorities, and data amounts of subunits contained in it can satisfy minimum guaranteed bandwidth of data transfer.

Abstract: A dynamically reconfigurable processor having a wiring structure which enables flexible mapping of a program to the processor with a small wiring area is provided. The dynamically reconfigurable processor comprises: a first arithmetic circuit group composed of arithmetic circuits of a type Ai (i=1, 2, . . . , N); a second arithmetic circuit group composed of a part of an arithmetic circuit group included in the first arithmetic circuit group and an arithmetic circuit group of a type B which is connected thereto and different from the arithmetic circuit of the type Ai; inter-arithmetic-circuit wires mutually connecting the arithmetic circuits of the type Ai and the arithmetic circuits of the type B; and a switch group which causes the inter-arithmetic-circuit wires in the second arithmetic circuit group to be inter-arithmetic-circuit wires different from other inter-arithmetic-circuit wires and changes the connection order between the arithmetic circuits in the second arithmetic circuit group.

Abstract: A microprocessor includes a first cache memory, a first instruction fetch unit, a first instruction decoder, a first processing unit and a first latch that holds a control signal outputted from the first instruction decoder. When the first instruction fetch unit receives a first instruction performed by the first processing unit it outputs the first instruction to the first instruction decoder. When the first instruction fetch unit receives a second instruction which is not performed by the first processing unit, it outputs a specific instruction to the first instruction decoder, after which the supply of clock pulses to other latch circuits In the first processing unit is halted based on the control signal.

Abstract: The present invention provides a hardware accelerator, which allows faster switching between processing modes. In an information processing device with a bytecode accelerator BCA for translating a stack-based intermediate code (bytecode) into register-based instructions, a selector SEL for switching between BCA and soft VM is posed between an instruction part FET and a decode part DEC and data transfer paths P4 and P5 are formed between BCA and the register file REG_FILE. When bytecode accelerator BCA is activated, the P3 side is selected by the selector SEL and the translated CPU instructions are transferred to the decode part DEC. If the intermediate language code cannot be translated by the BCA, the processing mode is switched to software processing. During switching between the modes, internal information of BCA can be transferred between BCA and REG_FILE in parallel, achieving faster mode switching.