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    • 61. 发明授权
    • Semiconductor device and manufacturing method thereof
    • 半导体装置及其制造方法
    • US07875875B2
    • 2011-01-25
    • US11450280
    • 2006-06-12
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • H01L31/00
    • H01L31/035236B82Y20/00H01S5/22H01S5/2275H01S5/3201H01S5/3412H01S5/5009
    • A quantum dot semiconductor device securing sufficient gains without depending on polarization and a manufacturing method thereof. On a first barrier layer, a multilayer quantum dot is formed by repeatedly stacking alternately a quantum dot layer and a second barrier layer. On a quantum dot layer as an uppermost layer of the quantum dot, a third barrier layer which keeps local strains in the quantum dot layer is formed. On the third barrier layer, a fourth barrier layer which compensates compressive strains from the second barrier layer is formed. Therefore, the fourth barrier layer made of tensile strain materials compensates accumulation of compressive strains caused by stacking of a multilayer quantum dot layer. The third barrier layer prevents tensile strains in the fourth barrier layer from directly impacting on the quantum dot layer, so that local strains can be effectively cancelled. Thus, the above-described semiconductor device can be realized.
    • 量子点半导体器件及其制造方法确保足够的增益而不依赖于极化。 在第一阻挡层上,通过重复堆叠量子点层和第二阻挡层来形成多层量子点。 在作为量子点的最上层的量子点层上形成保持量子点层局部应变的第三势垒层。 在第三阻挡层上形成补偿来自第二阻挡层的压缩应变的第四阻挡层。 因此,由拉伸应变材料制成的第四阻挡层补偿由堆叠多层量子点层引起的压缩应变的累积。 第三阻挡层防止第四阻挡层中的拉伸应变直接影响量子点层,从而可以有效地消除局部应变。 因此,可以实现上述半​​导体器件。
    • 62. 发明申请
    • DATA TRANSFER APPARATUS AND DATA TRANSFER METHOD
    • 数据传输设备和数据传输方法
    • US20100306441A1
    • 2010-12-02
    • US12852137
    • 2010-08-06
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • G06F13/14
    • G06F13/362
    • A data transfer apparatus for transferring data between a system bus and a local bus at a high speed is provided. A bus bridge 101 is connected between a system bus 132 and a local bus 137. Data transferred between a CPU 133, an I/O device 136 and a main memory 135 on the system bus 132 are retained in an associative memory 106 via an associative memory control unit 105. When an access to this data from an I/O device 138 on the local bus 137 is generated, the data are transferred from the associative memory 106 to the I/O device 138. Thus, when a data transfer request from the I/O device 138 to the main memory 135 is generated, no bus cycle is generated on the system bus 132 as long as this data are retained in the associative memory 106. Consequently, the data can be transferred at a high speed.
    • 提供了一种用于在系统总线和本地总线之间高速传输数据的数据传送装置。 总线桥101连接在系统总线132和本地总线137之间。在CPU 133,I / O设备136和系统总线132上的主存储器135之间传送的数据经由关联式存储器106保留在关联存储器106中 存储器控制单元105.当生成来自本地总线137上的I / O设备138的该数据的访问时,数据从关联存储器106传送到I / O设备138.因此,当数据传输请求 产生从I / O设备138到主存储器135,只要该数据被保留在关联存储器106中,就不会在系统总线132上产生总线周期。因此,可以高速传送数据。
    • 63. 发明授权
    • Data transfer apparatus and data transfer method
    • 数据传输装置和数据传输方法
    • US07814257B2
    • 2010-10-12
    • US11519114
    • 2006-09-11
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • G06F13/14G06F13/00
    • G06F13/362
    • A data transfer apparatus for transferring data between a system bus and a local bus at a high speed is provided. A bus bridge 101 is connected between a system bus 132 and a local bus 137. Data transferred between a CPU 133, an I/O device 136 and a main memory 135 on the system bus 132 are retained in an associative memory 106 via an associative memory control unit 105. When an access to this data from an I/O device 138 on the local bus 137 is generated, the data are transferred from the associative memory 106 to the I/O device 138. Thus, when a data transfer request from the I/O device 138 to the main memory 135 is generated, no bus cycle is generated on the system bus 132 as long as this data are retained in the associative memory 106. Consequently, the data can be transferred at a high speed.
    • 提供了一种用于在系统总线和本地总线之间高速传输数据的数据传送装置。 总线桥101连接在系统总线132和本地总线137之间。在CPU 133,I / O设备136和系统总线132上的主存储器135之间传送的数据经由关联式存储器106保留在关联存储器106中 存储器控制单元105.当生成来自本地总线137上的I / O设备138的该数据的访问时,数据从关联存储器106传送到I / O设备138.因此,当数据传输请求 产生从I / O设备138到主存储器135,只要该数据被保留在关联存储器106中,就不会在系统总线132上产生总线周期。因此,可以高速传送数据。
    • 65. 发明授权
    • Data transfer apparatus with control of buses to enable reading of predetermined data sizes
    • 具有控制总线的数据传送装置,能够读取预定的数据大小
    • US07516262B2
    • 2009-04-07
    • US12028708
    • 2008-02-08
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • G06F13/36
    • G06F13/4027G06F13/4031G06F13/4059G06F13/423G06F2213/0024
    • A bus bridge is connected to a primary bus and a secondary bus, and relays data between a master and a target which are each connected to a different one of the primary and secondary buses. The bus bridge includes a primary bus interface, a secondary bus interface, a data FIFO, and a register block. The register block, which can be written by the master, includes two registers corresponding to the primary and secondary buses. Relay information showing the number of entries of data to be relayed from the target to the master is registered in a register corresponding to a bus to which the target is connected. In a read transaction, the primary bus interface or the secondary bus interface reads data from the target until data of the amount shown by the registered relay information is stored in the data FIFO.
    • 总线桥连接到主总线和辅助总线,并且中继主机和目标之间的数据,每个主站和目标站之间连接到主总线和次总线之间的不同的总线。 总线桥包括主总线接口,辅助总线接口,数据FIFO和寄存器块。 可由主器件写入的寄存器块包括与主母线和辅助母线相对应的两个寄存器。 显示要从目标到主机中继的数据的条目数的中继信息被登记在对应于目标连接到的总线的寄存器中。 在读取事务中,主总线接口或辅助总线接口从目标读取数据,直到被注册的中继信息所示量的数据被存储在数据FIFO中。
    • 66. 发明申请
    • BUS BRIDGE AND ARBITRATION METHOD
    • BUS BRIDGE AND ARBITRATION方法
    • US20080183936A1
    • 2008-07-31
    • US11936425
    • 2007-11-07
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • G06F13/36
    • G06F13/4031
    • A bus bridge is connected to a first bus and a second bus. In the bus bridge, an arbiter grants ownership of the first bus to one of a plurality of devices connected to the first bus. A detecting unit detects a read cycle initiated by the device on the first bus to read data from a memory which is also accessible by another device connected to the second bus. A first signaling unit sends a first signal to the arbiter, when the data is not yet transferable to the device when the read cycle is detected. A second signaling unit sends a second signal to the arbiter, when the data becomes transferable to the device. The arbiter deprives the device of the ownership of the first bus upon receipt of the first signal, and withholds from granting the ownership to the device until receipt of the second signal.
    • 总线桥连接到第一总线和第二总线。 在总线桥中,仲裁者将第一总线的所有权授予连接到第一总线的多个设备之一。 检测单元检测由第一总线上的设备发起的读周期,以从存储器读取数据,该存储器也可由连接到第二总线的另一设备访问。 当检测到读取周期时,当数据不能传输到设备时,第一信令单元向仲裁器发送第一信号。 当数据可转移到设备时,第二信令单元向仲裁器发送第二信号。 仲裁者在收到第一个信号后,剥夺了第一个公共汽车的所有权,并将所有权授予设备,直到收到第二个信号。
    • 67. 发明授权
    • Data transfer apparatus for limiting read data by a bus bridge with relay information
    • 用于通过具有中继信息的总线桥接器限制读取数据的数据传送装置
    • US07360009B2
    • 2008-04-15
    • US11623685
    • 2007-01-16
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • G06F13/36
    • G06F13/4027G06F13/4031G06F13/4059G06F13/423G06F2213/0024
    • A bus bridge is connected to a primary bus and a secondary bus, and relays data between a master and a target which are each connected to a different one of the primary and secondary buses. The bus bridge includes a primary bus interface, a secondary bus interface, a data FIFO, and a register block. The register block, which can be written by the master, includes two registers corresponding to the primary and secondary buses. Relay information showing the number of entries of data to be relayed from the target to the master is registered in a register corresponding to a bus to which the target is connected. In a read transaction, the primary bus interface or the secondary bus interface reads data from the target until data of the amount shown by the registered relay information is stored in the data FIFO.
    • 总线桥连接到主总线和辅助总线,并且中继主机和目标之间的数据,每个主站和目标站之间连接到主总线和次总线之间的不同的总线。 总线桥包括主总线接口,辅助总线接口,数据FIFO和寄存器块。 可由主器件写入的寄存器块包括与主母线和辅助母线相对应的两个寄存器。 显示要从目标到主机中继的数据的条目数的中继信息被登记在对应于目标连接到的总线的寄存器中。 在读取事务中,主总线接口或辅助总线接口从目标读取数据,直到被注册的中继信息所示量的数据被存储在数据FIFO中。
    • 69. 发明申请
    • Semiconductor device and manufacturing method thereof
    • 半导体装置及其制造方法
    • US20070210300A1
    • 2007-09-13
    • US11450280
    • 2006-06-12
    • Kenichi Kawaguchi
    • Kenichi Kawaguchi
    • H01L31/00
    • H01L31/035236B82Y20/00H01S5/22H01S5/2275H01S5/3201H01S5/3412H01S5/5009
    • A quantum dot semiconductor device securing sufficient gains without depending on polarization and a manufacturing method thereof. On a first barrier layer, a multilayer quantum dot is formed by repeatedly stacking alternately a quantum dot layer and a second barrier layer. On a quantum dot layer as an uppermost layer of the quantum dot, a third barrier layer which keeps local strains in the quantum dot layer is formed. On the third barrier layer, a fourth barrier layer which compensates compressive strains from the second barrier layer is formed. Therefore, the fourth barrier layer made of tensile strain materials compensates accumulation of compressive strains caused by stacking of a multilayer quantum dot layer. The third barrier layer prevents tensile strains in the fourth barrier layer from directly impacting on the quantum dot layer, so that local strains can be effectively cancelled. Thus, the above-described semiconductor device can be realized.
    • 量子点半导体器件及其制造方法确保足够的增益而不依赖于极化。 在第一阻挡层上,通过重复堆叠量子点层和第二阻挡层来形成多层量子点。 在作为量子点的最上层的量子点层上形成保持量子点层局部应变的第三势垒层。 在第三阻挡层上形成补偿来自第二阻挡层的压缩应变的第四阻挡层。 因此,由拉伸应变材料制成的第四阻挡层补偿由堆叠多层量子点层引起的压缩应变的累积。 第三阻挡层防止第四阻挡层中的拉伸应变直接影响量子点层,从而可以有效地消除局部应变。 因此,可以实现上述半​​导体器件。