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    • 1. 发明申请
    • CLOCK SIGNAL DIVIDING CIRCUIT
    • 时钟信号分路
    • US20100052753A1
    • 2010-03-04
    • US12514115
    • 2007-10-26
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • H03L7/00
    • G06F1/10H03K23/507H03L7/0814H03L7/16
    • A clock signal dividing circuit in which a dividing ratio is regulated by N/M (M and N are positive integers and satisfy M>N) includes: a variable delay circuit which gives a predetermined delay amount based on a control value to an input clock signal CKI to output an output clock signal CKO; and a variable delay control circuit which cumulatively adds values obtained by subtracting N from M every cycle of the input clock signal CKI, when the addition result is N or more, performs a calculation which subtracts N from the addition result to obtain a calculation result K, and calculates, to a maximum delay amount in the variable delay circuit corresponding to one cycle of the input clock signal CKI, a control value corresponding to a delay amount of K/N of the maximum delay amount to give the control value to the variable delay circuit.
    • 分频比由N / M(M和N是正整数,满足M> N)调节的时钟信号分频电路包括:可变延迟电路,其基于对输入时钟的控制值给出预定的延迟量 信号CKI输出输出时钟信号CKO; 以及可变延迟控制电路,当相加结果为N以上时,累积地将通过从输入时钟信号CKI的每个周期从M中减去N而获得的值执行从相加结果中减去N的计算,以获得计算结果K ,并且将对应于输入时钟信号CKI的一个周期的可变延迟电路中的最大延迟量计算为与最大延迟量的K / N的延迟量相对应的控制值,以将控制值赋予该变量 延时电路。
    • 2. 发明申请
    • Clock Generating Circuit and Clock Generating Method
    • 时钟发生电路和时钟发生方法
    • US20080018372A1
    • 2008-01-24
    • US11575168
    • 2005-09-16
    • Koichi NoseMasayuki MizunoAtsufumi Shibayama
    • Koichi NoseMasayuki MizunoAtsufumi Shibayama
    • H03H11/16
    • H03K5/00006G06F1/06H03K5/13H03K5/1565H03K2005/00052H03L7/07H03L7/0814
    • A clock converting circuit (1) receives and then converts m-phase clocks of a frequency f having a phase difference of 1/(f×m) to n-phase clocks of the frequency f having a phase difference of 1/(f×n). A single-phase clock generating circuit (2) receives the n-phase clocks of the frequency f having a phase difference equivalent time of 1/(f×n) to generate single-phase clocks in synchronism with the rising or falling edges of the n-phase clocks. Since the frequency of the m-phase clocks inputted to the clock converting circuit (1) is ‘f’, if a desired frequency of the single-phase clocks is decided, then ‘n’ can be obtained from the equation: the frequency of the single-phase clocks is equal to (f×n). This value of ‘n’ is set to the clock converting circuit (1), thereby obtaining the n-phase clocks of the frequency f from the m-phase clocks of the frequency f to provide single-phase clocks of a desired frequency.
    • 时钟转换电路(1)接收并且将具有1 /(fxm)相位差的频率f的m相时钟转换成具有1 /(fxn)相位差的频率f的n相时钟。 单相时钟发生电路(2)接收具有1 /(fxn)的相位差等效时间的频率f的n相时钟,以产生与n频率的上升沿或下降沿同步的单相时钟。 相位时钟。 由于输入到时钟转换电路(1)的m相时钟的频率为'f',所以如果确定了单相时钟的期望频率,则可以从下列公式得到'n':频率 单相时钟等于(fxn)。 该值“n”被设置为时钟转换电路(1),从而从频率f的m相时钟获得频率f的n相时钟,以提供期望频率的单相时钟。
    • 3. 发明授权
    • Clock generating circuit and clock generating method
    • 时钟发生电路和时钟发生方法
    • US08242814B2
    • 2012-08-14
    • US11575168
    • 2005-09-16
    • Koichi NoseMasayuki MizunoAtsufumi Shibayama
    • Koichi NoseMasayuki MizunoAtsufumi Shibayama
    • H03B19/00
    • H03K5/00006G06F1/06H03K5/13H03K5/1565H03K2005/00052H03L7/07H03L7/0814
    • A clock converting circuit (1) receives and then converts m-phase clocks of a frequency f having a phase difference of 1/(f×m) to n-phase clocks of the frequency f having a phase difference of 1/(f×n). A single-phase clock generating circuit (2) receives the n-phase clocks of the frequency f having a phase difference equivalent time of 1/(f×n) to generate single-phase clocks in synchronism with the rising or falling edges of the n-phase clocks. Since the frequency of the m-phase clocks inputted to the clock converting circuit (1) is ‘f’, if a desired frequency of the single-phase clocks is decided, then ‘n’ can be obtained from the equation: the frequency of the single-phase clocks is equal to (f×n). This value of ‘n’ is set to the clock converting circuit (1), thereby obtaining the n-phase clocks of the frequency f from the m-phase clocks of the frequency f to provide single-phase clocks of a desired frequency.
    • 时钟转换电路(1)接收并将具有1 /(f×m)相位差的频率f的m相时钟转换为相位差为1 /(f×m)的频率f的n相时钟 n)。 单相时钟发生电路(2)接收具有1 /(f×n)的相位差当量时间的频率f的n相时钟,以产生与相位差等效时间的上升沿或下降沿同步的单相时钟 n相时钟。 由于输入到时钟转换电路(1)的m相时钟的频率为'f',所以如果确定了单相时钟的期望频率,那么可以从以下等式获得“n”:频率 单相时钟等于(f×n)。 该值“n”被设置为时钟转换电路(1),从而从频率f的m相时钟获得频率f的n相时钟,以提供期望频率的单相时钟。
    • 5. 发明授权
    • Clock signal dividing circuit
    • 时钟信号分频电路
    • US07893742B2
    • 2011-02-22
    • US12514115
    • 2007-10-26
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • H03L7/00
    • G06F1/10H03K23/507H03L7/0814H03L7/16
    • A clock signal dividing circuit in which a dividing ratio is regulated by N/M (M and N are positive integers and satisfy M>N) includes: a variable delay circuit which gives a predetermined delay amount based on a control value to an input clock signal CKI to output an output clock signal CKO; and a variable delay control circuit which cumulatively adds values obtained by subtracting N from M every cycle of the input clock signal CKI, when the addition result is N or more, performs a calculation which subtracts N from the addition result to obtain a calculation result K, and calculates, to a maximum delay amount in the variable delay circuit corresponding to one cycle of the input clock signal CKI, a control value corresponding to a delay amount of K/N of the maximum delay amount to give the control value to the variable delay circuit.
    • 分频比由N / M(M和N是正整数,满足M> N)调节的时钟信号分频电路包括:可变延迟电路,其基于对输入时钟的控制值给出预定的延迟量 信号CKI输出输出时钟信号CKO; 以及可变延迟控制电路,当相加结果为N以上时,累积地将通过从输入时钟信号CKI的每个周期从M中减去N而获得的值执行从相加结果中减去N的计算,以获得计算结果K ,并且将对应于输入时钟信号CKI的一个周期的可变延迟电路中的最大延迟量计算为与最大延迟量的K / N的延迟量相对应的控制值,以将控制值赋予该变量 延时电路。
    • 6. 发明授权
    • Semiconductor device and communication control method
    • 半导体器件和通信控制方法
    • US07702945B2
    • 2010-04-20
    • US11575473
    • 2005-09-16
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • G06F1/04
    • H04L7/0012G06F1/12H04L7/0041
    • The present invention relates to a technique capable of establishing communications between cores, which can provide a large degree of freedom of clock frequencies settable in each core, and thus providing deterministic operation, small communication latency, and high reliability. An object of the present invention is to provide a semiconductor device with high reliability, by analyzing factors affecting the performance of the semiconductor device, based on the communication histories within the semiconductor device, and reflecting the analysis back to the next generation semiconductor devices. The improved semiconductor device includes a core A for transmitting data in sync with the clock signal clkA, a core B for receiving data in sync with the clock signal clkB coincided with the rising or falling of the clock signal clkA in a constant period, and a controller for controlling communications between the core A and the core B. The controller controls in such way that the core B can receive only the data arriving prior to the setup of the clock signal clkB. The controller stores the history on a communication status between cores.
    • 本发明涉及能够建立核之间的通信的技术,其能够提供可在每个核心中设置的时钟频率的大的自由度,从而提供确定性的操作,小的通信延迟和高的可靠性。 本发明的目的是通过基于半导体器件内的通信历史分析影响半导体器件的性能的因素,并将分析反映到下一代半导体器件,来提供具有高可靠性的半导体器件。 改进的半导体器件包括用于与时钟信号clkA同步发送数据的核心A,用于接收与时钟信号clkB同步的数据的核心B与时钟信号clkA的上升或下降保持一致,并且 控制器用于控制核心A和核心B之间的通信。控制器以这样的方式进行控制,使得核心B可以仅接收在建立时钟信号clkB之前到达的数据。 控制器将历史记录存储在内核之间的通信状态。
    • 8. 发明申请
    • Semiconductor Device and Communication Control Method
    • 半导体器件与通信控制方法
    • US20080218225A1
    • 2008-09-11
    • US11575473
    • 2005-09-16
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • Atsufumi ShibayamaKoichi NoseMasayuki Mizuno
    • H03L7/00
    • H04L7/0012G06F1/12H04L7/0041
    • The present invention relates to a technique capable of establishing communications between cores, which can provide a large degree of freedom of clock frequencies settable in each core, and thus providing deterministic operation, small communication latency, and high reliability. An object of the present invention is to provide a semiconductor device with high reliability, by analyzing factors affecting the performance of the semiconductor device, based on the communication histories within the semiconductor device, and reflecting the analysis back to the next generation semiconductor devices. The improved semiconductor device includes a core A for transmitting data in sync with the clock signal clkA, a core B for receiving data in sync with the clock signal clkB coincided with the rising or falling of the clock signal clkA in a constant period, and a controller for controlling communications between the core A and the core B. The controller controls in such way that the core B can receive only the data arriving prior to the setup of the clock signal clkB. The controller stores the history on a communication status between cores.
    • 本发明涉及一种能够建立核之间的通信的技术,其能够提供可在每个核心中设置的时钟频率的大的自由度,从而提供确定性的操作,小的通信延迟和高的可靠性。 本发明的目的是通过基于半导体器件内的通信历史分析影响半导体器件的性能的因素,并将分析反映到下一代半导体器件,来提供具有高可靠性的半导体器件。 改进的半导体器件包括用于与时钟信号clkA同步发送数据的核心A,用于接收与时钟信号clkB同步的数据的核心B与时钟信号clkA的上升或下降保持一致,并且 控制器用于控制核心A和核心B之间的通信。控制器以这样的方式进行控制,使得核心B可以仅接收在建立时钟信号clkB之前到达的数据。 控制器将历史记录存储在内核之间的通信状态。
    • 9. 发明授权
    • Clock signal frequency dividing circuit and clock signal frequency dividing method
    • 时钟信号分频电路和时钟信号分频方式
    • US08081017B2
    • 2011-12-20
    • US12515901
    • 2007-11-09
    • Atsufumi ShibayamaKoichi Nose
    • Atsufumi ShibayamaKoichi Nose
    • H03K21/00
    • H03K23/48G06F1/08H03K23/667
    • To provide a rational frequency dividing circuit wherein the variations in cycle times of frequency divided clock signals are small, there are many occasions in which the minimum cycle time of frequency divided clock signals and test costs are small. A clock signal frequency dividing circuit, the frequency division ratio of which is specified as N/M where are both N and M are integers, includes an output clock selecting circuit (200) that selects one of three situations: an input clock signal is outputted as it is, the input clock signal is inverted and outputted and the input clock signal is not outputted; and a clock selection control circuit (100) that generates a control signal for controlling the foregoing selection of the output clock selecting circuit. The clock selection control circuit controls the foregoing selection of the output clock selecting circuit at every cycle of the input clock signal.
    • 为了提供一种合理的分频电路,其中分频时钟信号的周期时间的变化小,在分频时钟信号和测试成本的最小周期时间很少的场合很多。 其分频比被指定为N / M的时钟信号分频电路都是N和M都是整数,包括选择三种情况之一的输出时钟选择电路(200):输出输入时钟信号 输入时钟信号被反相输出,不输出输入时钟信号; 以及时钟选择控制电路(100),其产生用于控制输出时钟选择电路的上述选择的控制信号。 时钟选择控制电路在输入时钟信号的每个周期控制输出时钟选择电路的上述选择。
    • 10. 发明申请
    • CLOCK SIGNAL FREQUENCY DIVIDING CIRCUIT AND CLOCK SIGNAL FREQUENCY DIVIDING METHOD
    • 时钟信号分频电路和时钟信号频分法
    • US20100052740A1
    • 2010-03-04
    • US12515901
    • 2007-11-09
    • Atsufumi ShibayamaKoichi Nose
    • Atsufumi ShibayamaKoichi Nose
    • H03B19/00
    • H03K23/48G06F1/08H03K23/667
    • To provide a rational frequency dividing circuit wherein the variations in cycle times of frequency divided clock signals are small, there are many occasions in which the minimum cycle time of frequency divided clock signals and test costs are small. A clock signal frequency dividing circuit, the frequency division ratio of which is specified as N/M where are both N and Mare integers, includes an output clock selecting circuit (200) that selects one of three situations: an input clock signal is outputted as it is, the input clock signal is inverted and outputted and the input clock signal is not outputted; and a clock selection control circuit (100) that generates a control signal for controlling the foregoing selection of the output clock selecting circuit. The clock selection control circuit controls the foregoing selection of the output clock selecting circuit at every cycle of the input clock signal.
    • 为了提供一种合理的分频电路,其中分频时钟信号的周期时间的变化小,在分频时钟信号和测试成本的最小周期时间很少的场合很多。 其分频比被指定为N / M的时钟信号分频电路均为N和Mare整数,包括选择三种情况之一的输出时钟选择电路(200):输入时钟信号作为 输入时钟信号被反相输出,输入时钟信号不输出; 以及时钟选择控制电路(100),其生成用于控制输出时钟选择电路的上述选择的控制信号。 时钟选择控制电路在输入时钟信号的每个周期控制输出时钟选择电路的上述选择。