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    • 2. 发明授权
    • Integration circuit
    • 集成电路
    • US4278943A
    • 1981-07-14
    • US920343
    • 1978-06-29
    • Eiji MasudaChikara SatoYasoji Suzuki
    • Eiji MasudaChikara SatoYasoji Suzuki
    • G06G7/186H03K5/00
    • G06G7/1865
    • An integration circuit comprises an operational amplifier with first and second input terminals and an output terminal, an integration capacitor connected between the first input terminal and the output terminal, an integration resistor connected at one end to the first input terminal, a switch connected at one end to the other end of said resistor, a voltage signal source to be integrated which is connected through the switch to the other end of the resistor, and a reference voltage signal source connected to the second input terminal. The integration circuit further comprises means which applies, at the same time as the switch is opened, a signal with the same potential as the signal derived from the reference voltage signal source to said other end of the resistor, thereby to prevent an output signal from being adversely affected by a parasitic capacitance of the switch.An integration method includes a first step for applying a voltage signal to be integrated to an input part of an integration circuit and a second step for stopping the application of the integration voltage signal to the input part, and further comprises a third step for applying a reference potential signal to the input part of the integration circuit at the same time as the voltage signal to be integrated stops.
    • 积分电路包括具有第一和第二输入端子的运算放大器和输出端子,连接在第一输入端子和输出端子之间的积分电容器,一端连接到第一输入端子的积分电阻器, 结束到所述电阻器的另一端,要被集成的电压信号源,其通过开关连接到电阻器的另一端,以及参考电压信号源连接到第二输入端子。 积分电路还包括在与开关同时打开具有与从参考电压信号源导出到电阻器的另一端的信号相同的电位的信号的装置,从而防止输出信号 受到开关寄生电容的不利影响。 积分方法包括:第一步骤,将要积分的电压信号施加到积分电路的输入部分;以及第二步骤,用于停止向输入部分施加积分电压信号,并且还包括第三步骤, 与要积分的电压信号同时停止对积分电路的输入部分的参考电位信号。
    • 3. 发明授权
    • Analog-to-digital converter
    • US4243975A
    • 1981-01-06
    • US945641
    • 1978-09-25
    • Eiji MasudaYasoji Suzuki
    • Eiji MasudaYasoji Suzuki
    • H03M1/52H03M1/00H03K13/20
    • H03M1/183H03M1/52
    • A first reference voltage, a second reference voltage and an unknown analog signal with the same polarity with respect to that of the first reference voltage are applied in a given sequence to the second input of an integrator whose first input is supplied with a voltage which is half the difference between the first and second reference voltages. The output of the integrator is coupled with the second input of a comparator whose first input is supplied with a medium voltage between the second reference voltage and the input voltage at the first input of the integrator as a comparing reference voltage. At the beginning of conversion, the integrator initiates integration from the comparing reference voltage level. During first and second periods each having a given duration, the second reference voltage and the unknown analog signal are sequentially applied to the second input of the integrator. During a third period, the first reference voltage is applied to the second input of the integrator. A first counter counts clock pulses with a given frequency during the third period to thereby provide a digital value corresponding to the unknown analog signal. When the magnitude of the unknown analog signal is slightly smaller than the first reference voltage and when it is slightly larger than the second reference voltage, a digital value corresponding to the difference between the magnitudes of the unknown analog signal and the reference voltage is measured by a second counter. In another embodiment of the invention, one calibration cycle is executed for a series of conversion cycles of unknown analog signals. In the calibration cycle, a digital value, which includes an error due to an input offset voltage of the integrator, corresponding to the first of second reference voltage, is measured. The measured digital value of each unknown analog signal is calibrated depending on the difference between the measured digital value for a reference voltage including the error and a known correct digital value for the reference voltage.
    • 4. 发明授权
    • Voltage transfer circuit and a booster circuit, and an IC card
comprising the same
    • 电压传输电路和升压电路,以及包括该电路的IC卡
    • US06046626A
    • 2000-04-04
    • US3946
    • 1998-01-08
    • Yukihiro SaekiYasoji Suzuki
    • Yukihiro SaekiYasoji Suzuki
    • G11C11/413G06K19/07G11C11/407G11C16/06H02M3/07H03K19/0948G05F3/02
    • H02M3/073
    • A voltage transfer circuit comprises a first MOS transistor of a first channel type having a drain terminal connected to a first node supplied with a predetermined voltage, a source terminal connected to a second node, and a gate terminal, a second MOS transistor of a first channel type having a source terminal connected to the second node, a drain terminal connected to the gate terminal of the first MOS transistor, and a gate terminal supplied with a clock signal, as well as a third MOS transistor of a second channel type having a drain terminal connected to the drain terminal of the second MOS transistor, a source terminal connected to a third node supplied with a reference voltage, and a gate terminal supplied with the clock signal.
    • 电压传输电路包括第一通道类型的第一MOS晶体管,其具有连接到被提供有预定电压的第一节点的漏极端子,连接到第二节点的源极端子和栅极端子,第一MOS晶体管的第一 沟道型,具有连接到第二节点的源极端子,连接到第一MOS晶体管的栅极端子的漏极端子和提供有时钟信号的栅极端子,以及具有第二沟道类型的第三MOS晶体管,其具有 漏极端子连接到第二MOS晶体管的漏极端子,连接到提供有参考电压的第三节点的源极端子和被提供有时钟信号的栅极端子。
    • 6. 发明授权
    • Complementary MOSFET logic circuit
    • 互补MOSFET逻辑电路
    • US4558234A
    • 1985-12-10
    • US652429
    • 1984-09-20
    • Yasoji SuzukiKenji Matsuo
    • Yasoji SuzukiKenji Matsuo
    • H03K19/017H03K19/0175H03K19/0944H03K19/092H03K19/003H03K19/01H03K19/094
    • H03K19/09448H03K19/01721H03K19/017518
    • Disclosed is a complementary MOSFET logic circuit having a complementary MOS inverter with a pregiven ratio of the channel widths of a P channel MOSFET and an N channel MOSFET and pregiven threshold voltages of the FETs so as to have an input voltage characteristic adapted to an output voltage characteristic, and a buffer circuit which includes a bipolar transistor for receiving at the base thereof a signal from the output terminal of the complementary MOS inverter and an N channel MOSFET for receiving at the gate thereof an input signal applied to the complementary MOS inverter. The inverter and buffer are connected in series to one another between a high potential applying point and a low potential applying point, and a signal corresponding to a logic output signal of the complementary MOS inverter is produced at the output terminal thereof.
    • 公开了具有互补MOS反相器的互补MOSFET逻辑电路,其具有P沟道MOSFET和N沟道MOSFET的沟道宽度的预制比和FET的预定阈值电压,以便具有适于输出电压的输入电压特性 特性和缓冲电路,其包括用于在其基极处接收来自互补MOS反相器的输出端的信号的双极晶体管和用于在其栅极处接收施加到互补MOS反相器的输入信号的N沟道MOSFET。 反相器和缓冲器在高电位施加点和低电位施加点之间彼此串联连接,并且在其输出端产生与互补MOS反相器的逻辑输出信号相对应的信号。
    • 9. 发明授权
    • Basic circuit for electronic timepieces
    • 电子钟表基本电路
    • US4264968A
    • 1981-04-28
    • US864714
    • 1977-12-27
    • Yasoji SuzukiFuminari TanakaYasushi Sato
    • Yasoji SuzukiFuminari TanakaYasushi Sato
    • G01R19/00G04G3/02G04G9/00G04G99/00G04C3/00
    • G04G99/00G04G3/022
    • There is provided an electronic timepiece basic circuit comprising a pulse generating circuit for generating 1 Hz pulses, a first terminal group having a plurality of terminals including a terminal connected to the output terminal of the pulse generating circuit, a second terminal group having terminals to be connected to the terminals of the first terminal group, respectively, 10 scale counters coupled with the second terminal group, 6 scale counters connected to the 10 scale counters, a display unit, and a decoder which is coupled with the 10 scale counters and the 6 scale counters and decodes the contents of the 10 and 6 scale counters and delivers the decoded contents to the display unit. The first and second terminal groups are properly coupled to each other. The combination of the 10 scale counters and the 6 scale counters is properly modified so as to form a 12, 24, or 60 scale counter, as necessary.
    • 提供了一种电子钟表基本电路,包括用于产生1Hz脉冲的脉冲发生电路,具有包括连接到脉冲发生电路的输出端的端子的多个端子的第一端子组,具有端子的第二端子组 分别连接到第一终端组的终端,与第二终端组耦合的10个比例计数器,连接到10个比例计数器的6个比例计数器,显示单元和与10个比例计数器耦合的解码器,6 缩放计数器并解码10和6比例计数器的内容,并将解码的内容传送到显示单元。 第一和第二端子组彼此适当地联接。 10个刻度计数器和6个刻度计数器的组合被适当修改,以便根据需要形成12个,24个或60个刻度计数器。
    • 10. 发明授权
    • Voltage sense circuit
    • 电压检测电路
    • US4255678A
    • 1981-03-10
    • US962221
    • 1978-11-20
    • Yasoji SuzukiKiyofumi OchiiHirozi Asahi
    • Yasoji SuzukiKiyofumi OchiiHirozi Asahi
    • G11C11/41G11C11/409G11C11/419H03K5/24G11C7/00
    • G11C11/419
    • A voltage sense circuit in which first and second parallel connections of complementary MOS transistors are connected between a pair of signal lines connected to memory cells and outputs of a flip-flop circuit for detecting a potential change of the signal line caused by data readout from an accessed memory cell. MOS transistors of one channel type in the parallel connections are adapted to precharge output node capacitors of the flip-flop circuit to a supply voltage level, while MOS transistors of the other channel type are adapted to couple complementary output voltage levels of the flip-flop circuit produced after the data readout and operation of the flip-flop circuit to the signal lines. Use of the parallel connections of complementary MOS transistors enables the application of a single power source for producing gate signals of these MOS transistors.
    • 一种电压检测电路,其中互补MOS晶体管的第一和第二并联连接在连接到存储单元的一对信号线之间,并且用于检测由数据读出引起的信号线的电位变化的触发器电路的输出 存取存储单元 并联连接中的一个通道类型的MOS晶体管适于将触发器电路的输出节点电容器预充电到电源电压电平,而另一个通道类型的MOS晶体管适于耦合触发器的互补输出电压电平 在触发电路的数据读出和操作到信号线之后产生的电路。 使用互补MOS晶体管的并联连接使得能够应用单个电源来产生这些MOS晶体管的栅极信号。