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    • 1. 发明申请
    • BAND CONTROL METHOD AND COMMUNICATION APPARATUS
    • 带控制方法和通信装置
    • US20090238206A1
    • 2009-09-24
    • US11910572
    • 2006-03-30
    • Yasuhiro HamadaKeiichi OhataKenichi MaruhashiTakao MorimotoMasaharu ItoShuya Kishimoto
    • Yasuhiro HamadaKeiichi OhataKenichi MaruhashiTakao MorimotoMasaharu ItoShuya Kishimoto
    • H04J3/22
    • H04L5/143H04B1/50H04J3/1694H04L5/0037
    • The present invention intends to improve communication efficiency between two communication apparatuses each engaged in the communication by full duplex communication method by using a surplus band of the one to transmission band of the other. A first bandwidth required by a first communication apparatus (A) at data transmission and a second bandwidth required by a second communication apparatus (B) at data transmission are presumed. Next, the first bandwidth presumed as mentioned is compared to a first bandwidth used which the first communication apparatus (A) currently uses and at the same time, the second bandwidth presumed as mentioned is compared to a second bandwidth used which the second communication apparatus (B) currently uses. The first bandwidth and the second bandwidth are then adjusted, and a third bandwidth which the first communication apparatus (A) uses at data transmission and a fourth bandwidth which the second communication apparatus (B) uses are determined.
    • 本发明旨在通过使用一个对另一个的传输频带的剩余频带来提高通过全双工通信方式进行通信的两个通信装置之间的通信效率。 推测第一通信装置(A)在数据传输时所需的第一带宽和第二通信装置(B)在数据传输时所需的第二带宽。 接下来,将所提到的假定的第一带宽与当前使用的第一通信装置(A)所使用的第一带宽进行比较,并且同时将假定的所述第二带宽与第二通信装置( B)目前使用。 然后调整第一带宽和第二带宽,并确定第一通信装置(A)在数据传输时使用的第三带宽和第二通信装置(B)使用的第四带宽。
    • 3. 发明授权
    • Band control method and communication apparatus
    • 频带控制方法和通信装置
    • US08045580B2
    • 2011-10-25
    • US11910572
    • 2006-03-30
    • Yasuhiro HamadaKeiichi OhataKenichi MaruhashiTakao MorimotoMasaharu ItoShuya Kishimoto
    • Yasuhiro HamadaKeiichi OhataKenichi MaruhashiTakao MorimotoMasaharu ItoShuya Kishimoto
    • H04J3/16
    • H04L5/143H04B1/50H04J3/1694H04L5/0037
    • The present invention intends to improve communication efficiency between two communication apparatuses each engaged in the communication by full duplex communication method by using a surplus band of the one to transmission band of the other. A first bandwidth required by a first communication apparatus (A) at data transmission and a second bandwidth required by a second communication apparatus (B) at data transmission are presumed. Next, the first bandwidth presumed as mentioned is compared to a first bandwidth used which the first communication apparatus (A) currently uses and at the same time, the second bandwidth presumed as mentioned is compared to a second bandwidth used which the second communication apparatus (B) currently uses. The first bandwidth and the second bandwidth are then adjusted, and a third bandwidth which the first communication apparatus (A) uses at data transmission and a fourth bandwidth which the second communication apparatus (B) uses are determined.
    • 本发明旨在通过使用一个对另一个的传输频带的剩余频带来提高通过全双工通信方式进行通信的两个通信装置之间的通信效率。 推测第一通信装置(A)在数据传输时所需的第一带宽和第二通信装置(B)在数据传输时所需的第二带宽。 接下来,将所提到的假定的第一带宽与当前使用的第一通信装置(A)所使用的第一带宽进行比较,并且同时将假定的所述第二带宽与第二通信装置( B)目前使用。 然后调整第一带宽和第二带宽,并确定第一通信装置(A)在数据传输时使用的第三带宽和第二通信装置(B)使用的第四带宽。
    • 4. 发明授权
    • Dielectric resonator, dielectric resonator frequency adjusting method, and dielectric resonator integrated circuit
    • 介质谐振器,介质谐振器频率调节方法和介质谐振器集成电路
    • US07378925B2
    • 2008-05-27
    • US10546587
    • 2004-02-23
    • Masaharu ItoKenichi MaruhashiShuya KishimotoKeiichi Ohata
    • Masaharu ItoKenichi MaruhashiShuya KishimotoKeiichi Ohata
    • H01P7/10
    • H01P7/00H01L2224/0554H01L2224/05568H01L2224/05573H01L2224/16227H01L2924/00014H01P7/10H03B5/1876H01L2224/05599H01L2224/0555H01L2224/0556
    • An oscillator comprising a dielectric resonator (DR) has a high controllability and reproducibility of coupling between the dielectric resonator (DR) and an oscillation circuit, and an integrated circuit is reduced in size. The dielectric resonator (DR) (1) is composed of a dielectric substrate (2), grounding conductive layers (3a, 3b) formed on both sides of the dielectric substrate (2), and via holes (4a) for electrical connection between the conductive layers. A coupling element (7a) composed of a slot (5a) provided in the central portion of the grounding conductive layer (3a) and a patch (6a) surrounded by the slot (5a) is coupled to the dielectric resonator (DR) (1). The patch (6a) is connected to a transmission line (13a) on an oscillation circuit (9) through a bump (8). The transmission line (13a) is connected to the ground through a termination resistor (15a). On the oscillation circuit MMIC (9), the transmission line (13a) is connected to the gate of a transistor FET (14) A capacitive transmission line (13a) for positive feedback is connected to the transistor FET (14). The output of the transistor FET (14) is connected to a transmission line (13c) for output through a matching circuit (16). The transmission line (13c) is bump-connected to a coplanar line (12a) composed of a signal conductive layer (11a) formed on an edge of the dielectric resonator (DR) (1) and the grounding conductive layer (3a).
    • 包括介质谐振器(DR)的振荡器具有在介质谐振器(DR)和振荡电路之间的耦合的高可控性和再现性,并且集成电路的尺寸减小。 介质谐振器(DR)(1)由电介质基片(2),形成在电介质基片(2)的两侧的接地导电层(3a,3b)和用于电气的通孔 导电层之间的连接。 由设置在接地导电层(3a)的中心部分的槽(5a)和由槽(5a)围绕的贴片(6a)组成的耦合元件(7a)耦合到介质谐振器 (DR)(1)。 贴片(6a)通过凸块(8)连接到振荡电路(9)上的传输线(13a)。 传输线路(13a)通过终端电阻器(15A)连接到地面。 在振荡电路MMIC(9)上,传输线(13a)连接到晶体管FET(14)的栅极。用于正反馈的电容传输线(13a)连接到晶体管FET(14)。 晶体管FET(14)的输出端通过匹配电路(16)连接到传输线路(13c)以进行输出。 传输线(13c)凸起连接到由形成在介质谐振器(DR)(1)的边缘上的信号导电层(11a)和接地导电层(3)构成的共面线(12a) 一个)。
    • 5. 发明申请
    • Feeder waveguide and sector antenna
    • 馈线波导和扇形天线
    • US20060244671A1
    • 2006-11-02
    • US10556726
    • 2004-04-27
    • Keiichi OhataMasaharu ItoShuya KishimotoKenichi Maruhashi
    • Keiichi OhataMasaharu ItoShuya KishimotoKenichi Maruhashi
    • H01Q13/00
    • H01P1/15
    • In the sector antenna of the present invention, a feeder waveguide is formed that branches midway from a feeder port to each of a plurality of antennas. This feeder waveguide is formed from a waveguide tube and includes a main feeder line that extends from a waveguide that extends from the feeder port and branches in two directions, and branch feeder lines that each branch in two directions from the two ends of the main feeder line. Sector selection structures are provided for selectively shutting off each branch waveguide by effectively forming conductive walls for blocking the cross section of each of the branch waveguides at positions of each of the branch feeder lines that branch and extend from the main feeder line and from which each branch waveguide begins.
    • 在本发明的扇形天线中,形成了从馈线中途分支到多个天线中的馈电波导。 该馈线波导由波导管形成,并且包括从馈线端口延伸并在两个方向上分支的波导延伸的主馈线,以及分支馈线,其从主馈线的两端分支到两个方向 线。 提供了扇区选择结构,用于通过有效地形成导电壁来选择性地关闭每个分支波导,用于阻挡每个分支波导的横截面在从主馈线分支和延伸的每个分支馈线的位置, 分支波导开始。
    • 7. 发明申请
    • Dielectric resonator, dielectric resonator frequency adjusting method, and dielectric resonator integrated circuit
    • 介质谐振器,介质谐振器频率调节方法和介质谐振器集成电路
    • US20060152306A1
    • 2006-07-13
    • US10546587
    • 2004-02-23
    • Masaharu ItoKenichi MaruhashiShuya KishimotoKeiich Ohata
    • Masaharu ItoKenichi MaruhashiShuya KishimotoKeiich Ohata
    • H01P7/10
    • H01P7/00H01L2224/0554H01L2224/05568H01L2224/05573H01L2224/16227H01L2924/00014H01P7/10H03B5/1876H01L2224/05599H01L2224/0555H01L2224/0556
    • An oscillator comprising a dielectric resonator (DR) has a high controllability and reproducibility of coupling between the dielectric resonator (DR) and an oscillation circuit, and an integrated circuit is reduced in size. The dielectric resonator (DR) (1) is composed of a dielectric substrate (2), grounding conductive layers (3a, 3b) formed on both sides of the dielectric substrate (2), and via holes (4a) for electrical connection between the conductive layers. A coupling element (7a) composed of a slot (5a) provided in the central portion of the grounding conductive layer (3a) and a patch (6a) surrounded by the slot (5a) is coupled to the dielectric resonator (DR) (1). The patch (6a) is connected to a transmission line (13a) on an oscillation circuit (9) through a bump (8). The transmission line (13a) is connected to the ground through a termination resistor (15a). On the oscillation circuit MMIC (9), the transmission line (13a) is connected to the gate of a transistor FET (14) A capacitive transmission line (13a) for positive feedback is connected to the transistor FET (14). The output of the transistor FET (14) is connected to a transmission line (13c) for output through a matching circuit (16). The transmission line (13c) is bump-connected to a coplanar line (12a) composed of a signal conductive layer (11a) formed on an edge of the dielectric resonator (DR) (1) and the grounding conductive layer (3a).
    • 包括介质谐振器(DR)的振荡器具有在介质谐振器(DR)和振荡电路之间的耦合的高可控性和再现性,并且集成电路的尺寸减小。 介质谐振器(DR)(1)由电介质基片(2),形成在电介质基片(2)的两侧的接地导电层(3a,3b)和用于电气的通孔 导电层之间的连接。 由设置在接地导电层(3a)的中心部分的槽(5a)和由槽(5a)围绕的贴片(6a)组成的耦合元件(7a)耦合到介质谐振器 (DR)(1)。 贴片(6a)通过凸块(8)连接到振荡电路(9)上的传输线(13a)。 传输线路(13a)通过终端电阻器(15A)连接到地面。 在振荡电路MMIC(9)上,传输线(13a)连接到晶体管FET(14)的栅极。用于正反馈的电容传输线(13a)连接到晶体管FET(14)。 晶体管FET(14)的输出端通过匹配电路(16)连接到传输线路(13c)以进行输出。 传输线(13c)凸起连接到由形成在介质谐振器(DR)(1)的边缘上的信号导电层(11a)和接地导电层(3)构成的共面线(12a) 一个)。
    • 9. 发明授权
    • Dielectric waveguide filter with inductive windows and coplanar line coupling
    • 具有感应窗和共面线耦合的介质波导滤波器
    • US07196598B2
    • 2007-03-27
    • US10332348
    • 2001-07-06
    • Kenichi MaruhashiMasaharu ItoKeiichi Ohata
    • Kenichi MaruhashiMasaharu ItoKeiichi Ohata
    • H01P1/028
    • H01P1/2088
    • The present invention provides a filter exhibiting excellent filter characteristics and having less number of stages. A dielectric substrate (1) has one surface connected to a top conductor (2) and an opposite surface connected to a bottom conductor (3). A pair of rows of via-holes connecting together the top conductor (2) and the bottom conductor (3) are formed along the signal transfer direction. A slit (6) is formed in a portion of the top conductor (2) overlying the central resonator among a plurality of resonators. The slit (6) extends in a direction perpendicular to the signal transfer direction. Slits (7, 8) are formed in each of portions of the top conductor (2) overlying resonators disposed at both ends. A coplanar waveguide (9) mounted on the top conductor (2) is connected to the slit (7).
    • 本发明提供了具有优异的过滤特性并且具有较少级数的过滤器。 电介质基板(1)具有连接到顶部导体(2)的一个表面和连接到底部导体(3)的相反表面。 沿着信号传送方向形成一对连接在一起的顶部导体(2)和底部导体(3)的通孔。 在多个谐振器中的覆盖中心谐振器的顶部导体(2)的一部分中形成狭缝(6)。 狭缝(6)沿垂直于信号传送方向的方向延伸。 在位于两端的谐振器的顶部导体(2)的每个部分中形成狭缝(7,8)。 安装在顶部导体(2)上的共面波导(9)连接到狭缝(7)。
    • 10. 发明授权
    • Dielectric waveguide filter
    • 介质波导滤波器
    • US07170373B2
    • 2007-01-30
    • US10502782
    • 2003-01-31
    • Masaharu ItoKenichi MaruhashiKeiichi Ohata
    • Masaharu ItoKenichi MaruhashiKeiichi Ohata
    • H01P1/208H01P3/16
    • H01P1/2088H01P5/107
    • A conductive layer is formed on each of the upper and lower surfaces of a dielectric substrate, and the two conductive layers are connected by rows of via-holes that are formed which a spacing that is less than or equal to ½ of the wavelength in the dielectric substrate in the resonance frequency, whereby n stages of dielectric resonators and input/output waveguide structures are formed. If the number n of stages is assumed to be 3, the first-stage resonator and the second-stage resonator are coupled by an electromagnetic field by means of via-holes of a first spacing; the second-stage resonator and the third-stage resonator are coupled by an electromagnetic by means of via-holes of a second spacing, whereby a filter is formed. The input/output waveguide structure and the filter are coupled by an electromagnetic by means of via-holes of a fourth spacing. The first-stage resonator and the third-stage resonator are coupled by an electromagnetic field by means of via-holes of a third spacing.
    • 在电介质基板的上表面和下表面的每一个上形成导电层,并且两个导电层通过形成的行的通孔连接,所述通孔的间隔小于或等于 电介质基板的谐振频率,从而形成n级介质谐振器和输入/输出波导结构。 如果假设n个级数为3,则第一级谐振器和第二级谐振器通过电磁场通过第一间隔的通孔耦合; 第二级谐振器和第三级谐振器借助于具有第二间隔的通孔的电磁耦合,从而形成滤波器。 输入/输出波导结构和滤波器通过第四间隔通孔的电磁耦合。 第一级谐振器和第三级谐振器通过第三间隔的通孔由电磁场耦合。