公开(公告)号：US10062629B2

公开(公告)日：2018-08-28

申请号：US14931720

申请日：2015-11-03

Applicant: RF Micro Devices, Inc.

Inventor： George Maxim ,  Dirk Robert Walter Leipold ,  Marcus Granger-Jones ,  Baker Scott

IPC: H03H7/38 ,  H01L23/31 ,  H01L21/304 ,  H01L21/02 ,  H01L21/683 ,  H01L23/29 ,  H01L23/373 ,  H01L23/00 ,  H05K1/02 ,  H05K1/18 ,  H01Q1/50 ,  H01L23/36 ,  H01L21/56 ,  H01L23/20 ,  H01L23/367 ,  H01L21/306 ,  H01L23/522 ,  H01L49/02

CPC classification number: H01L23/315 ,  H01L21/02266 ,  H01L21/02282 ,  H01L21/304 ,  H01L21/30604 ,  H01L21/565 ,  H01L21/6835 ,  H01L23/20 ,  H01L23/291 ,  H01L23/293 ,  H01L23/3121 ,  H01L23/3135 ,  H01L23/36 ,  H01L23/367 ,  H01L23/3731 ,  H01L23/3737 ,  H01L23/5223 ,  H01L23/5227 ,  H01L23/5228 ,  H01L23/562 ,  H01L24/17 ,  H01L28/10 ,  H01L28/20 ,  H01L28/40 ,  H01L2221/68327 ,  H01L2221/6834 ,  H01L2221/68381 ,  H01L2224/131 ,  H01L2224/13147 ,  H01L2224/16225 ,  H01L2224/16227 ,  H01L2224/73204 ,  H01L2224/92125 ,  H01L2924/0002 ,  H01L2924/19011 ,  H01L2924/19041 ,  H01L2924/19042 ,  H01L2924/19043 ,  H01Q1/50 ,  H05K1/0203 ,  H05K1/181 ,  H01L2924/00 ,  H01L2924/014 ,  H01L2924/00014

Abstract: Antenna aperture tuning circuitry includes a first signal path and a second signal path coupled in parallel between an antenna radiating element and ground. A first LC resonator and a second LC resonator are each coupled between the first signal path and ground. The first LC resonator and the second LC resonator are electromagnetically coupled such that a coupling factor between the first LC resonator and the second LC resonator is between about 1.0% and 40.0%. A third LC resonator and a fourth LC resonator are each coupled between the second signal path and ground. The third LC resonator and the fourth LC resonator are electromagnetically coupled such that a coupling factor between the third LC resonator and the fourth LC resonator is between about 1.0% and 40.0%.

公开(公告)号：US09893709B2

公开(公告)日：2018-02-13

申请号：US14673192

申请日：2015-03-30

Applicant: RF Micro Devices, Inc.

Inventor： Nadim Khlat ,  Marcus Granger-Jones

IPC: H03H7/46 ,  H03H9/70 ,  H03H7/01 ,  H01P5/22 ,  H03H9/72 ,  H04B1/525 ,  H04B1/58

CPC classification number: H03H7/46 ,  H01P5/22 ,  H01P5/227 ,  H03H7/0138 ,  H03H7/463 ,  H03H9/706 ,  H03H9/725 ,  H04B1/525 ,  H04B1/58

Abstract: RF circuitry, which includes a first hybrid RF coupler, a second hybrid RF coupler, a third hybrid RF coupler, and RF filter circuitry, is disclosed. The first hybrid RF coupler provides a first main port, a first pair of quadrature ports, and an isolation port. The second hybrid RF coupler provides a second main port and a second pair of quadrature ports. The third hybrid RF coupler provides a third main port and a third pair of quadrature ports. RF filter circuitry is coupled to the first pair of quadrature ports, the second pair of quadrature ports, and the third pair of quadrature ports. The first main port, the second main port, and the third main port provide main ports of the RF triplexer. The isolation port is a common port of the RF triplexer for coupling to an RF antenna.

公开(公告)号：US09735850B2

公开(公告)日：2017-08-15

申请号：US15084142

申请日：2016-03-29

Applicant: RF Micro Devices, Inc.

Inventor： Nadim Khlat ,  Marcus Granger-Jones

IPC: H04B1/44 ,  H04B7/06 ,  H04B1/00 ,  H04B1/401

CPC classification number: H04B7/0608 ,  H04B1/0053 ,  H04B1/0064 ,  H04B1/0458 ,  H04B1/18 ,  H04B1/401 ,  H04B7/0602 ,  H04B7/0802

Abstract: Antenna swapping circuitry includes a first pole, a second pole, a first throw, a second throw, and a number of switching elements. A first switching element is coupled between the first pole and the first throw. A second switching element is coupled between the first pole and the second throw. A third switching element is coupled between the second pole and the first throw. A fourth switching element is coupled between the second pole and the second throw. A linearity of the first switching element and the fourth switching element is higher in a closed state of operation than in an open state of operation. A linearity of the second switching element and a third switching element is higher in an open state of operation than in a closed state of operation.

公开(公告)号：US09729191B2

公开(公告)日：2017-08-08

申请号：US14659314

申请日：2015-03-16

Applicant: RF Micro Devices, Inc.

Inventor： Nadim Khlat ,  Marcus Granger-Jones

IPC: H04L5/00 ,  H04B1/525

CPC classification number: H04B1/525

Abstract: RF circuitry, which includes a first hybrid RF coupler, a second hybrid RF coupler, and a third hybrid RF coupler, is disclosed. The first hybrid RF coupler is coupled to a first RF antenna. The second hybrid RF coupler is configured to receive a first lowband RF receive signal via the first RF antenna. The first hybrid RF coupler is configured to receive one of a first midband RF receive signal and a first highband RF receive signal via the first RF antenna. The third hybrid RF coupler configured to receive another of the first midband RF receive signal and the first highband RF receive signal via the first RF antenna.

公开(公告)号：US09602146B2

公开(公告)日：2017-03-21

申请号：US14611850

申请日：2015-02-02

Applicant: RF Micro Devices, Inc.

Inventor： Marcus Granger-Jones ,  Nadim Khlat

IPC: H04B1/00 ,  H04L5/14 ,  H04L5/00

CPC classification number: H04B1/0057 ,  H04B1/006 ,  H04L5/001 ,  H04L5/0023 ,  H04L5/14

Abstract: RF front end circuitry includes mid/high-band switching circuitry and a carrier-aggregation diplexer. The mid/high-band switching circuitry is configured to receive and selectively route mid-band and high-band signals between a mid/high-band output port and a number of mid/high-band transceiver ports. The carrier-aggregation diplexer is coupled to a first one of the mid/high-band transceiver ports. Further, the carrier-aggregation diplexer is configured to pass mid-band signals between a mid-band diplexer port and the first one of the mid/high-band transceiver ports while attenuating other signals, and pass high-band signals between a high-band diplexer port and the first one of the mid/high-band transceiver ports while attenuating other signals.

公开(公告)号：US20170005385A1

公开(公告)日：2017-01-05

申请号：US15010829

申请日：2016-01-29

Applicant: RF Micro Devices, Inc.

Inventor： Nadim Khlat ,  Marcus Granger-Jones

IPC: H01P1/15 ,  H01P1/213

CPC classification number: H03H19/002 ,  H03H7/465 ,  H03H2250/00 ,  H04B1/006

Abstract: This disclosure relates to radio frequency (RF) front end circuitry used to route RF signals. In one embodiment, the RF front end circuitry has a filter circuit and a switch device. The switch device includes a common port, an RF port, and switchable path connected in series between the common port and the RF port. The switch device is configured to present approximately the filter capacitance of the filter circuit at the common port when the switchable path is closed. However, when the switchable path is open, the switch device is configured to present a device capacitance at the common port that is approximately equal to the filter capacitance of the filter circuit. In this manner, if the common port is connected to an antenna, the capacitance seen by the antenna from the common port remains substantially unchanged regardless of which of the switchable path is opened or closed.

Abstract translation: 本公开涉及用于路由RF信号的射频（RF）前端电路。 在一个实施例中，RF前端电路具有滤波器电路和开关装置。 开关装置包括在公共端口和RF端口之间串联连接的公共端口，RF端口和可切换路径。 开关装置被配置为当可切换路径闭合时，在公共端口处大致呈现滤波器电路的滤波电容。 然而，当可切换路径打开时，开关装置被配置为在公共端口处呈现近似等于滤波器电路的滤波器电容的器件电容。 以这种方式，如果公共端口连接到天线，则天线从公共端口看到的电容保持基本上不变，而不管可切换路径中哪一个被打开或关闭。

公开(公告)号：US20160336972A1

公开(公告)日：2016-11-17

申请号：US15083791

申请日：2016-03-29

Applicant: RF Micro Devices, Inc.

Inventor： Nadim Khlat ,  Marcus Granger-Jones

IPC: H04B1/00 ,  H04B7/04

CPC classification number: H04B1/006 ,  H04B1/3805 ,  H04B1/48 ,  H04B7/0602 ,  H04B7/0805

Abstract: RF front end circuitry includes primary transceiver circuitry associated with a primary antenna and secondary receiver circuitry associated with a secondary antenna. Generally, the primary transceiver circuitry and the primary antenna are located on one end of a mobile communications device, while the secondary receiver circuitry and the secondary antenna are located at an opposite end of the device. Cross-coupling connection lines run between the antenna switching circuitry for the primary antenna and the secondary antenna, and are reused to send a portion of primary RF transmit signals from the primary transceiver circuitry to the secondary receiver circuitry so that primary RF transmit signals coupled into the secondary receiver path via antenna-to-antenna coupling can be reduced.

Abstract translation: RF前端电路包括与主天线相关联的主收发器电路和与辅助天线相关联的辅助接收器电路。 通常，主收发器电路和主天线位于移动通信设备的一端，而辅助接收器电路和辅助天线位于设备的相对端。 交叉耦合连接线在用于主天线的天线切换电路和次天线之间运行，并且被重用以将主要RF发射信号的一部分从主收发器电路发送到次级接收机电路，使得主RF发射信号耦合到 可以减少通过天线到天线耦合的次级接收机路径。

公开(公告)号：US20160126007A1

公开(公告)日：2016-05-05

申请号：US14929608

申请日：2015-11-02

Applicant: RF Micro Devices, Inc.

Inventor： Dirk Robert Walter Leipold ,  George Maxim ,  Marcus Granger-Jones ,  Baker Scott

IPC: H01F27/28 ,  H01F27/29

CPC classification number: H01F27/2804 ,  H01F2027/2809 ,  H01L21/0276 ,  H01L28/10 ,  H01P7/06 ,  H01P7/065 ,  H01P7/08 ,  H03H7/38 ,  H03H7/463 ,  H03H9/24 ,  H04B1/40 ,  H04J1/08

Abstract: Embodiments of an apparatus are disclosed that includes a first three dimensional (3D) inductor and a second 3D inductor. The first three dimensional (3D) inductor has a first conductive path shaped as a first two dimensional (2D) lobe laid over a first 3D volume. In addition, the second 3D inductor has a second conductive path, wherein the second 3D inductor is inserted into the first 3D inductor so that the second conductive path at least partially extends through the first 3D volume. Since second 3D inductor is inserted into the first 3D inductor, the 3D inductors may be coupled to one another. Depending on orientation and distances of structures provided by the 3D inductors, the 3D inductors may be weakly or moderately coupled.

Abstract translation: 公开了一种包括第一三维（3D）电感器和第二3D电感器的装置的实施例。 第一三维（3D）电感器具有第一导电路径，其形状设置在第一3D体积上的第一二维（2D）波瓣。 另外，第二3D电感器具有第二导电路径，其中第二3D电感器被插入到第一3D电感器中，使得第二导电路径至少部分地延伸穿过第一3D体积。 由于第二3D电感器被插入到第一3D电感器中，所以3D电感器可以彼此耦合。 根据由3D电感器提供的结构的取向和距离，3D电感可能会弱或适度耦合。

公开(公告)号：US09294067B2

公开(公告)日：2016-03-22

申请号：US13668743

申请日：2012-11-05

Applicant: RF Micro Devices, Inc.

Inventor： Michael F. Zybura ,  Marcus Granger-Jones

IPC: H02M1/12 ,  H01F21/00 ,  H03H7/42 ,  H03H7/01 ,  H03H7/09

CPC classification number: H03H7/42 ,  H03H7/0115 ,  H03H7/09 ,  H03H7/1775

Abstract: In one embodiment, a balanced to unbalanced transformer utilizes a crossover configuration such that some portion of the secondary coil (inductor) is shared between two resonators (capacitors). Adding a first capacitor in parallel with a portion of the secondary inductor creates a first harmonic trap (filter), and also efficiently uses the secondary coil (inductor) as a resonating element.Adding a second capacitor which shares (crossover configuration) a portion of the secondary inductor with the first capacitor creates a second harmonic trap (filter), which may be tuned to the same harmonic as the first harmonic trap, or may be tuned to a different harmonic.

Abstract translation: 在一个实施例中，平衡到不平衡变压器利用交叉配置，使得次级线圈（电感器）的某些部分在两个谐振器（电容器）之间共享。 添加与次级电感器的一部分并联的第一电容器产生第一谐波陷波器（滤波器），并且还有效地使用次级线圈（电感器）作为谐振元件。 使用第一电容器添加共享（交叉配置）次级电感器的一部分的第二电容器产生二次谐波陷波器（滤波器），其可以调谐到与第一谐波陷波器相同的谐波，或者可以被调谐到不同的 谐波。

公开(公告)号：US09209784B2

公开(公告)日：2015-12-08

申请号：US13922337

申请日：2013-06-20

Applicant: RF Micro Devices, Inc.

Inventor： Christian Rye Iversen ,  Marcus Granger-Jones

IPC: H03L5/00 ,  H01P1/22 ,  H03H21/00 ,  H03K17/10

CPC classification number: H03H21/0007 ,  H03K17/102

Abstract: Switchable capacitive elements are disclosed, along with programmable capacitor arrays (PCAs). One embodiment of the switchable capacitive element includes a field effect transistor (FET) device stack, a first capacitor, and a second capacitor. The FET device stack is operable in an open state and in a closed state and has a plurality of FET devices coupled in series to form the FET device stack. The first capacitor and the second capacitor are both coupled in series with the FET device stack. However, the first capacitor is coupled to a first end of the FET device stack while the second capacitor is coupled to a second end opposite the first end of the FET device stack. In this manner, the switchable capacitive element can be operated without a negative charge pump, with decreased bias swings, and with a better power performance.

Abstract translation: 公开了可切换电容元件以及可编程电容器阵列（PCA）。 可切换电容元件的一个实施例包括场效应晶体管（FET）器件堆叠，第一电容器和第二电容器。 FET器件堆栈可在打开状态和关闭状态下工作，并且具有串联耦合以形成FET器件堆叠的多个FET器件。 第一电容器和第二电容器都与FET器件堆叠串联耦合。 然而，第一电容器耦合到FET器件堆叠的第一端，而第二电容器耦合到与FET器件堆叠的第一端相对的第二端。 以这种方式，可切换的电容元件可以在没有负电荷泵的情况下操作，具有减小的偏置摆动以及更好的功率性能。