公开(公告)号：US09967884B2

公开(公告)日：2018-05-08

申请号：US15271912

申请日：2016-09-21

Applicant: NETGEAR, INC.

Inventor： Joseph Amalan Arul Emmanuel ,  Peiman Amini

IPC: H04W72/04 ,  H04L12/44 ,  H04L12/26 ,  H04L12/733 ,  H04W4/02 ,  H04W24/08 ,  H04W36/30 ,  H04W36/36 ,  H04W24/06 ,  H04W40/12 ,  H04W84/18 ,  H04W84/12 ,  H04W24/04 ,  H04W72/08

CPC classification number: H04W72/0453 ,  H04L12/44 ,  H04L43/0888 ,  H04L43/0894 ,  H04L43/10 ,  H04L43/16 ,  H04L45/20 ,  H04W4/023 ,  H04W24/04 ,  H04W24/06 ,  H04W24/08 ,  H04W36/30 ,  H04W36/36 ,  H04W40/12 ,  H04W72/085 ,  H04W76/10 ,  H04W76/15 ,  H04W84/12 ,  H04W84/18

Abstract: A dedicated backhaul for whole home coverage variously applies optimization techniques, e.g. using the 5 GHz high band or low band as a dedicated backhaul; using the 2.4 GHz band as backup if the 5 GHz band fails to reach between nodes; using Ethernet when it is better than the 5 GHz and 2.4 GHz bands and it is available; and using a spanning tree protocol or a variant to avoid loops. The dedicated backhaul is used if the received signal strength indication (RSSI) of the dedicated channel is above a threshold. In embodiments, a daisy chain uses probe request contents to communicate hop count and link quality between the nodes by attempting to route directly if link quality is better than a defined threshold. For each extra hop, there must be some percentage gain over smaller hops. If the link is below some threshold, it is not used.

公开(公告)号：US09948326B2

公开(公告)日：2018-04-17

申请号：US15369677

申请日：2016-12-05

Applicant: Netgear, Inc.

Inventor： Joseph Amalan Arul Emmanuel ,  Peiman Amini ,  Chia-Wei Liu

IPC: H04W4/00 ,  H04B1/00 ,  H04W28/02 ,  H04W72/02 ,  H04W72/04 ,  H04W74/00 ,  H04L12/709 ,  H04L12/801 ,  H04W28/08 ,  H04L29/08 ,  H04L29/06 ,  H04W88/06 ,  H04W88/10 ,  H04W80/02 ,  H04W84/12

CPC classification number: H04B1/0053 ,  H04B1/005 ,  H04B1/0057 ,  H04L45/245 ,  H04L47/34 ,  H04L67/02 ,  H04L69/16 ,  H04W28/0215 ,  H04W28/0263 ,  H04W28/08 ,  H04W72/02 ,  H04W72/04 ,  H04W72/0453 ,  H04W72/0486 ,  H04W74/002 ,  H04W80/02 ,  H04W84/12 ,  H04W88/06 ,  H04W88/10

Abstract: Systems and methods for enabling a WLAN client to communicate simultaneously over more than one band at a time are described, where each client has at least one radio that is operational in each supported band. Load balancing based on traffic requirements optimizes the use of the multiple bands.

公开(公告)号：US09838827B2

公开(公告)日：2017-12-05

申请号：US14996161

申请日：2016-01-14

Applicant: NETGEAR, INC.

Inventor： Peiman Amini ,  Arms Yongyuth ,  Joseph Amalan Arul Emmanuel

IPC: H04W4/00 ,  H04B1/44 ,  H04W88/10 ,  H04W72/12 ,  H04L12/861 ,  H04W24/02 ,  H04W52/38 ,  H04W72/08 ,  H04W72/04 ,  H04L5/00 ,  H04L25/03 ,  H04W28/26 ,  H04W52/02 ,  H04B1/525 ,  H04W84/12 ,  H04L29/06 ,  H04L29/08 ,  H04W88/12

CPC classification number: H04W4/38 ,  H04B1/44 ,  H04B1/525 ,  H04L5/0055 ,  H04L25/03006 ,  H04L49/9005 ,  H04L69/28 ,  H04L69/323 ,  H04L69/324 ,  H04W24/02 ,  H04W28/26 ,  H04W52/0212 ,  H04W52/386 ,  H04W72/0453 ,  H04W72/082 ,  H04W72/1215 ,  H04W72/1247 ,  H04W84/12 ,  H04W88/10 ,  H04W88/12 ,  Y02B70/30 ,  Y02D70/00 ,  Y02D70/1262 ,  Y02D70/142 ,  Y02D70/144 ,  Y02D70/164 ,  Y02D70/166 ,  Y02D70/23 ,  Y02D70/40

Abstract: Techniques are disclosed for controlling, in a network device, multiple radio circuits operating in a same or similar frequency band and in close physical proximity. In some embodiments, the radio circuits operate on the same network protocol. The network device can include a coexistence controller coupled to the network circuits. According to some embodiments, the network circuits are each assigned a priority, and the coexistence controller can control operations among the network circuits by selectively adjusting one or more transmission operating parameters of a respective network circuit based on a plurality of operating criteria, which include each network circuit's priority. Among other benefits, the embodiments disclosed herein can increase wireless network bandwidth and reduce mobile device power consumption by providing coordination among the radio circuits so that the transmitting and receiving operations are performed in a way that they do not interfere with their respective antennas.

公开(公告)号：US09775164B2

公开(公告)日：2017-09-26

申请号：US14562493

申请日：2014-12-05

Applicant: NETGEAR, INC.

Inventor： Peiman Amini ,  Joseph Amalan Arul Emmanuel

IPC: H04W72/08 ,  H04W52/02 ,  H04W16/10 ,  H04W84/12 ,  H04W72/04

CPC classification number: H04W72/082 ,  H04W16/10 ,  H04W52/0212 ,  H04W72/0453 ,  H04W84/12 ,  Y02D70/142 ,  Y02D70/144 ,  Y02D70/162 ,  Y02D70/166 ,  Y02D70/26

Abstract: A method for selecting signal channel for a wireless networking device is provided. The method collects WLAN and non-WLAN interference information on the candidate channels. The method then determines a weighted grade for each of the candidate channels based on the collected WLAN and non-WLAN interference information. A channel is selected among the candidate channels based on the weighted grades. The method further adjusts WLAN transmit parameter of the wireless networking device based on the collected WLAN and non-WLAN interference information.

公开(公告)号：US09763117B2

公开(公告)日：2017-09-12

申请号：US14555511

申请日：2014-11-26

Applicant: Netgear, Inc.

Inventor： Peiman Amini ,  Joseph Amalan Arul Emmanuel ,  ShunLiang Yu

IPC: H04W24/02 ,  H04W72/04 ,  H04W8/22

CPC classification number: H04W24/02 ,  H04W8/22 ,  H04W72/0453

Abstract: The disclosure is related to a multi-band wireless station, e.g., a wireless access point, that includes more than one wireless radio in the same frequency band. The wireless station operates at multiple frequency bands, e.g., 2.4 GHz and 5 GHz. Further, the wireless station includes multiple radios in the same frequency band. For example, the wireless station can have two radios for the 5 GHz band—one for a low 5 GHz band and another for high 5 GHz band. If the client station is connecting to the 5 GHz band, it can either connect to the first sub-band or the second sub-band of the 5 GHz. The wireless station can decide the sub-band to which a particular client station has to be assigned based on a number of assignment attributes, e.g., client station attributes and the sub-band attributes.

公开(公告)号：US09590661B2

公开(公告)日：2017-03-07

申请号：US14242662

申请日：2014-04-01

Applicant: NETGEAR, Inc.

Inventor： Joseph Amalan Arul Emmanuel ,  Peiman Amini ,  Paul Nysen ,  Shun-Liang Yu ,  Chia-Wei Liu ,  Shahrokh Zardoshti ,  Gin Wang ,  Henry Chen

IPC: H04B1/00 ,  H04L27/26 ,  H04B1/04

CPC classification number: H04B1/005 ,  H04B1/0096 ,  H04B2001/0491 ,  H04L27/2672 ,  H04W84/12

Abstract: Various embodiments disclose systems and methods for employing a Sub1G signal (e.g. a signal in the range of approximately 500 Mhz or 800 mHz) for use with internal and/or external components of various user devices. The Sub1G region may provide a path loss advantage over traditional 2.4 and 5 Ghz systems because of the lower frequency in free-space path loss model. Sub 1G may also present less interference compared to 2.4 GHz (e.g., better QoS for applications such as VOIP, Gaming, etc.). In some of the disclosed embodiments, Sub1G may be employed using current 2.4G or 5G Wireless LAN chipset with RF Up/Down Converters. In some embodiments, the Sub1G approach may be used to create a Long Range Bridge, Long Range Extender, Long Range Client, Long Range Hotspot, etc.

Abstract translation: 各种实施例公开了用于使用与各种用户装置的内部和/或外部组件一起使用的Sub1G信号（例如，大约500Mhz或800mHz的信号）的系统和方法。 由于自由空间路径损耗模型的频率较低，Sub1G区域可能会比传统的2.4和5 Ghz系统提供路径损耗优势。 与1GHz相比，Sub 1G还可以呈现更少的干扰（例如，对于诸如VOIP，游戏等应用的更好的QoS）。 在一些所公开的实施例中，可以使用具有RF上/下转换器的当前2.4G或5G无线LAN芯片组来采用Sub1G。 在一些实施例中，Sub1G方法可用于创建长距离桥，长距离扩展器，远程客户端，远程热点等。

公开(公告)号：US09521624B2

公开(公告)日：2016-12-13

申请号：US14980761

申请日：2015-12-28

Applicant: NETGEAR, INC.

Inventor： Joseph Amalan Arul Emmanuel ,  Shun-Liang Yu ,  Peiman Amini

IPC: H04W52/02

CPC classification number: H04W52/0219 ,  H04W52/0229 ,  H04W52/0235 ,  H04W52/0245 ,  H04W52/0254 ,  H04W52/0258 ,  H04W84/12 ,  Y02D70/00 ,  Y02D70/142 ,  Y02D70/23 ,  Y02D70/26

Abstract: Various of the disclosed embodiments concern efficiency improvements in wireless products. For example, some embodiments specify profiles for regional and custom-specified operational constraints. The profiles may be retrieved from across a network or stored locally upon the device. The profiles may specify various configuration adjustments that optimize the system's performance. For example, when possible, some embodiments may allow the system to operate at a lower power level and to thereby save energy. Various factors and conditions may be assessed in some embodiments prior to adjusting the existing power configuration.

公开(公告)号：US09451626B2

公开(公告)日：2016-09-20

申请号：US14878986

申请日：2015-10-08

Applicant: Netgear, Inc.

Inventor： Peiman Amini ,  Arms Yongyuth ,  Steve Skeoch ,  Joseph Amalan Arul Emmanuel

IPC: H04B1/44 ,  H04W72/08 ,  H04W88/10 ,  H04W72/12 ,  H04L12/861 ,  H04W24/02 ,  H04W52/38 ,  H04B1/525 ,  H04W84/12

CPC classification number: H04W4/38 ,  H04B1/44 ,  H04B1/525 ,  H04L5/0055 ,  H04L25/03006 ,  H04L49/9005 ,  H04L69/28 ,  H04L69/323 ,  H04L69/324 ,  H04W24/02 ,  H04W28/26 ,  H04W52/0212 ,  H04W52/386 ,  H04W72/0453 ,  H04W72/082 ,  H04W72/1215 ,  H04W72/1247 ,  H04W84/12 ,  H04W88/10 ,  H04W88/12 ,  Y02B70/30 ,  Y02D70/00 ,  Y02D70/1262 ,  Y02D70/142 ,  Y02D70/144 ,  Y02D70/164 ,  Y02D70/166 ,  Y02D70/23 ,  Y02D70/40

Abstract: Techniques are disclosed for reducing interference, in a network device, among multiple radio circuits operating in a same or similar frequency band and in close physical proximity. In some embodiments, a network device includes a first and a second wireless network circuit. The network circuits operate in a same radio frequency band and are collocated. The second network circuit is assigned a higher priority than the first network circuit. The device further includes a coexistence controller coupled to the network circuits via a communication bus and configured to selectively suppress transmitting operations of the first network circuit during receiving operations of the second network circuit. Among other benefits, the embodiments can increase wireless network bandwidth and reduce mobile device power consumption by providing coordination among the radio circuits so that the transmitting and receiving operations are performed in a way that they do not interfere with their respective antennas.

公开(公告)号：US20150139204A1

公开(公告)日：2015-05-21

申请号：US14242662

申请日：2014-04-01

Applicant: NETGEAR, Inc.

Inventor： Joseph Amalan Arul Emmanuel ,  Peiman Amini ,  Paul Nysen ,  Shun-Liang Yu ,  Chia-Wei Liu ,  Shahrokh Zardoshti ,  Gin Wang ,  Henry Chen

IPC: H04B1/00

CPC classification number: H04B1/005 ,  H04B1/0096 ,  H04B2001/0491 ,  H04L27/2672 ,  H04W84/12

Abstract: Various embodiments disclose systems and methods for employing a Sub1G signal (e.g. a signal in the range of approximately 500 Mhz or 800 mHz) for use with internal and/or external components of various user devices. The Sub1G region may provide a path loss advantage over traditional 2.4 and 5 Ghz systems because of the lower frequency in free-space path loss model. Sub 1G may also present less interference compared to 2.4 GHz (e.g., better QoS for applications such as VOIP, Gaming, etc.). In some of the disclosed embodiments, Sub1G may be employed using current 2.4G or 5G Wireless LAN chipset with RF Up/Down Converters. In some embodiments, the Sub1G approach may be used to create a Long Range Bridge, Long Range Extender, Long Range Client, Long Range Hotspot, etc.

Abstract translation: 各种实施例公开了用于使用与各种用户装置的内部和/或外部组件一起使用的Sub1G信号（例如，大约500Mhz或800mHz的信号）的系统和方法。 由于自由空间路径损耗模型的频率较低，Sub1G区域可能比传统的2.4和5 GHz系统提供路径损耗优势。 与1GHz相比，Sub 1G还可以呈现更少的干扰（例如，对于诸如VOIP，游戏等应用的更好的QoS）。 在一些所公开的实施例中，可以使用具有RF上/下转换器的当前2.4G或5G无线LAN芯片组来采用Sub1G。 在一些实施例中，Sub1G方法可用于创建长距离桥，长距离扩展器，远程客户端，远程热点等。

公开(公告)号：US20230148353A1

公开(公告)日：2023-05-11

申请号：US18154704

申请日：2023-01-13

Applicant: NETGEAR, Inc.

Inventor： Peiman Amini ,  Joseph Amalan Arul Emmanuel

IPC: H04N19/166 ,  H04N19/103 ,  H04N19/124 ,  H04N19/156 ,  H04N19/184 ,  H04N19/40 ,  H04N19/42 ,  H04B17/318 ,  H04B17/391 ,  H05B47/19 ,  G07C9/37 ,  H05B47/105 ,  G06F9/54 ,  G06T7/20 ,  G08B3/10 ,  G08B5/22 ,  G08B13/191 ,  G08B13/193 ,  G08B13/196 ,  G08B21/18 ,  G08B27/00 ,  G08B29/18 ,  H04L1/00 ,  H04L5/00 ,  H04L43/0852 ,  H04L43/12 ,  H04L43/16 ,  H04L65/80 ,  H04L67/1087 ,  H04N7/12 ,  H04N7/18 ,  H04N17/00 ,  H04W24/08 ,  H04W24/10 ,  H04W28/02 ,  H04W36/00 ,  H04W36/30 ,  H04W52/02 ,  H04W72/0453 ,  G06V20/52 ,  H04L65/65 ,  H04L65/612 ,  H04W72/23 ,  H04N23/90 ,  H04N23/661 ,  H04N23/60 ,  H04N23/68

CPC classification number: H04N19/166 ,  H04N19/103 ,  H04N19/124 ,  H04N19/156 ,  H04N19/184 ,  H04N19/40 ,  H04N19/42 ,  H04B17/318 ,  H04B17/391 ,  H05B47/19 ,  G07C9/37 ,  H05B47/105 ,  G06F9/542 ,  G06T7/20 ,  G08B3/10 ,  G08B3/1016 ,  G08B5/223 ,  G08B13/191 ,  G08B13/193 ,  G08B13/19656 ,  G08B13/1966 ,  G08B13/19669 ,  G08B13/19695 ,  G08B21/182 ,  G08B27/006 ,  G08B29/183 ,  H04L1/0003 ,  H04L1/0009 ,  H04L1/0017 ,  H04L1/0033 ,  H04L5/0053 ,  H04L43/0858 ,  H04L43/12 ,  H04L43/16 ,  H04L65/80 ,  H04L67/1093 ,  H04N7/12 ,  H04N7/183 ,  H04N17/002 ,  H04W24/08 ,  H04W24/10 ,  H04W28/021 ,  H04W36/0011 ,  H04W36/30 ,  H04W52/0245 ,  H04W52/0261 ,  H04W72/0453 ,  G06V20/52 ,  H04L65/65 ,  H04L65/612 ,  H04W72/23 ,  H04N23/90 ,  H04N23/661 ,  H04N23/665 ,  H04N23/6811 ,  G06T2207/30232 ,  G06T2207/30241 ,  H04N7/147

Abstract: A client device is configured to communicate with an access point over a wireless network, exchanging data with the access point over a selected communication channel. After the wireless connection to the access point has ended, the client device receives a probe from the access point over a low-level layer, such as a data link layer. In response to receiving the probe, the client device reconnects to the access point.