Patent application number | Description | Published |
20090047027 | Optical Network Unit Transceiver Module Having Direct Connect RF Pin Configuration - Systems and method for using a direct connect RF pin configuration for an ONU transceiver module to connect directly to an external component. The ONU module communicates with an optical network. The ONU module further includes an RF interface and a direct connect RF pin configuration to communicate using RF signals. In one embodiment, the direct connect RF pin configuration includes two ground pins and a data pin which are spaced apart and directly connected to a PCB of the ONU. The opposing ends of the pins are directly connected to a PCB of an external component, such as an ONU host box. The pins are thus spaced apart such that they do not impede each others' function and available for direct connection to the external component. | 02-19-2009 |
20090074357 | SURFACE WARP RESISTANT OPTICAL DEVICES - In at least one example, an optical component includes a central optical surface proximate an optical axis, a peripheral portion extending radially from the central optical surface, and a stepped portion between the central optical surface and the peripheral portion. The stepped portion may be formed to raise the central optical surface above the peripheral portion. | 03-19-2009 |
20090123118 | INTEGRATED OPTICAL INTERCONNECT - An integrated optical interconnect. The integrated optical interconnect includes a receptacle for connecting to a first external component. The receptacle includes an EMI shield with an aperture sized to allow transmission of an optical signal through the aperture while containing EMI within the receptacle. The integrated optical interconnect also includes a port injection molded around or within a portion of the receptacle, the port being configured to receive a second external component and a lens injection molded near a location of the aperture of the EMI shield. | 05-14-2009 |
20090290619 | TRANSCEIVER MODULE WITH DUAL PRINTED CIRCUIT BOARDS - Transceiver modules with dual printed circuit boards. In one example embodiment, a transceiver module includes first and second printed circuit boards (PCBs), a transmitter, a receiver, and a flexible circuit. The first PCB is positioned in a first plane and the second PCB is positioned in a second plane. The transmitter and the receiver are both positioned in a third plane that is offset from the first and second planes. The flexible circuit includes conductive traces that allow electrical data signals to pass between the transmitter and the receiver and the first and second PCBs. | 11-26-2009 |
20100080518 | PRINTED CIRCUIT BOARD POSITIONING IN AN OPTOELECTRONIC MODULE - Printed circuit board (PCB) positioning in an optoelectronic module. In one example embodiment, a spacer can be use to position top and bottom PCBs that are at least partially enclosed within top and bottom shells of an optoelectronic module. The spacer includes top and bottom surfaces and a plurality of top posts extending from the top surface. The top posts are configured to extend through openings in the top PCB to contact inside surfaces of the top shell. | 04-01-2010 |
20100129035 | OPTICAL NETWORK UNIT TRANSCEIVER - In one example embodiment, a pluggable ONU transceiver module comprises a top shell, a bottom shell configured to mate with the top shell to form a cavity, and a PCB disposed within the cavity. A plurality of pins are coupled to the PCB and are configured to be inserted into a protruding socket of a host device through the bottom shell. The protruding socket is mounted on a PCB of the host device. The pluggable ONU transceiver module further comprises one or more guiding features integrated with the bottom shell and configured to ensure that the pins are inserted correctly into the protruding socket, and means for positioning the top shell at a predetermined height above the PCB of the host device to allow coupling of the top shell to a heatsink of the host device. | 05-27-2010 |
20100132999 | ELECTROMAGNETIC SHIELDING CONFIGURATION - An electromagnetic shielding configuration comprising a first electrically conductive wall having a first surface and a second electrically conductive wall having a second surface. The first surface is oppositely disposed from the second surface, wherein interfacing of the first conductive wall and the second conductive wall forms an enclosure wall. The first surface comprises at least one stepped edge forming a plurality of surfaces of unequal lateral displacement, and a corrugated surface on at least one of the plurality of surfaces, the corrugated surface formed by a series of apices extending radially from the first surface. The second surface is substantially a conjugate of the first surface. | 06-03-2010 |
20100142898 | BAIL RELEASE MECHANISM FOR COMMUNICATIONS MODULE - In one example, a bail release mechanism includes a bail and a de-latching member. The bail is configured to be attached to the shell of a module that includes a latch pin configured to engage a structure of a host device receptacle to secure the module within the receptacle. The bail is further configured to rotate about a first axis between a latched position and an unlatched position. The first axis is in a fixed position relative to the shell. The de-latching member is attached to the bail at a second axis that is offset from the first axis and is configured to rotate about the second axis. The second axis is movable relative to the shell. The de-latching member includes a first end configured to displace the structure of the receptacle during rotation of the de-latching member to disengage the latch pin from the structure. | 06-10-2010 |
20110080008 | LATCHING MECHANISM FOR A MODULE - One embodiment includes a latching mechanism having a latch, a cam and a slider. The cam is configured to rotate about an axis of rotation. The cam is also configured to displace an end of the latch when the cam is rotated about the axis of rotation. The slider is operably connected to the cam and is configured to cause the cam to rotate about the axis of rotation. Some embodiments also include a retaining cover and a boot. The retaining cover secures a second end of the latch to a module in which the latching mechanism is implemented. The boot is operatively connected to the slider and can be manipulated by a user to activate the slider. | 04-07-2011 |
20110081114 | COMMUNICATIONS MODULE INTEGRATED BOOT AND RELEASE SLIDE - One embodiment includes an integrated boot and release slide having a release slide and a boot. The release slide includes a main body, a plurality of arms, and a plurality of coupling structures. The arms extend from a first end of the main body. The coupling structures extend from a second end of the main body opposite the first end. The boot is overmolded over the coupling structures of the release slide and defines a cavity configured to slidably receive a communications cable. | 04-07-2011 |
20110200287 | CONSTRAINING BALL LENS IN AN OPTICAL SUBASSEMBLY - In one embodiment, an optical subassembly includes a housing, a ball lens, a constraining insert, and a ball lens constraint. The housing includes a fiber receptacle formed in a first end of the housing and a second receptacle formed in a second end of the housing opposite the first end. The fiber receptacle and second receptacle define a cavity through the housing from the first end to the second end of the housing. The ball lens and the constraining insert are disposed within the cavity. The ball lens constraint is configured to cooperate with the constraining insert to constrain the ball lens in three dimensions within the cavity. | 08-18-2011 |
20120148198 | COMMUNICATIONS MODULE INTEGRATED BOOT AND RELEASE SLIDE - One embodiment includes communications module having a release slide and a boot. The release slide includes a main body, a plurality of arms, and a plurality of coupling structures. The arms extend from a first end of the main body. The coupling structures extend from a second end of the main body opposite the first end. The boot is disposed over the coupling structures of the release slide and defines a cavity configured to slidably receive a communications cable. | 06-14-2012 |
20120183300 | OPTICAL NETWORK UNIT TRANSCEIVER MODULE HAVING DIRECT CONNECT RF PIN CONFIGURATION - Methods for providing a direct connect RF pin configuration for an ONU transceiver module to connect directly to an external component. The ONU module communicates with an optical network. The ONU module further includes an RF interface and a direct connect RF pin configuration to communicate using RF signals. In one embodiment, the direct connect RF pin configuration includes two ground pins and a data pin which are spaced apart and directly connected to a PCB of the ONU. The opposing ends of the pins are directly connected to a PCB of an external component, such as an ONU host box. The pins are thus spaced apart such that they do not impede each others' function and available for direct connection to the external component. | 07-19-2012 |
20120318573 | ELECTROMAGNETIC SHIELDING CONFIGURATION - An electromagnetic shielding configuration comprising a first electrically conductive wall having a first surface and a second electrically conductive wall having a second surface. The first surface is oppositely disposed from the second surface, wherein interfacing of the first conductive wall and the second conductive wall forms an enclosure wall. The first surface comprises at least one stepped edge forming a plurality of surfaces of unequal lateral displacement, and a corrugated surface on at least one of the plurality of surfaces, the corrugated surface formed by a series of apices extending radially from the first surface. The second surface is substantially a conjugate of the first surface. | 12-20-2012 |
20130044985 | OPTICAL NETWORK UNIT TRANSCEIVER - In one example embodiment, a pluggable ONU transceiver module comprises a top shell, a bottom shell configured to mate with the top shell to form a cavity, and a PCB disposed within the cavity. A plurality of pins are coupled to the PCB and are configured to be inserted into a protruding socket of a host device through the bottom shell. The protruding socket is mounted on a PCB of the host device. The pluggable ONU transceiver module further comprises one or more guiding features integrated with the bottom shell and configured to ensure that the pins are inserted correctly into the protruding socket, and means for positioning the top shell at a predetermined height above the PCB of the host device to allow coupling of the top shell to a heatsink of the host device. | 02-21-2013 |
20130094153 | ELECTROMAGNETIC RADIATION SHIELDING ON A PCI EXPRESS CARD - An example embodiment includes an electromagnetic radiation (EMR) shield. The EMR shield is configured to reduce EMR from escaping a host device. The EMR shield includes a structure, two or more module-grounding tabs, and multiple fingers. The structure is configured to substantially surround two or more adjacent transceiver modules positioned in an opening defined in a bezel. The two or more module-grounding tabs extend from the structure. Each of the module-grounding tabs is configured to contact one of the transceiver modules. The fingers extend from the structure and are configured to contact the bezel at multiple contact areas substantially surrounding the opening. | 04-18-2013 |
20130142490 | ELECTROMAGNETIC RADIATION SHIELD FOR AN ELECTRONIC MODULE - An electromagnetic radiation shield for an electronic module. In one example embodiment, an EMR shield for an electronic transceiver module includes a conductive carrier sized and configured to surround a shell of an electronic transceiver module. The conductive carrier defines a plurality of extended elements located on at least one edge of the conductive carrier and an orientation element. Each extended element is configured to bias against the shell in order to create a physical and electrical contact between the conductive carrier and the shell. The orientation element is configured to engage a corresponding structure in the shell in order to correctly orient the conductive carrier with respect to the shell. | 06-06-2013 |
20130178090 | LATCHING MECHANISM FOR A MODULE - One embodiment includes a latching mechanism having a latch, a cam and a slider. The cam is configured to rotate about an axis of rotation. The cam is also configured to displace an end of the latch when the cam is rotated about the axis of rotation. The slider is operably connected to the cam and is configured to cause the cam to rotate about the axis of rotation. | 07-11-2013 |
20130182390 | THERMALLY CONDUCTIVE FLEXIBLE MEMBER FOR HEAT TRANSFER - An example embodiment includes a thermal conduction system for dissipating thermal energy generated by operation of an optical subassembly that disposed within a shell of a communication module. The thermal conduction system can include a thermally conductive flexible member that contacts the optical subassembly and to contact the shell of the communication module. By contacting the optical subassembly and the shell, the thermal energy generated by operation of the optical subassembly can transfer from the optical subassembly to the shell. The thermally conductive flexible member defines thermally conductive flexible member holes that correspond to pins extending from the optical subassembly. The pins pass through the thermally conductive flexible member holes enabling the thermally conductive flexible member to contact the optical subassembly. | 07-18-2013 |
20140064677 | OPTICAL NETWORK UNIT TRANSCEIVER - A pluggable ONU transceiver module comprises a top shell, a bottom shell configured to mate with the top shell to form a cavity, and a PCB disposed within the cavity. A plurality of pins are coupled to the PCB and are configured to be inserted into a protruding socket of a host device through the bottom shell. The protruding socket is mounted on a PCB of the host device. The pluggable ONU transceiver module further comprises one or more guiding features integrated with the bottom shell and configured to ensure that the pins are inserted correctly into the protruding socket, and means for positioning the top shell at a predetermined height above the PCB of the host device to allow coupling of the top shell to a heatsink of the host device. | 03-06-2014 |
20150063752 | CONSTRAINING BALL LENS IN AN OPTICAL SUBASSEMBLY - In one embodiment, an optical subassembly includes a housing, a ball lens, a constraining insert, and a ball lens constraint. The housing includes a fiber receptacle formed in a first end of the housing and a second receptacle formed in a second end of the housing opposite the first end. The fiber receptacle and second receptacle define a cavity through the housing from the first end to the second end of the housing. The ball lens and the constraining insert are disposed within the cavity. The ball lens constraint is configured to cooperate with the constraining insert to constrain the ball lens in three dimensions within the cavity. | 03-05-2015 |