Patent Grant
9472873
1. Field of the Disclosure
This disclosure pertains in general to receptacle connectors, and more specifically to reversible receptacle connectors for connecting electric paths.
2. Description of the Related Art
Electronic devices often include data connectors that receive or provide power and communicate data. The connectors are traditionally female receptacles designed to receive male connectors. The receptacle connects electrical paths of the connector to an electronic device. A reversible receptacle can receive a reversible connector in two possible orientations. The reversible receptacle ensures a positive connection between the connector and the receptacle regardless of the relative orientation of the connector. The receptacle includes a pair of contacts. The contacts are connected together by a conductive bridge, typically at a location close to a printed circuit board (PCB). The reversible receptacle including only the first conductive bridge limits the bandwidth and degrades the signal quality of signals transmitted on the pair of contacts. Examples of reversible receptacles include Universal Serial Bus (USB) Type C receptacles and Super Mobile High-Definition Link (MHL) receptacles.
Embodiments relate to a receptacle assembly for connecting to a plug of a connector. The receptacle includes an insulating member, contacts, and conductive bridges. The receptacle includes a first contact on a first side of the insulating member. The first contact electrically connects to a first plug contact of the connector when the connector engages with the receptacle in a first orientation. The receptacle further includes a second contact on a second side of the insulating member. The second contact electrically connects to the first plug contact of the connector when the connector engages with the receptacle in a second orientation. The second contact extends to a printed circuit board of an electric device and is connected to the first contact via a first conductive bridge at a first location closer to the printed circuit board than the first plug contact. The first and second contacts are connected via a second conductive bridge at a second location closer to the first plug contact than the first conductive bridge.
In one embodiment, the second conductive bridge is formed to penetrate the insulating member and the first conductive bridge is separated away from the insulating member.
In one embodiment, a distance between the first and second conductive bridge along the first contact is less than 15 mm/√{square root over (εr)}, where εr is the relative permittivity of the insulating member.
In one embodiment, the second conductive bridge includes a first portion extending from the first contact into the insulating member, a second portion extending from the second contact into the insulating member, and a conductive path extending between the first portion and the second portion. The conductive path is parallel to a top or bottom surface of the insulating member when the plug engages with the receptacle in the second orientation.
In one embodiment, the first contact includes a first portion extending on the first side of the insulating member at a first height and is parallel to the first side of the insulating member. The first contact further includes a second portion extending to the printed circuit board parallel to the first side of the insulating member at a second height lower than the first height. The first contact includes a third portion connecting the first and second portions of the first contact.
The teachings of the embodiments disclosed herein can be readily understood by considering the following detailed description in conjunction with the accompanying drawings.
The Figures (FIG.) and the following description relate to various embodiments by way of illustration only. It is noted that wherever practicable similar or like reference numbers may be used in the figures may indicate similar or like functionality. Alternative embodiments of the structures and methods disclosed herein will be readily recognized as viable alternatives that may be employed without departing from the principles discussed herein. Reference will now be made in detail to several embodiments, examples of which are illustrated in the accompanying figures.
A receptacle receives one or more plugs from a connector and electrically connects the connector to an electronic device. The female receptacle receives one or more male plugs of the connector and electrically connects the connector to the electronic device. The receptacle transmits power and data from the connector to the electronic device, and vice versa.
Some receptacles are reversible. A reversible receptacle receives a reversible connector in two possible orientations. In both orientations, the reversible connectors provide the same connectivity to the electronic device so that users can conveniently use either orientation of the connector to connect the electronic device. Examples of the reversible receptacle include Universal Serial Bus (USB) Type C receptacles and Super Mobile High-Definition Link (MHL) receptacles.
The reversible receptacle includes a pair of contacts. The contacts are on either side of an insulating member in the reversible receptacle. The contacts extend from the connector to a printed circuit board (PCB) of the electronic device. The contacts are connected together by a first conductive bridge at a location close to the PCB. The first conductive bridge is not connected to the connector and therefore acts as an open stub in the receptacle. The open stub causes undesirable capacitance between the contacts of the reversible connectors which in turn causes crosstalk between a signal transmitted on the contacts. Crosstalk occurs when a signal transmitted on one part of a device (e.g., one of the contacts of the reversible receptacle) creates an undesired effect in another part of the device (e.g., the other one of the contacts of the reversible receptacle). The crosstalk limits the bandwidth and degrades the signal quality of the signal transmitted via the contacts.
Embodiments relate to providing a second conductive bridge connecting the contacts in a receptacle at a location closer to the connector than the first conductive bridge to reduce the capacitance introduced by the open stub. The first and second conductive bridges are separated by a distance. The reducing of the capacitance in turn reduces the crosstalk between the signal transmitted on the contacts. The second conductive bridge reduces the effect of the open stub thereby increasing the bandwidth of and improving the signal quality of the signal than receptacles with a single conductive bridge at a location closer to the PCB than the connector.
The first contact 102 and the second contact 104 transmit signals from the connector 150 to the PCB 130 of the electronic device. The first contact 102 and the second contact 104 can be implemented using metal traces. The first contact 102 is on a first side (i.e., top-side) of the insulating member 112 and the second contact 104 is on a second side (i.e., bottom-side) of the insulating member 112. The first contact 102 and the second contact 104 extend to the PCB 130 of the electronic device.
The first contact 102 includes a first portion 162A extending on the first side (i.e., top-side) of the insulating member 112 at a first height 164 from a PCB surface 132 and parallel to the first side of the insulating member 112. The first contact 102 further includes a second portion 162B extending to the PCB 130 parallel to the first side of the insulating member 112 at a second height 166 from the PCB surface 132 lower than the first height 164. In one embodiment, the second height 166 from the PCB surface 132 is zero (i.e., the second portion 162B is on the PCB surface 132). The first contact 102 includes a third portion 162C connecting the first portion 162A and the second portion 162B of the first contact 102.
Similarly, the second contact 104 includes a first portion 172A at a third height 174 from the PCB surface 132 and parallel to the second side (i.e., bottom-side) of the insulating member 112, a second portion 172B extending to the PCB 130 parallel to the second side of the insulating member 112 at a fourth height 176 from the PCB surface 132 lower than the third height 174, and a third portion 172C connecting the first portion 172A and the second portion 172B of the second contact 104. In one embodiment, the third height 174 is lower than the first height 164 and higher than the second height 166, and the fourth height 176 and the second height 166 are substantially the same. In one embodiment, the fourth height 176 from the PCB surface 132 is zero (i.e., the second portion 172B is on the PCB surface 132.
The insulating member 112 separates the first contact 102 and the second contact 102 within the receptacle 100. The insulating member 112 has a sheet-like structure and separates a first side (e.g., top-half) of the receptacle 100 from a second side (e.g., bottom-half) of the receptacle 100. The insulating member 112 prevents signals transmitted via contacts (e.g., first contact 102) at one side (e.g., top-side) of the insulating member 112 from affecting signals transmitted via contacts (e.g., second contact 104) at another side (e.g., bottom-side) of the insulating member 112. In one embodiment, the insulating member 112 is an insulative plastic or any other composite material.
The connector 150 engages with the receptacle 100 in each of two orientations. That is, the connector 150 may engage with the receptacle 100 in a first orientation while the connector 150 may also engage with the receptacle 100 in a second orientation rotated 180 degrees relative to the first orientation without reconfiguration. Conductive bridges are provided in the receptacle 100 so that plug contacts of the connector 150 may engage with the appropriate contacts of the receptacle 100 in either orientation.
In the embodiment of
The receptacle 100 also includes the second conductive bridge 124 to reduce the capacitance introduced by the open stub which in turn reduces the crosstalk between the signal transmitted on the first contact 102 and the second contact 104. The second conductive bridge 124 connects the first contact 102 and the second contact 104 at a second location closer to the connector 150 than the first conductive bridge 122. Specifically, the second conductive bridge 124 connects the first portion 162A of the first contact 102 and the first portion 172A of the second contact 104.
In one embodiment, the second conductive bridge 124 is formed to penetrate the insulating member 112 and the first conductive bridge 122 is separated away from the insulating member 112. The second conductive bridge 124 includes a first portion 142A extending from the first portion 162A of the first contact 102 into the insulating member 112, a second portion 142B extending from the first portion 172A of the second contact 104 into the insulating member 112, and a first conductive bridge 144 extending between the first portion 142A and the second portion 142B. The first conductive bridge 144 extends from the first portion 142A to the second portion 142B and is parallel to the top or bottom surface of the insulating member 112. The second conductive bridge 124 is not limited to the structure illustrated in
In one embodiment, the first conductive bridge 122 and the second conductive bridge 124 are separated by a distance along the path of the signals. As illustrated in
The receptacle 300 connects multiple electrical paths of the connector 350 to a PCB 330 of an electronic device. The receptacle 300, the connector 350, and the PCB 330 are similar to the receptacle 100, the connector 350, and the PCB 130 of
The first contact 302, the second contact 304, the third contact 306, and the fourth contact 308 (hereinafter collectively referred to as “contacts 302 through 308”) transmit signals from the connector 350 to the PCB 330 of the electronic device. The contacts 302 through 308 can be implemented using metal traces. The first contact 302 and the third contact 306 are on the first side (i.e., top-side) of the insulating member 312 and the second contact 304 and the fourth contact 308 are on the second side (i.e., bottom-side) of the insulating member. The contacts 302 through 308 extend to the PCB 330 of the electronic device.
In one embodiment, the receptacle 300 is a Universal Serial Bus (USB) Type C receptacle. The USB Type C receptacle is a receptacle 300 which conforms to the mechanical and electrical requirements of the USB Type C standard developed and maintained by the Universal Serial Bus Implementers Forum (USB-IF). The receptacle 300 complying with the USB Type C standard includes additional contacts which are omitted in
The first contact 302 and the second contact 304 are similar to the first contact 102 and the second contact 104 illustrated in
The third contact 306 includes a first portion 382A extending on the first side (i.e., top-side) of the insulating member 312 at a fifth height 384 from the PCB surface 332 and parallel to the first side of the insulating member 312, a second portion 382B extending to the PCB 330 parallel to the first side of the insulating member 312 at a sixth height 386 from the PCB surface 332 lower than the fifth height 384, and a third portion 382C connecting the first portion 382A and the second portion 382B of the third contact 306. In one embodiment, the fifth height 384 and the first height 364 are substantially the same, and the sixth height 386 and the second height 376 are substantially the same. In one embodiment, the sixth height 386 from the PCB surface 332 is zero (i.e., the second portion 382B is on the PCB surface 332).
The fourth contact 308 includes a first portion 392A extending on the second side (i.e., bottom-side) of the insulating member 312 at a seventh height 394 from the PCB surface 332 and parallel to the second side of the insulating member 312, a second portion 392B extending to the PCB 330 parallel to the second side of the insulating member 312 at an eighth height 396 from the PCB surface 332 lower than the seventh height 394, and a third portion 392C connecting the first portion 392A and the second portion 392B of the fourth contact 308. In one embodiment, the seventh height 394 and the third height 374 are substantially the same, and the eighth height 396 and the fourth height 366 are substantially the same. In one embodiment, the eighth height 396 from the PCB surface 332 is zero (i.e., the second portion 392B is no the PCB surface 332).
The insulating member 312 is similar to the insulating member 112 of the receptacle 100 illustrated in
The connector 350 engages with the receptacle in each of the two orientations. Conductive bridges are provided in the receptacle 300 so that plug contacts of the connector 350 may engage with the appropriate contacts of the receptacle 300 in either orientation.
In the embodiment of
The second conductive bridge 324 and the fourth conductive bridge 328 reduce the effect of the open stubs. The second conductive bridge 324 connects the first contact 302 and the second contact 304 at a second location closer to the connector 350 than the first conductive bridge 322. The fourth conductive bridge 328 connects the third contact 306 and the fourth contact 308 at a fourth location closer to the connector 350 than the third conductive bridge 326. The second conductive bridge 324 and the fourth conductive bridge 328 are spatially separated from one another by a distance 336. In one embodiment, the second location of the second conductive bridge 324 and the fourth location of the fourth conductive bridge 328 are substantially the same.
In one embodiment, similar to the second conductive bridge 124 illustrated in
In one embodiment, the third conductive bridge 326 and the fourth conductive bridge 328 are separated by a distance. As illustrated in
Principles described herein can be used in receptacles other than USB Type C, for example, Super Mobile High-Definition Link (MHL). Thus, while particular embodiments and applications of the present disclosure have been illustrated and described, it is to be understood that the embodiments are not limited to the precise construction and components disclosed herein.
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