This application claims the priority benefit of China application no. 202011425332.6, filed on Dec. 8, 2020. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
This disclosure is related an electrical connector.
With the rapid development of electronic technology nowadays, the resolution of display devices is increasing and the requirements for high transmission bandwidth have led to the emergence of a high-resolution multimedia interface (HDMI), which is a fully digitized image and sound transmission interface that can simultaneously transmit uncompressed audio and video signals, and are commonly applied in the audio-visual transmission of consumer electronic products to ensure that the signal will not be attenuated during the audio-visual transmission process.
Furthermore, as high-quality images gradually become mainstream for display of film and television, the data transmission bandwidth in conventional technology might not meet the functional requirements of the future video transmission interface, and the new HDMI 2.1 specification has been formulated. The transmission bandwidth is upgraded considerably from 18 Gbps to 48 Gbps of HDMI 2.0, and supports a variety of higher dynamic image pixels and update rates. In addition, dynamic HDR and low-latency transmission technology have also been incorporated to the functional part, which is compatible with the previous HDMI 2.0 specification.
What follows is that the terminal structure required for the new specification HDMI 2.1 is more complicated, which increases the difficulty of designing the required mold, and even requires at least two sets of different molds to meet the requirements of the new specification, which has also led to an increase in manufacturing costs.
This disclosure provides an electrical connector complied with HDMI 2.1 and having a simple structure that can meet the requirements for high-frequency signal transmission.
In the disclosure, an electrical connector complied with HDMI 2.1 includes an insulating body, a plurality of terminals and a metallic shell. The metallic shell covers portions of the insulating body and the terminals. The terminals includes ten terminals located on an upper row and nine terminals located on a lower row, and the terminals are alternated along the arrangement direction of the terminals. The ten terminals located on the upper row includes a first terminal Data2+, a third terminal Data2−, a fifth terminal Data Shield, a seventh terminal Data0+, a ninth terminal Data0−, an eleventh terminal Data3 Shield, a thirteenth terminal CEC, a fifteenth terminal SCL, a seventeenth terminal DDC/CEC Ground, and a nineteenth terminal Hot Plug Detec1 arranged in an arrangement direction in sequence. The nine terminals on the lower row includes a second terminal Data2 Shield, a fourth terminal Data1+, a sixth terminal Data1−, an eighth terminal Data0 Shield, a tenth terminal Data3+, a twelfth terminal Data3−, a fourteenth terminal Utility, a sixteenth terminal SDA, and an eighteenth terminal +5V Power arranged in an arrangement direction in sequence.
In the disclosure, an electrical connector complied with HDMI 2.1 includes an insulating body, a plurality of terminals and a metallic shell. The metallic shell covers portions of the insulating body and the terminals. The terminals includes ten terminals located on an upper row and nine terminals located on a lower row, and the terminals are alternated along the arrangement direction of the terminals. The ten terminals located on the upper row includes a first terminal Data2+, a third terminal Data2−, a fifth terminal Data Shield, a seventh terminal Data0+, a ninth terminal Data0−, an eleventh terminal Data3 Shield, a thirteenth terminal CEC, a fifteenth terminal SCL, a seventeenth terminal DDC/CEC Ground, and a nineteenth terminal Hot Plug Detec1 arranged in an arrangement direction in sequence. The nine terminals on the lower row includes a second terminal Data2 Shield, a fourth terminal Data1+, a sixth terminal Data1−, an eighth terminal Data0 Shield, a tenth terminal Data3+, a twelfth terminal Data3−, a fourteenth terminal Utility, a sixteenth terminal SDA, and an eighteenth terminal +5V Power arranged in an arrangement direction in sequence. The first terminal has a width of 0.46 mm to 0.51 mm, the third terminal has a width of 0.26 mm to 0.31 mm, the fourth terminal has a width of 0.25 mm to 0.30 mm, the sixth terminal has a width of 0.25 mm to 0.30 mm, the seventh terminal has a width of 0.24 mm to 0.31 mm, the ninth terminal has a width of 0.24 mm to 0.31 mm, the tenth terminal has a width of 0.26 mm to 0.30 mm, and the twelfth terminal has a width of 0.26 mm to 0.30 mm.
Based on the foregoing, an electrical connector complied with HDMI 2.1 includes an insulating body, a plurality of terminals, and a metallic shell, and the metallic shell covers portions of the insulating body and the terminals. These terminals include ten terminals located in the upper row and nine terminals located in the lower row, and have specific pin assignments along the arrangement direction. Furthermore, the widths of the above-mentioned terminals along the arrangement direction are different. Among them, the first terminal, the third terminal, the fourth terminal, the sixth terminal, the seventh terminal, the ninth terminal, the tenth terminal and the twelfth terminal have a larger width. That is, these terminals with larger widths are used to transmit data, so the requirements for high-frequency signal transmission can be met by increasing the width of the terminals.
Furthermore, in order to meet the requirement of high-frequency signal transmission, the first terminal P1, the third terminal P3, the fourth terminal P4, the sixth terminal P6, the seventh terminal P7, the ninth terminal P9, the tenth terminal P10 and the twelfth terminal P12 in the embodiment are all used for data transmission, and accordingly have a larger width than the other terminals 120 to meet transmission requirements. In detail, the first terminal P1 of this embodiment has a width of 0.46 mm to 0.51 mm, the third terminal P3 has a width of 0.26 mm to 0.31 mm, the fourth terminal P4 has a width of 0.25 mm to 0.30 mm, the sixth terminal P6 has a width of 0.25 mm to 0.30 mm, the seventh terminal P7 has a width of 0.24 mm to 0.31 mm, the ninth terminal P9 has a width of 0.24 mm to 0.31 mm, the tenth terminal P10 has a width of 0.26 mm to 0.30 mm, and the twelfth terminal P12 has a width of 0.26 mm to 0.30 mm. In contrast, the width of the second terminal P2, the width of the fifth terminal P5, the width of the eighth terminal P8, the width of the eleventh terminal P11, the width of the thirteenth terminal P13, the width of the fourteenth terminal P14, the width of the fifteenth terminal P15, the width of the sixteenth terminal P16, the width of the seventeenth terminal P17, the width of the eighteenth terminal P18, and the width of the nineteenth terminal P19 are 0.24 mm, respectively. To put it simply, the width of the terminals 120 used for data transmission in this embodiment is greater than the width of the terminals 120 not used for data transmission, and the width is the size of each terminal 120 along the arrangement direction RA.
Please refer to
As shown in
More specifically, the cross section of the base 11 of the insulating body 110 is in a zigzag shape and is divided into an upper platform 111c and a lower platform 111d with a step between each other. The cross section uses the arrangement direction RA as a normal. When the electrical connector 100 is soldered to the circuit board 200 as shown in
Please refer to
Here, the symmetrical centerline CN of each terminal 120 in the contact segment C1 is taken as a reference, and the widths d1 and d2 are formed as follows:
Furthermore, the openings 112a and 112b on the upper surface S3 are arranged in a first row and a second row along the arrangement direction RA, and the distance d5 between the first row relative to the reference surface 111a of the base 111 is 0.5 mm, and the distance d6 between the second row relative to the reference surface 111a is 2.3 mm. An opening size d3 of each opening 112a located in the first row is 0.6 mm along the insertion direction MA, and an opening size d4 of each opening 112b located in the second row is 0.8 mm along the insertion direction MA.
Furthermore, the openings 112c and 112d on the lower surface S4 are arranged in a first row and a second row along the arrangement direction RA. The distance d8 between the first row relative to the reference surface 111a is 1.3 mm, and the distance d9 between the second row relative to the reference surface 111a is 3.3 mm. An opening size d7 of each opening 112c located in the first row is 0.8 mm along the insertion direction MA, and an opening size d7 of each opening 112d located in the second row is also 0.8 mm along the insertion direction MA.
Based on the above, compared with the existing electrical connector complied with HDMI 2.0, the openings on the tongue for exposing the terminals are all 0.5 mm. In this embodiment, the openings 112a, 112b, 112c, and 112d are all enlarged, which can effectively reduce the impedance of the terminals 120, so as to meet the requirements of HDMI 2.1 for high-speed transmission.
In summary, in the above-mentioned embodiments of the disclosure, the electrical connector complied with HDMI 2.1 includes an insulating body, a plurality of terminals, and a metallic shell, and the metallic shell covers portions of the insulating body and the terminals. These terminals include ten terminals in the upper row and nine terminals in the lower row, and have specific pin assignments along the arrangement direction. Furthermore, the widths of the above-mentioned terminals along the arrangement direction are different. Among them, the first terminal, the third terminal, the fourth terminal, the sixth terminal, the seventh terminal, the ninth terminal, the tenth terminal and the twelfth terminal have a larger width. That is, these terminals with larger widths are used to transmit data, and therefore the requirements for high-frequency signal transmission can be met by increasing the width of the terminals.
Number | Date | Country | Kind |
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202011425332.6 | Dec 2020 | CN | national |