This application claims priority to Japanese Patent Application No. 2018-086068, filed on Apr. 27, 2018, the entire disclosure of which is incorporated by reference herein.
This application relates to an electrical connector.
The Unexamined Japanese Patent Application Kokai Publication No. 2008-041656 discloses a connector that includes a plurality of signal contacts every two of which constitute a pair and a plurality of ground contacts every two of which constitute a pair. One end sides of the signal contacts and the ground contacts are arranged in a row in such a sequence that every pair of ground contacts sandwich a pair of signal contacts. On the other hand, the other end sides of the signal contacts and the ground contacts are arranged in such a manner that the respective contacts form the respective vertices of trapezoids and links between signal contacts adjacent to each other and links between ground contacts adjacent to each other form upper bases and lower bases, respectively, of the trapezoids. In each of the trapezoids, the upper base and the lower base are parallel with each other and the upper base is shorter than the lower base. Arrangement of the signal contacts and the ground contacts as described above enables transmission quality in differential transmission to be improved.
However, the electrical connector disclosed in the Unexamined Japanese Patent Application Kokai Publication No. 2008-041656 has limitation in suppression of crosstalk. For this reason, there is a possibility that resonance may occur in a frequency band in which signals are transmitted and transmission quality of signals may deteriorate.
The present disclosure is made in consideration of the above-described actual situation, and an objective of the present disclosure is to provide an electrical connector that is capable of preventing transmission quality of signals from deteriorating.
In order to achieve the objective described above, an electrical connector of the present disclosure is an electrical connector that includes a first connector that is mounted on a circuit board and a second connector that is connected to coaxial cables and, through fitting of the first connector and the second connector to each other, connects the circuit board and the coaxial cables to each other, in which
the first connector includes
In this case, the second connector may include
a plurality of conductive second contacts to each of which a cable connecting portion that connects to an inner conductor of one of the coaxial cables and a second contact contacting portion that comes into contact with one of the first contact contacting portions when the second connector is fitted to the first connector are formed and that extend in a direction along the circuit board, are arranged in a row in a corresponding manner to the first contacts, and serve as the opposite contacts,
an insulating second housing that holds the second contacts and to which gaps for housing the walls projecting from the first connector are disposed,
a conductive second shell that is mounted to the second housing in such a manner as to be spaced away from and cover the second contacts and the walls and is connected to the first shell when the second connector is fitted to the first connector, and
a conductive ground bar that connects to outer conductors of the coaxial cables and connects to the second shell.
The electrical connector may be configured in such a way that
based on a phenomenon in which, as a height of each of the walls above the circuit board decreases, a resonant frequency of each transmission line including one of the first contacts and one of the second contacts increases, the height of each of the walls above the circuit board is specified to a height corresponding to a frequency band of a noise targeted to be suppressed.
The electrical connector may also be configured in such a way that
a height of each of the walls above the circuit board is equal to a maximum height of each transmission line that is constituted by one of the first contacts, one of the second contacts, and an inner conductor of one of the coaxial cables above the circuit board.
The electrical connector may also be configured in such a way that
a height of each of the walls from the circuit board changes in accordance with a height of one of the arranged first contacts, one of the arranged second contacts, and an inner conductor of one of the arranged coaxial cables.
The electrical connector may also be configured in such a way that
a height of each of the walls above the circuit board is higher than a height of an inner conductor of one of the coaxial cables above the circuit board.
The electrical connector may also be configured in such a way that
a length of each of the walls along the circuit board is
longer the length of each transmission line constituted by one of the first contacts and one of the second contacts along the circuit board.
The electrical connector may also be configured in such a way that
a gap between each of the walls and the first and second shells is shorter than a half wavelength of a signal transmitted via one of the first contacts and one of the second contacts.
The electrical connector may also be configured in such a way that
the walls
partition the contacts from each other for each pair of contacts transmitting a pair of differential signals.
The electrical connector may also be configured in such a way that
each of the coaxial cables includes a pair of inner conductors that transmit a pair of differential signals, and
the pair of inner conductors are connected to a pair of the second contacts sandwiched by the walls.
According to the present disclosure, conductive walls that are erected with respect to a circuit board are disposed at both ends of an arrangement of first contacts and opposite contacts and at locations that partition the first contacts and the opposite contacts for each signal to be transmitted, and the walls are spaced apart from a shell. Since such a configuration enables the upper edges of the walls to be positioned in proximity to the first contacts and the opposite contacts, noise components generated due to resonance of transmission lines including the contacts easily propagate to the walls. As a result of this effect, it is possible to prevent transmission quality of signals from deteriorating.
A more complete understanding of this application can be obtained when the following detailed description is considered in conjunction with the following drawings, in which:
Hereinafter, an electrical connector according to an embodiment of the present disclosure will be described in detail with reference to the drawings. In all the drawings, the same reference symbols are assigned to the same or equivalent constituent elements. In the electrical connector according to the present embodiment, walls made of a conductor are disposed between transmission lines so as to reduce crosstalk between the transmission lines.
As illustrated in
Fitting of the receptacle connector 2 and the plug connector 3 to each other causes the 16 coaxial cables 4 and circuits on the circuit board 5 to be connected to each other. In the present embodiment, each coaxial cable 4 contains a pair of inner conductors 4a and transmits a pair of differential signals. Therefore, the electrical connector 1 is capable of transmitting 16 pairs of differential signals simultaneously.
First, a configuration of the receptacle connector 2 will be described. As illustrated comprehensively in
Each first contact 20 is a conductive member made of a metal with the longitudinal direction thereof aligned with the x-axis direction, as illustrated in
As illustrated in
Further, to each first contact 20, a first contact contacting portion 20c that, bending at one end of the rising portion 20b, extends in a direction along the circuit board 5 and comes into contact with an opposite contact (a second contact 30) is also formed. Between the rising portion 20b and the first contact contacting portion 20c, a locking portion 20d that is locked to the first housing 21 is disposed.
As described above, in each first contact 20, while the board connecting portion 20a is arranged along the circuit board 5, the locking portion 20d and the first contact contacting portion 20c are arranged at a height h1 with respect to the circuit board 5 taken as a reference, that is, the height h1 above the circuit board 5. The height h1 is set to be a maximum height of each first contact 20 above the circuit board 5.
The first housing 21 is an insulating member made of a resin. The first housing 21 holds the first contacts 20 with the plurality of first contacts 20 extending in the x-axis direction and arranged in a row in the y-axis direction, as illustrated in
The walls 22A are conductive members press-fitted into the first housing 21. As illustrated in
In the present embodiment, with regard to each wall 22A, a maximum height of a portion facing a first contact 20 above the circuit board 5 is h2 and a maximum height of a portion facing an opposite contact and an inner conductor 4a in a coaxial cable 4, to be described later, above the circuit board 5 is h4.
As illustrated in
As illustrated in
Next, a configuration of the plug connector 3 will be described. As illustrated comprehensively in
As illustrated in
As illustrated in
The second housing 31 is an insulating member. The second housing 31 holds the second contacts 30 with the plurality of second contacts 30 extending in the x-axis direction, as illustrated in
As illustrated in
As illustrated in
When, as illustrated in
In this case, as illustrated in
Further, when the receptacle connector 2 and the plug connector 3 are in this state, the contact pieces 23a of the first shell 23 come into contact with the second shell 34, as illustrated in
When the plug connector 3 is fitted into the receptacle connector 2 mounted on the circuit board 5, the walls 22A of the receptacle connector 2 are inserted into the grooves 31a of the plug connector 3. When the receptacle connector 2 and the plug connector 3 are in this state, the second shell 33 is brought to a state of being spaced apart from and covering the walls 22A, which constitute the receptacle connector 2, as illustrated in
In addition, the walls 22A are connected to the ground electrodes 5b on the circuit board 5. Therefore, the walls 22A have the same potential as that of the outer conductors 4b of the coaxial cables 4.
A pair of inner conductors 4a of each coaxial cable 4 transmits a pair of differential signals. Therefore, as illustrated in
In addition, as illustrated in
As illustrated in
In addition, a gap L between the upper edge 22a of each wall 22A and the second shell 33 (see
As illustrated in
Since such a configuration enables interspaces between a first contact 20, a second contact 30, and an inner conductor 4a and the upper edge 22a of each wall 22A to be set to be short, it becomes easy to transmit noise components emitted from the transmission lines including the first contact 20, the second contact 30, and the inner conductor 4a to the upper edge 22a of the wall 22A and to suppress emission of noise components to adjacent transmission lines.
As described above, the walls 22A are disposed in order to reduce crosstalk between pairs of transmission lines transmitting pairs of differential signals. Now, to what degree near end crosstalk (NEXT, an S-parameter), which is one of frequency characteristics of a transmission line, is reduced will be described.
As indicated by the thick solid line in
In addition, as indicated by the solid line in
As illustrated above, it was revealed that, as in the electrical connector 1 according to the present embodiment, inserting, between pairs of transmission lines each pair of which transmit a pair of differential signals and are made up of first contacts 20, second contacts 30, and inner conductors 4a of a coaxial cables 4, the walls 22A having the same height as the maximum heights of the first contacts 20, the second contacts 30, and the inner conductors 4a enabled frequency characteristics of the transmission lines to be improved. The degree of improvement achieved by the configuration was greater than in a case of surrounding the transmission lines by a conductive shell.
Further, the frequency characteristics of the transmission lines for signals change according to the height of the walls 22A. As indicated by the dotted line in
Meanwhile, as indicated by the alternate long and short dash line in
The analysis described thus far has revealed that there exists a phenomenon in which, as the height h2 and h4 of the walls 22A above the circuit board 5 decrease, resonant frequencies of the transmission lines including the first contacts 20, the second contacts 30, and the inner conductors 4a increase. Use of this phenomenon enables the height h2 and h4 of the walls 22A to be adjusted so that resonant frequencies of the transmission lines fall outside the frequency band of signals to be transmitted, that is, to be adjusted according to the frequency band of a noise targeted to be suppressed.
For example, when the frequency band of signals to be transmitted is in a range of F1 (GHz) or higher and F2 (GHz) or lower, resonant frequencies of the transmission lines are required to be set at frequencies higher than or equal to F2 (GHz) by configuring the height h2 and h4 of the walls 22A to be lower than the height h1 of the first contacts 20 and the height h3 of the second contacts 30 and the inner conductors 4a, respectively. Such a configuration enables noise components in a vicinity of the frequency band of signals to be transmitted to be suppressed. In addition, when the frequency band of signals to be transmitted is higher than or equal to F2 (GHz), resonant frequencies of the transmission lines are required to be set at frequencies higher than or equal to F1 (GHz) and lower than or equal to F2 (GHz) by configuring the height h2 and h4 of the walls 22A to be higher than the height h1 of the first contacts 20 and the height h3 of the second contacts 30 and the inner conductors 4a, respectively. Such a configuration enables noise components in a vicinity of the frequency band of signals to be transmitted to be suppressed.
As illustrated in
In
As described in detail thus far, according to the embodiment described above, the conductive walls 22A or 22B, which are erected on the circuit board 5, are disposed at both ends of the arrangement of the first contacts 20 and the second contacts 30 and at locations that partition the first contacts 20 and the second contacts 30 for each signal (a pair of differential signals) to be transmitted and the walls 22A or 22B are spaced apart from the first shell 23 and the second shell 33. Since such a configuration enables the upper edges 22a of the walls 22A or 22B to be positioned in proximity to the first contacts 20 and the second contacts 30, noise components generated due to resonance of the transmission lines including the first contacts 20 and the second contacts 30 easily propagate to the walls 22A or 22B. As a result of this effect, it is possible to, by suppressing an increase in crosstalk due to resonance, prevent transmission quality of signals from deteriorating.
Among the above configurations, the configuration that most effectively suppresses crosstalk (that is, having a lowest near end crosstalk value) is a case where the height of the walls 22A is changed in accordance with the height of transmission lines for signals, including the first contacts 20, the second contacts 30, and the inner conductors 4a, in the connector with respect to the circuit board 5 taken as a reference.
A case where the frequency of signals to be transmitted, that is, the frequency of a noise that has to be reduced, and resonant frequencies of the transmission lines are set apart from each other is considered. For example, when the resonant frequencies are to be lowered, it is preferable to set the height h2 and h4 of the walls 22A or 22B higher than the maximum height h1 and h3 of the transmission lines in the connector, respectively. On the other hand, when the resonant frequencies are to be raised, it is preferable to set the height h2 and h4 of the walls 22A or 22B lower than the maximum height h1 and h3 of the transmission lines in the connector, respectively. An acceptable range for a difference between the height h2 and h4 of the walls 22A or 22B and the height h1 and h3 of the first contacts 20, the second contacts 30, and the inner conductors 4a may be set at ±1.5 mm, or the difference may be set at a value within width of the first contact 20, the second contacts 30, and the inner conductors 4a. Alternatively, the height h2 and h4 of the walls 22A or 22B are only required to be set at a height that enables at least a portion of a space between a transmission line and another transmission line arranged adjacent thereto in the connector to be shielded. Still alternatively, the height h2 and h4 of the walls 22A or 22B above the circuit board 5 may be higher than the height h3 of the inner conductors 4a of the coaxial cables 4 above the circuit board 5.
Setting the height h2 and h4 of the walls 22A to be lower or higher than the height h1 and h3 of the first contacts 20, the second contacts 30, and the inner conductors 4a as described above enables the resonant frequencies of the transmission lines for signals to be set apart from the frequency of the signals and crosstalk due to resonance to be thereby reduced.
While the walls 22A or 22B function as members that transmit noises emitted from the transmission lines in the connector, changing the height h2 and h4 of the walls 22A or 22B causes the resonant frequencies of the transmission lines to be changed. Therefore, it is preferable that the height h2 and h4 of the walls 22A or 22B be determined according to the frequency of signals to be transmitted.
Although, in the embodiment described above, the second shell constituting the plug connector 3 is separated into the second shell (shell A) 33 and the second shell (shell B) 34, the two second shell components may be combined into one body.
In the embodiment described above, a case where the coaxial cables 4, each of which contains a pair of inner conductors 4a, are connected was described. However, the present disclosure is not limited to the case. The present disclosure is applicable to an electrical connector in which coaxial cables each of which contains an inner conductor are connected to a circuit board.
Although, in the embodiment described above, the electrical connector 1 that transmits differential signals was described, the present disclosure is not limited to the electrical connector 1. The present disclosure is applicable to an electrical connector that transmits single-end signals.
The foregoing describes some example embodiments for explanatory purposes. Although the foregoing discussion has presented specific embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the broader spirit and scope of the invention. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. This detailed description, therefore, is not to be taken in a limiting sense, and the scope of the invention is defined only by the included claims, along with the full range of equivalents to which such claims are entitled.
The present disclosure is applicable to an electrical connector that electrically connects coaxial cables to a circuit board and transmits high-frequency signals.
1 Electrical connector
2 Receptacle connector
3 Plug connector
4 Coaxial cable
4
a Inner conductor
4
b Outer conductor
4
c Insulator
4
d Outer coating
5 Circuit board
5
a Signal electrode
5
b Ground electrode
20 First contact
20
a Board connecting portion
20
b Rising portion
20
c First contact contacting portion
20
d Locking portion
21 First housing
22A, 22B Wall
22
a Upper edge
23 First shell
23
a Contact piece
30 Second contact
30
a Cable connecting portion
30
b Second contact contacting portion
30
c Locking portion
31 Second housing
31
a Groove
32 Ground bar
33 Second shell (shell A)
34 Second shell (shell B)
33
a Pull bar
Number | Date | Country | Kind |
---|---|---|---|
JP2018-086068 | Apr 2018 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6129555 | Daikuhara et al. | Oct 2000 | A |
6315608 | Lopata et al. | Nov 2001 | B1 |
20050054226 | Akama et al. | Mar 2005 | A1 |
20140187085 | Nishimura | Jul 2014 | A1 |
20170141499 | Mashima et al. | May 2017 | A1 |
Number | Date | Country |
---|---|---|
107069348 | Aug 2017 | CN |
107453079 | Dec 2017 | CN |
2000-067955 | Mar 2000 | JP |
3694485 | Oct 2003 | JP |
2005-085686 | Mar 2005 | JP |
2008-041656 | Feb 2008 | JP |
2017-097972 | Jun 2017 | JP |
Entry |
---|
Notification of Reasons for Refusal (JP Patent Application No. 2018-086068); dated Feb. 18, 2020; 6 pages; Includes English Translation. |
Notifcation of First Office Action (CN Application No. 201910319737.2); dated Jun. 1, 2020; 13 pages. |
Number | Date | Country | |
---|---|---|---|
20190334289 A1 | Oct 2019 | US |