KR200262543Y1 - RF connector in mobile phone - Google Patents

Abstract

The present invention relates to an inspection RF connector used for a printed circuit board of a mobile communication device, wherein the widths of the connection terminal 1 and the guide terminal 2 of the RF connector are equally set over predetermined intervals X1 to X3, respectively. The widths of the connection terminal 1 and the guide terminal 2 are impedance matching between the pin 3 of the supply connector inserted into the RF connector and the RF connector during the performance test of the mobile communication device. It is characterized in that it is set based on matching, it is possible to not only enable more accurate performance test of the mobile communication device, but also easy to assemble in the manufacturing process of the RF connector, it is effective in reducing the defective rate during mass production.

Description

RF connector in mobile phone

The present invention relates to an inspection RF connector used in a printed circuit board of a mobile communication device.

In general, when a mobile communication device such as a personal communications services (PCS) phone is shipped from a factory, an inspection for checking an operation state of the mobile communication device is required.

In addition, when a function is degraded even while using a mobile communication device, an inspection is required to identify the cause of the malfunction and to repair or replace it.

In these cases, it is checked whether each circuit of the printed circuit board mounted inside the mobile communication device is normally operated. In this case, the printed circuit board (or 'PCB (Printed Circuit Board) board) of the mobile communication device shown in FIG. By using the RF connector A mounted on the circuit board, the respective circuits of the PCB substrate (duplexer 10, band filter IF 11a, 11b, modem 12, control unit 13). ), The performance of the data processor 14 and the voice processor 15 is examined.

That is, the RF connector A includes a contact terminal 1 and a guide terminal 2. When a telephone call is made using a mobile communication device, as shown in FIG. One end of 1) maintains a short circuit state with one end of the guide terminal 2, and the guide terminal 2 is connected to the antenna unit again.

On the other hand, when inspecting the mobile communication device, as shown in FIG. 2B, the F-type connector pin 3 is connected to the RF connector A so that one end of the connection terminal 1 and the guide terminal 2 which are kept short-circuited. One end of the switch is switched to an open state, and the inspection RF signal input from the outside through the inserted F-type connector pin 3 passes through the connection terminal 1 to the respective circuits 10 to 15 of the PCB board. Supplied.

When the RF signal for inspection is supplied to each of the partial circuits 10 to 15 of the PCB substrate in this manner, the inspector contacts the test probe with the input / output terminals of each of the partial circuits 10 to 15 to make contact therewith. By checking the signal detected from the waveform or a specific value (for example, voltage, current, power, etc.) displayed on the screen of the tester, if the inspection RF signal is confirmed normally, it is determined that the performance of the corresponding circuit is normal. do.

However, the test RF signal is supplied at a high frequency of about 870 MHz when the mobile communication device is a cellular phone and about 1840 MHz when the PCS phone is connected to the F-type connector pin-connection terminal-PCB substrate (X1). Due to complicated and various attenuation factors such as length and width of connecting terminal and guide terminal, separation distance between connecting terminal and guide terminal, it is impossible to produce domestically in domestic. It was a situation.

Accordingly, the present invention has been made to solve the above-mentioned problems, and based on impedance matching between a supply connector (F-type connector) and an RF connector for supplying an inspection RF signal, the connection terminal and the guide terminal in the RF connector It is an object of the present invention to provide an RF connector of a mobile communication device in which the width is set to be uniform in the propagation paths X1 to X3 so that the inspection RF signal can be transmitted with a minimum amount of attenuation.

1 shows a printed board of a mobile communication device equipped with an RF connector,

2A is a cross-sectional view of a state in which an F-type connector is not connected to an RF connector,

Figure 2b is a cross-sectional view of the F-type connector is connected to the RF connector,

2c is a rear view of the RF connector,

3A is a plan view of a conventional RF connector (connection terminal),

3b is a plan view of an RF connector (connection terminal) according to the present invention,

4A is a plan view of a conventional RF connector (guide terminal),

Figure 4b is a plan view of the RF connector (guide terminal) according to the present invention,

5 is a partially separated perspective view of the RF connector according to the present invention.

<Code Description of Main Parts of Drawing>

1: Connection terminal 2: Guide terminal

3: Pin of F type connector (Supply connector)

A: RF Connector

As one embodiment of the present invention for achieving the above object, the invention described in claim 1, in the RF connector of the mobile communication device, of the connection terminal 1 and the guide terminal 2 of the RF connector (A) The width of the mobile communication device provides an RF connector, characterized in that evenly set over a predetermined period (X1 to X3).

In addition, according to the invention of claim 2, in the first aspect, the width of the connection terminal 1 and the guide terminal 2, the supply connector is inserted into the RF connector (A) during the performance test of the mobile communication device An RF connector of a mobile communication device, characterized in that it is set based on impedance matching between pin 3 and RF connector A, solves the above-mentioned problems.

In the invention described in claim 3, the width W _C and W _{G of} the connection terminal 1 and the guide terminal 2 are set equal to each other in the RF connector of the mobile communication device. As a solution to the above problem,

In addition, according to the invention of claim 4, the width W _C , W _{G of} the connecting terminal 1 and the guide terminal 2 is connected to the pin 3 of the supply connector according to claim 1 or 2. An RF connector of a mobile communication device, which is set based on a characteristic impedance value at a short-circuit point X1 between the other ends of the terminal 1, solves the above problem.

In addition, according to the invention of claim 5, the width W _C , W _{G of} the connecting terminal 1 and the guide terminal 2 is the pin 3 and the guide terminal ( The above-mentioned problem is solved by the RF connector of a mobile communication device, which is set based on the separation distance h).

In addition, the invention described in claim 6 is an RF connector of a mobile communication device according to claim 5, wherein the supply connector is an F-type connector.

The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

In this embodiment, it is assumed that the supply connector for supplying the inspection RF signal is an F-type connector.

3b and 4b are plan views of the RF connector according to the present invention, which correspond to the connection terminal 1 and the guide terminal 2, respectively, as shown in the widths in the sections X1-X2-X3 W _C and W It can be seen that _G is uniform.

In addition, as in the present embodiment, W _C and W _G may be equally set to the value of W, and FIG. 5 is a partially separated perspective view of the RF connector A according to the present embodiment devised as described above.

Hereinafter, the setting process of W will be described in detail with reference to the accompanying drawings.

FIG. 2B is a cross-sectional view of the state in which the F-type connector pin 3 is connected to the RF connector A. The inserted F-type connector pin 3 is shorted in contact with one end of the connection terminal 1 below. The upper side of the guide terminal 2 is connected to the insulator of the central portion of the one end of the guide terminal 2 and is substantially opened with the guide terminal 2. 2C is a rear view of the RF connector A. FIG.

At this time, the inspection RF signal supplied through the F-type connector pin 3 passes through the propagation paths X1 to X3 through one end of the connection terminal 1 in a short circuit state (Fig. 1 to 10 to 15. In order to reduce the amount of power attenuation of the inspection RF signal in the propagation paths X1 to X3, the F-type connector pin 3 and the RF connector A structurally perform impedance matching. Should be done.

In more detail, impedance matching should be made at the short-circuit point X1 to which the F-type connector pin 3 and one end of the connection terminal 1 of the RF connector A are connected, preferably at the short-circuit point X1. It is required to change the structure of the RF connector A so that the characteristic impedance is 50 kHz.

Therefore, it is assumed that the connection terminal 1 and the guide terminal 2 corresponding to the structure of the RF connector A are waveguides or parallel plates through which the RF signal for inspection supplied through the F-type connector pin 3 is propagated. The width W of the connecting terminal and the guide terminal can be calculated by substituting the separation distance h of the F-type connector pin 3 and the guide terminal 2 and the characteristic impedance value of 50 kV into the following formula (1).

Characteristic impedance ≒ {(permeability of air x specific permeability of medium) / (dielectric constant of air x relative permittivity of medium)} ^1/2 × separation distance (h) / width (W) Equation (1)

Here, the width of the connection terminal and the guide terminal means the length of the connection terminal and the guide terminal in a direction perpendicular to the direction in which the F-type connector pin is connected.

The present invention is not limited to the embodiments described above, it can be variously modified and changed by those skilled in the art, which is included in the spirit and scope of the present invention defined in the appended claims.

As described above, the present invention is to ensure a stable connection between the RF connector and the F-type connector during the performance test of the mobile communication device, the test RF signal supplied through the F-type connector is transmitted by the minimum power attenuation By doing so, there is an effect of enabling a more accurate performance check.

In addition, the present invention is easy to assemble in the manufacturing process of the RF connector is effective in reducing the failure rate during mass production.

Claims (6)

In the RF connector of a mobile communication device, The width of the connection terminal (1) and the guide terminal (2) of the RF connector (A) is set equally over the predetermined interval (X1 to X3), respectively, RF connector of the mobile communication device. The width of the connection terminal 1 and the guide terminal 2, according to claim 1, When the performance test of the mobile communication device, the mobile communication, characterized in that set based on the impedance matching (impedance matching) between the pin (3) of the supply connector inserted into the RF connector (A) and the RF connector (A) RF connector on the device. The RF connector as set forth in claim 2, wherein the widths W _C and W _{G of} the connection terminal (1) and the guide terminal (2) are set to be the same. The width W _C and W _{G of} the connecting terminal 1 and the guide terminal 2 is different from that of the pin 3 and the connecting terminal 1 of the supply connector. RF connector of a mobile communication device, characterized in that set based on the characteristic impedance value at the short-circuit point (X1) between stages. 5. The width W _C and W _{G of} the connecting terminal 1 and the guide terminal 2, RF connector of the mobile communication device, characterized in that further set based on the distance (h) between the pin (3) and the guide terminal (2) of the supply connector. 6. The RF connector of claim 5, wherein the supply connector is an F-type connector.