KR101004923B1 - Methode for measuring radio ferequency of wireless device - Google Patents

Abstract

PURPOSE: A method for testing an RF signal of a wireless device is provided to conveniently test the signal without using an additional component for testing performance of the RF signal on a signal line. CONSTITUTION: A series of through-holes is forms on a grounding patterns(131a,133a). Measuring a signal by an RF signal measuring device is conveniently performed through the through-holes. A contact structure of the RF signal measuring device is formed by a pin of spring type, probe structure of a plurality of pin structures, or conductive rubber material. Electrical distance between a signal measuring unit(133) and a grounding short unit(131) on a signal line is defined as a λ/4.

Description

How to test the RF signal of a wireless device {METHODE FOR MEASURING RADIO FEREQUENCY OF WIRELESS DEVICE}

The present invention relates to a method for testing an RF signal of a wireless device, and more particularly, to a wireless device configured to test the performance of an RF signal without adding a separate component on a signal line (or path) through which the RF signal is transmitted. Related to RF signal test method.

In general, a mobile communication system is a communication system for a mobile device such as a person, a car, a ship, a train, an aircraft, and the like, for example, a key phone system, a mobile phone (or a mobile communication terminal), a port phone, an aircraft phone, ( Mobile public telephones, radio paging, wireless telephones, satellite mobile communications, amateur radio and fishing service ships installed on trains, cruise ships and express buses.

Among them, mobile communication terminals are AMPS (Advanced Mobile Phone Service) system using analog method, Code Division Multiple Access (CDMA) system using digital method, Wideband Code Division Multiple Access (WCDMA), TDMA ( Time Division Multiple Access, Time Division Multiple Access (FDMA) system, Frequency Division Multiple Access (FDMA) system, Wireless Local Loop (WLL), CDMA2000-1x, IMT-2000 (International Mobile Telecommunication in the Year 2000, communication services will be received in a variety of ways, including the Global System for Mobile Communications (GSM) and the Global System for Mobile Communication (GSM).

Typically, mobile communication systems include Mobile Switching Center / Visitor Location Register (MSC / VLR), Home Location Register (HLR), Public Switched Telephone Network (PSTN), and Base Station (Basic). It consists of Station Controller / Base station Transceiver System, BSC / BTS) and Mobile Station (MS).

Here, the MSC performs an exchange function, and serves as a road and an intersection of all communication lines.

The HLR is a database where subscriber information is stored, and the VLR is a device that temporarily stores important subscriber information in order to prevent frequent HLR inquiry.

PSTN means the entire telephone network used in homes. Thus, when a user calls a mobile communication terminal of a mobile communication subscriber from a normal home telephone, the home telephone signal is first connected to the PSTN, and then input to the exchange of the mobile communication operator using the telephone number.

The mobile operator's switch calls the mobile communication terminal by inquiring whether the subscriber is a valid subscriber to the HLR and where the subscriber's location is based on the home telephone signal.

The location of the BSC and VLR in terms of systems may vary depending on the equipment manufacturer. For example, the BSC may be in the same spatial location as the MSC or may be in the base station BTS. The base station means that the BSC and the BTS are combined.

On the other hand, a mobile communication terminal having a conventional RF performance test unit includes an antenna switch for the signal is connected to the antenna, a mobile switch that is connected to the antenna switch and provides a frequency path to enable the test of the RF portion by the RF cable; An antenna matching unit connected to the mobile switch, and an antenna connected to the antenna matching unit for transmitting and receiving a signal. In addition, an additional RF cable is connected to the mobile switch to test the performance of the RF section.

Here, the RF cable is connected to the mobile switch from the outside of the mobile communication terminal, and the test is performed by connecting to the measurement equipment of the 8960 model to test the performance of the RF portion of the mobile communication terminal to the RF cable.

In order to test the performance of the RF portion of the mobile communication terminal, a test is performed through an antenna. In the development process, a mobile switch, for example, a connector at the rear end of the antenna is directly connected to a test equipment such as 8960 to obtain accurate measurement values. By arranging and connecting the RF cable which is a coaxial cable, the RF signal radiated to the antenna is checked and checked.

At this time, before the RF cable is connected, the antenna matching part and the antenna switch are electrically connected to each other. When the RF cable is connected to the mobile switch from the outside, the part connected to the antenna is cut off and the external RF cable part is connected to the 8960 device. The test proceeds by connecting.

However, if the mobile switch is used as described above, a hole for connecting an RF cable, which is a coaxial cable for testing, must be formed, and a defect occurs in the design of the mobile communication terminal. This can reduce the reliability of the test or make normal RF operation difficult.

The present invention has been made to solve the above problems, the object of the wireless device that can easily test the performance of the RF signal without configuring a separate component such as a connector on the signal line of the RF signal An RF signal test method is provided.

RF signal test method of a wireless device according to the present invention for achieving the above object is a signal processing unit for processing a signal transmitted and received through the antenna and the antenna to which the signal is transmitted and received, and a signal line connected to the antenna; A grounding short circuit formed on the signal line and checking a transmission / reception state of the signal, and a ground formed on the signal line so as to have an electrical length at a predetermined interval with the signal measuring section, and a ground to which the signal line is grounded; A wireless device comprising a unit, characterized in that it comprises the step of connecting the measurement terminal of the signal measuring device to the signal measuring unit of the wireless device, and shorting the signal line and ground to each other of the ground short.

As a result of the above, the present invention can be easily tested the signal without using a separate component for testing the performance of the RF signal on the signal line to which the RF signal is transmitted as in the prior art.

Hereinafter, the configuration will be described in more detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of a wireless device having an RF performance tester according to the present invention, FIG. 2 is a view showing the RF performance tester of FIG. 1 formed on a substrate, and FIG. A diagram illustrating the distance between ground shorts.

As shown in Figures 1 to 3, the wireless device having an RF performance test unit according to the present invention is connected to the antenna 110 and the antenna 110 by the signal line 111, the signal is transmitted and received, the antenna 110 Antenna switch 140 for controlling the signal transmitted and received by the antenna, and the antenna matching unit 120 provided between the antenna 110 and the antenna switch 140 to match the impedance of the antenna 110 and the antenna switch 140 And a signal measuring unit 133 provided between the antenna matching unit 120 and the antenna switch 140 and connected to an externally provided signal measuring apparatus for checking the transmission / reception state of the signal, and the antenna matching unit 120. ) And a ground short circuit 131 provided between the signal measuring unit 133 and the signal line 111 and the ground when the signal is measured by the signal measuring unit 133.

Here, the wireless device includes a signal processing unit 150, that is, a mobile station modem (MSM) unit for processing a signal received through the antenna 110 and a signal for transmitting through the antenna 110. The mobile terminal may further include a mobile device that receives a control signal and image data provided from the MSM unit and provides the same to a panel.

Substantially, the wireless device having the above-mentioned RF performance test unit 130 constitutes a plurality of circuit units including the MSM unit and is configured on the substrate 100. In this case, the substrate 100 may be formed of various types of substrates such as a printed circuit board (PCB), a flexible circuit board, and a multi-layer circuit board. Can be.

The substrate 100 includes a plurality of signal lines 111 (or signal wirings) formed by patterning copper or aluminum of a conductive material on an insulating layer of an insulating substrate or an insulating sheet, and the signal lines 111. An insulating material such as a solder resist (SR), ie, a first coating layer, is formed on the formed substrate 100 to protect the signal line 111 from the outside.

A plurality of electronic components are formed on the substrate 100 by exposing a part of the signal line 111 to the outside and electrically connecting the signal line 111 to the signal line 111 through soldering.

Of course, the ground patterns 131a and 133a spaced apart from each other along the signal lines 111 are formed on the substrate 100. The ground patterns 131a and 133a are formed at the same time when the signal line 111 of the substrate 100 is formed in the manufacturing process, and thus the ground patterns 131a and 133a may be positioned on the same layer as the signal line 111. .

As such, the ground patterns 131a and 133a formed on the substrate 100 are used for grounding a plurality of circuits, and in the case of a wireless device, also reduce the electromagnetic interference (EMI) of the RF signal.

Furthermore, the ground patterns 131a and 133a of the present invention may form part of the signal measuring unit 133 and serve as a ground for the device for the signal measuring apparatus, and also form part of the ground shorting unit 131. It is used as a short circuit ground that is shorted to the signal line 111 when testing a signal.

At this time, the RF signal line 111 and the ground patterns 131a and 133a constituting the signal measuring unit 133 and the ground shorting unit 131 of the present invention are substantially the signal line 111 and the ground patterns 131a and 133a. It may include a contact portion formed on the). This will be discussed later.

On the other hand, the antenna switch 140 is connected to the MSM unit (or mobile device) may be provided on the substrate 100, more precisely one side of the MSM unit (or mobile device) of the wireless device, such as a mobile communication terminal The other side may be configured on the substrate 100 by being electrically connected to the antenna 110 to which the RF signal is transmitted and received.

At this time, the antenna switch 140 serves to control the transmission signal from the MSM unit (or mobile device) to be output through the antenna 110. For example, when the call function of the mobile communication terminal is set, the MSM unit of the terminal will control the antenna switch 140 to allow a call through the antenna 110.

In addition, according to the control of the antenna switch 140, the mobile communication terminal may be operated in a photographing mode, and the antenna switch 140 may be a combination of a mobile communication terminal (DMB) and a mobile Internet phone (WIBRO). It may be applied in a communication mode and various communication service operations.

The antenna 110 is connected to the antenna matching unit 120 to transmit and receive a signal. In other words, the mobile communication terminal includes an antenna matching unit between the antenna 110 for receiving a radio signal from the outside and the MSM unit for processing the received radio signal, more specifically, between the antenna 110 and the antenna switch 140. 120) is installed.

Through the antenna matching unit 120, each end, that is, the output unit of the antenna 110 to which the received signal is output and the input unit of the antenna switch 140 to which the signal is input, or the output unit and the MSM unit of the antenna 110 The impedance between inputs is matched to buffer the difference in impedance between stages, thereby delivering the maximum signal power. Of course, in the case of a signal transmitted from the MSM unit or the mobile device to the antenna 110, the antenna matching unit 120 is provided between the output unit of the antenna switch 140 (or the MSM unit) and the input unit of the antenna 110. It can be expressed as.

Furthermore, the wireless device according to the present invention includes an RF performance test unit 130 provided between the antenna matching unit 120 and the antenna switch 140 on the path of the RF signal, that is, the RF signal line 111. . At this time, the RF performance test unit 130 is connected to an external RF signal measuring device and the signal measuring unit 133 to measure the signal, and the signal line 111 of the RF signal at the signal measurement in the signal measuring unit 133 ) And the ground pattern 131a are formed of a ground short portion 131 formed to short each other.

The signal measuring unit 133 and the ground shorting unit 131 may include a signal line 111 formed to transmit an RF signal on the substrate 100, and a ground pattern 131a spaced apart from the signal line 111. 133a, wherein the signal measuring unit 133 and the ground shorting unit 131 are contacted by an external signal measuring device by removing a part of the SR coating film on the signal line 111 and the ground patterns 131a and 133a. It includes a contact portion formed to be able to.

Of course, the ground patterns 131a and 133a of the present invention may be formed separately from each other. Accordingly, when the device ground pattern 133a and the short circuit ground pattern 131a are integrally formed on the substrate 100, the signal measuring unit 133 may include the signal line 111 and the ground patterns 131a and 133a. The ground short circuit 131 may include a short circuit device that shorts the signal line 111 and the ground patterns 131a and 133a, but the ground pattern 133a for the device and the ground pattern 133a for the short circuit may be short circuited. When formed separately, the ground shorting part 131 may include a shorting device and a shorting ground pattern 131a.

Furthermore, the signal measuring unit 133 and the ground shorting unit 131 of the present invention may further include a second coating layer filling the contact portion as an anti-oxidation layer. This may prevent corrosion of the signal line 111 and the ground patterns 131a and 133b in the contact portion exposed to the outside for the RF signal test.

As shown in FIG. 2, the contact portion of the present invention may include a series of through holes formed on the ground patterns 131a and 133a, and may facilitate signal measurement from the signal measuring device through the through holes. Can be. For example, the contact structure of the RF signal measuring device for contacting the signal line 111 and the ground patterns 131a and 133a may be a spring-type pin or a probe structure having a plurality of pin structures or using a conductive rubber material. Can be formed.

Above all, in the present invention, when the RF performance test unit 130 is formed on the substrate 100, the distance between the signal measuring unit 133 and the ground shorting unit 131 is adjusted. This is because only by temporarily opening the antenna 110 in the measurement of the RF signal (open), it is possible to accurately test the RF signal.

In this regard, the relationship between the input impedance and the output impedance based on the signal measuring unit 133 will be described with reference to Equation 1 below.

Zin = jZo ＊ tanβ ＊ ｌ

Is the length of the stub, that is, the electrical length between the signal measuring unit 133 and the ground shorting unit 131, β is a phase constant, and j is a phase.

Here, β denotes a phase angle (β = 2π / λg, where λg is a wavelength on the signal line), which is changed while the wave travels the unit length on the signal line (that is, the transmission line), and the unit is rad / m to be. And beta denotes the electrical length of the stub.

Therefore, when the electrical length is θ in Equation 1 above, it may be represented again as in Equation 2 below.

Zin = jZo ＊ tanθ

In the above Equation 1, when the impedance is calculated when? Is λ / 4, 3λ / 4, and 5λ / 4, tan (π / 2), tan (3π / 2), and tan (5π / 2) are infinite. It can be seen that. This means that it is equivalent to an open circuit for that frequency.

Therefore, as shown in FIG. 3, the distance l between the signal measuring unit 133 and the ground shorting unit 131 constituting the RF performance test unit 130 of the present invention is λ / 4, more precisely (2n). +1) λ / 4. Where n is a positive integer including zero.

For example, the wavelength (λ = 1 / f) is determined when the frequency of the RF signal of the mobile communication terminal is 2.4 GHZ. Subsequently, substituting the wavelength value into the above equation results in the signal measuring unit 133 and the ground short unit. The electrical length l between 131 will be approximately 8-9 cm. Of course, this represents the path between the signal measuring unit 133 and the ground shorting unit 131, that is, the electrical length l on the signal line 111.

Therefore, the electrical length l between the signal measuring unit 133 and the ground shorting unit 131 on the signal line 111 may vary depending on the frequency of the RF signal. It will not specifically limit. That is, the electrical length 1 will be determined according to the frequency of the RF signal that allows the ground shorting portion 131 to be equivalent to the open circuit when viewed from the signal measuring unit 133.

Figure 4 (a) is a view showing a state in which the signal line of the ground short and the ground pattern of the ground short section is open to each other, Figure 4 (b) is a ground of the signal line and ground short of the ground short section during RF performance test It is a figure which shows the state in which a pattern was short-circuited.

As shown in FIG. 4A, the ground short portion of the RF performance test unit formed on the initial substrate in the present invention maintains the signal line 111 and the ground pattern 131a open to each other.

And, as shown in (b) of FIG. 4, the signal line 111 and the ground pattern 131a of the ground short circuit unit may be shorted to each other when measuring a signal in the signal measuring unit of the present invention through an RF signal measuring apparatus provided from the outside. do.

In other words, one end of the measuring terminal of the signal measuring device is connected to the signal line 111, the other terminal is connected to the ground pattern 133a, and then the signal line 111 and the ground pattern ( The signal is measured by shorting 131a) with each other.

 As a result, during the RF signal test, a circuit equivalent to a circuit having an open ground short for the corresponding frequency is formed, thereby enabling accurate test of the RF signal.

This may be achieved by contacting the signal line 111 of the ground short portion and the short circuit device 200 separately provided in the RF signal measuring device on the contact portion of the ground pattern 131a.

Therefore, in the present invention, if the signal line 111 and the ground pattern 131a can be shorted to each other through the contact portion, various methods other than the probe type short circuit device 200 may be possible.

As a result, after the test of the RF signal is completed, as shown in FIG. 4A, the signal line 111 and the ground pattern 131a of the ground short portion maintain the open state again.

After that, as described above, a separate second coating layer covering the contact portion of the signal line 111 and the ground pattern 131a may be formed.

Based on the above description, the present invention provides a signal line 111 and a ground pattern 131a of the ground shorting unit 131 by using a separate short circuit device 200 provided from the outside during the RF signal test through the signal measuring unit. ) Short to each other.

However, the present invention is ideally the signal line 111 and the ground pattern 131a of the ground shorting unit 131 during the RF signal test in the signal measuring unit 133 without using a separate short circuit device 200. The short circuiting device 200 is formed on the substrate 100 so as to short-circuit each other.

In addition, the present invention is formed by adjusting the electrical length l between the signal measuring unit 133 and the ground shorting unit 131 according to the frequency of the wireless device.

Accordingly, the present invention may be substituted, modified, and changed in various forms by those skilled in the art without departing from the technical spirit of the present invention.

Therefore, the scope of the present invention should not be limited by the above-described embodiment and the accompanying drawings, but should be defined by the following claims.

1 is a block diagram showing the configuration of a wireless device having an RF performance tester according to the present invention.

FIG. 2 is a diagram illustrating an RF performance test unit of FIG. 1 formed on a substrate. FIG.

3 is a diagram illustrating the distance between the signal measuring unit and the ground short of FIG.

Figure 4 (a) is a view showing a state in which the signal line of the ground short section and the ground pattern of the ground short section is open to each other;

4B is a diagram illustrating a state in which a signal line of the ground short unit and a ground pattern of the ground short unit are shorted during the RF performance test;

DESCRIPTION OF REFERENCE NUMERALS

100: substrate 110: antenna

111: signal line 120: antenna matching unit

130: RF performance test unit 131: ground short

133: signal measuring unit 131a, 133a: ground pattern

140: antenna switch 150: signal processing unit

Claims (2)

An antenna through which signals are transmitted and received, a signal processor connected to each other by a signal line connected to the antenna and processing signals transmitted and received through the antenna, and a signal measuring unit formed on the signal line and checking the transmission / reception state of the signal. And a ground short formed on the signal line to have an electrical length at a predetermined distance from the signal measuring part and having a ground to which the signal line is grounded. Connecting a measurement terminal of a signal measuring device to a signal measuring unit of the wireless device; And Shorting the signal line and ground to each other; RF signal test method of a wireless device comprising a. The method of claim 1, Connecting the measurement terminal of the signal measuring unit to the signal measuring unit of the wireless device Connecting one end of the measurement terminal to the signal line and connecting the other terminal of the measurement terminal to the ground RF signal test method of a wireless device comprising a.

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