KR200334548Y1 - Power sensor - Google Patents

Abstract

The present invention displays and outputs the signal level of the main signal line through the power display means without physically branching the main signal line for which power level measurement is desired, so that the user can easily check the signal level state of the corresponding signal line. It relates to a power sensor.

According to the present invention, the power detector includes a first signal line L1 of a metal connected to a main signal line and a second signal line L2 of a metal in parallel to the first signal line L1 and a first signal. Branch means 110 receives a predetermined level of induced current induced by a magnetic field change from the line L1 to the second signal line L2, and attenuates the signal provided from the second signal line L2 by a predetermined level. Attenuating circuit 120 for converting, signal converting means D for converting an AC signal applied from the attenuating circuit 120 into a DC signal, and flattening and outputting a DC signal output from the signal converting means D And a power display means 140 for displaying and outputting a signal power level corresponding to the signal applied from the smoothing circuit 130.

Description

Power sensor {Power sensor}

The present invention displays and outputs the signal level of the main signal line through the power display means without physically branching the main signal line for which power level measurement is desired, so that the user can easily check the signal level state of the corresponding signal line. It relates to a power sensor.

In a communication system, it is necessary to constantly maintain a constant signal level input and output through the communication element to facilitate its driving.

For example, a wireless communication system amplifies a signal received from a base station and transmits the signal received from a base station to a wireless terminal in a shaded area or to receive a signal from a wireless terminal in a shaded area. Wireless repeaters that amplify signals and transmit them to base stations are installed and operated in the shaded area.

On the other hand, in a region such as a building of a predetermined size or more, the wireless relay apparatus is authorized through the interface unit 11 from the base station as shown in FIG. 1 to perform the radio relay process for the corresponding region through one wireless relay apparatus. In the amplification unit 13 to amplify the forward signal to be provided to the terminator 12, the signal output from the amplifying unit 13 is branched to a plurality of terminators 12 are distributed and installed in different locations Each configured to provide.

At this time, the signal provided from the amplifier 13 is a signal of a predetermined level is branched to the plurality of branch means 20 is provided to each end device (12). The signal branched through the branching means 20 is wirelessly transmitted to cover a certain service area through the terminator 12.

By the way, the terminator 12 should always maintain a constant signal level enough to provide a relay service for a certain area. At this time, when the amplification level of the amplifier is changed or the signal level branching from the branch means 20 is not constant, the terminal device 12 may not be able to smoothly provide a relay service for a prescribed area. . That is, the communication equipment as described above needs to monitor the signal level transmitted through the main signal line and maintain the signal of a constant power level at all times through the corresponding signal line.

Accordingly, the signal level of the main signal line may be measured by physically branching the signal from the main signal line by using a divider and combining the branched signal with an external power measuring device. Internal noise may be generated by branching connection points, which may cause a problem of degrading signal quality.

The present invention has been devised in view of the above circumstances, and provides a power sensor that can display and output the signal level of the main signal line by branching the signal of the main signal line by a certain amount so as not to degrade the signal quality of the main signal line. Has its technical purpose.

1 is a diagram showing a configuration of a general wireless relay device.

2 is a view showing the configuration of a power sensor according to the present invention.

Figure 3 shows an embodiment of the branching means shown in Figure 2;

******* Brief description of the main parts of the drawing *******

110: branch means, 120: attenuation circuit,

130: smoothing circuit, 140: power indicator,

L1, L2: signal line, Z ₀ : characteristic impedance,

R1, R2, R3: Resistor, VR: Variable Resistor,

L: inductor, C: capacitor,

D: diode.

The power sensor according to the present invention for achieving the above object is parallel to the metallic first signal line (L1) connected to the main signal line and the metallic second signal line (L2) parallel to the first signal line (L1). The branching means 110 receiving a predetermined level of induced current induced by a magnetic field change from the first signal line L1 to the second signal line L2 and from the second signal line L2. Attenuation circuit 120 for attenuating a predetermined level of the signal, a signal conversion means D for converting an AC signal applied from the attenuation circuit 120 into a DC signal, and a DC signal output from the signal conversion means D And a power display means 140 for displaying and outputting a signal power level corresponding to the signal applied from the smoothing circuit 130.

In the power detector, the attenuation circuit 120 has a resistor R1, a variable resistor VR, and a resistor R2 coupled to the second signal line L2 in a π type, and the signal converting means D ) Is composed of a rectifying diode (D), the smoothing circuit 130 is characterized in that the resistor (R3) and the capacitor (C) is coupled in parallel to the output terminal of the rectifying diode (D).

In addition, the power sensor is characterized in that the impedance matching inductor (L) is connected in parallel between the output terminal of the attenuation circuit 120 and the input terminal of the signal conversion means (D).

That is, according to the present invention, by receiving a signal derived from the first signal line for power measurement as the second signal line and displaying and outputting the signal level transmitted from the first signal line, the user is in a signal power state of the first signal line. It can be easily confirmed.

Hereinafter will be described an embodiment according to the present invention.

2 is a view showing the configuration of a power sensor according to the present invention.

As shown in FIG. 2, the power detector branches a signal of a predetermined level from the main signal line through the branching means 110, converts the branched signal into a DC component, and then branches the signal level to the power display unit 140. Is configured to display output.

That is, the branching means 110 is formed by arranging a metallic first signal line L1 connected to the main signal line and a metallic second signal line L2 in parallel with the first signal line L1. When a current is applied to the first signal line L1, a change in the magnetic field occurs around the first signal line L1, and thus, a induced level of a predetermined level is induced to the second signal line L2. At this time, the induced current level induced in the second signal line L2 is changed by factors such as the distance between the first signal line L1 and the second signal line L2 or the area of the parallel portion. The characteristic impedance Z of the ground terminal of the second signal line L2 is set to, for example, 50Ω. 3 is a diagram illustrating the configuration of the branching means 110 in the case where the main signal line is configured in a specific device, for example, the filter F. As shown in FIG. That is, as shown in FIG. 3, the branching means 110 is installed to arrange the resonator of the filter F, that is, the second signal line L2 in parallel with the first signal line L1. One end of the second signal line L2 may be configured to be coupled to the SMA port 111 that is electrically coupled to the attenuation circuit 120 through the filter F.

On the other hand, an induced current induced from the first signal line L1 to the second signal line L2 in the branching means 110 is applied to the attenuator 120.

The attenuator 120 combines a resistor R1, a variable resistor VR and a resistor R2 on the signal line coupled to the second signal line L2 in a π form. At this time, the user adjusts the variable resistor VR so that the signal applied from the second signal line L2 is attenuated and outputted to a signal level of the displayable range of the power display means described later. That is, the signal applied from the second signal line L2 is attenuated to a signal level corresponding to the values of the resistors R1 and R2 and the variable resistor VR and applied to the anode terminal of the diode D.

The diode D is a rectifier diode, and converts an AC signal applied from the attenuator 120 into a DC signal to provide the smoothing circuit 130. In this case, an impedance matching inductor L having one end grounded between the attenuator 120 and the anode end of the diode D is coupled in parallel.

The smoothing circuit 130 is composed of a resistor (R3) and a capacitor (C) coupled in parallel to the cathode terminal of the diode (D), respectively, to remove the ripple component of the DC signal output from the diode (D) stable characteristics It provides a direct current signal having a power display unit 140.

The power display unit 140 is for displaying a power level corresponding to the DC signal applied through the smoothing circuit 130 and may be implemented as, for example, a micro pamper meter.

That is, in the above embodiment, the signal derived from the first signal line for power measurement is supplied to the second signal line to display and output the signal level transmitted from the first signal line.

Therefore, by displaying the signal level transmitted from the main signal line by using the signal derived from the main signal line due to the magnetic characteristics, the user can easily check the current signal level without causing a deterioration of the signal quality by using the physical device. It is possible to do.

On the other hand, the present invention is not limited to the above embodiments and can be variously modified within the scope without departing from the technical spirit of the present invention.

As described above, according to the present invention, a signal obtained by using a physical device is provided by receiving a signal emitted from a first signal line for power measurement as a second signal line and displaying and outputting a signal level transmitted from the first signal line. The user can easily check the signal power state of the first signal line without causing a deterioration in quality.

Claims (3)

The magnetic field changes from the first signal line L1 by arranging the metallic first signal line L1 connected to the main signal line and the metallic second signal line L2 in parallel with the first signal line L1. Branching means (110) receiving a predetermined level of induced current induced by the second signal line (L2), An attenuation circuit 120 for attenuating the signal provided from the second signal line L2 by a predetermined level; Signal conversion means (D) for converting an AC signal applied from the attenuation circuit 120 into a DC signal, Smoothing circuit 130 for flattening and outputting the DC signal output from the signal conversion means (D), And a power display means (140) for displaying and outputting a signal power level corresponding to the signal applied from the smoothing circuit (130). The method of claim 1, The attenuation circuit 120 has a resistor R1, a variable resistor VR, and a resistor R2 coupled to the second signal line L2 in a π type. The signal conversion means (D) is a rectifying diode (D) is configured such that the attenuation circuit 120 is coupled to its anode end, The smoothing circuit 130 is a power sensor, characterized in that the resistor (R3) and the capacitor (C) is coupled in parallel to the cathode terminal of the rectifying diode (D). The method of claim 1, And an impedance matching inductor (L) having one end grounded in parallel between the output terminal of the attenuation circuit (120) and the input terminal of the signal conversion means (D).