KR200147011Y1 - Wireless probe - Google Patents

Abstract

The present invention relates to a probe (probe) used in measuring the signal in the oscilloscope, and more particularly to a wireless probe without the limitation of the measurement distance. The radio probe comprises a radio receiver on the signal input end side of the oscilloscope, and is equipped with a radio transmitter in a probe for inputting a measurement signal for an object to be measured into the oscilloscope.

Description

Wireless probe

1 is a state diagram used in the conventional probe.

2 is a state of use of the probe according to the present invention.

3 is an internal block diagram of the transmitter and receiver shown in FIG.

* Explanation of symbols for main parts of the drawings

15: wireless probe 17: probe tip

20: transmitting device 21: signal input unit

23: frequency modulator 25, 63: amplification part

27: transmitting unit 30: measured object

60: receiver 61: receiver

65: frequency demodulation section 67: output section

70: antenna 80: antenna wire

100: oscilloscope

The present invention relates to a probe (probe) used in measuring the signal in the oscilloscope, and more particularly to a wireless probe without the limitation of the measurement distance.

Probe is a tool which connects an oscilloscope input part and a to-be-measured object here.

Probes that have been used so far are wired probes as shown in FIG. That is, the probe 10 plays an intermediate role for connecting the oscilloscope 107 and the object under test 30, and thus the probe 17 is connected to the object under test 30. And a connector 45 coupled with the portion 17, the probe lead portion 50, and the input terminal 40 of the oscilloscope 100. Of course, an attenuator portion is also connected between the tip 17 and the lead 57 of the probe 10 to attenuate the input signal as much as desired, and the description thereof will be omitted.

That is, in the related art, when the signal is measured for the object to be measured 30, the instantaneous object 30 and the oscilloscope 100 are electrically connected to each other by using the wired probe 10. The measurement signal was input to the oscilloscope 100 through the lead 50 of the probe 10.

That is, since the oscilloscope and the measured object are connected by the wired probe when measuring the signal on the measured object by the above-described process, the measurement object 30 may be brought directly to the input terminal of the oscilloscope 100. In fact, it's not often possible to do that. Thus, the wired probe 10 used in the related art has a problem in that the distance limit with respect to the lead 50 becomes a problem, and the jamming of the lead according to the wired probe 10 occurs.

Therefore, an object of the present invention is to provide a wireless probe without the limitation of the measurement distance by using a wireless transceiver for measuring the oscilloscope signal.

Wireless probe according to the present invention for achieving the above object, comprising a radio receiving device on the signal input side of the oscilloscope, a radio transmitting device to the probe for inputting the measurement signal for the object to be measured by the oscilloscope It is equipped with a frame.

Hereinafter, a wireless probe frame according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a state diagram of use of the probe according to the present invention, and FIG. 3 is an internal block diagram of the transmitter and the receiver shown in FIG.

First, referring to FIG. 2, referring to a state of use of a wireless probe, a receiver 67 is connected to an input terminal side of the oscilloscope 100. The transmitter 20 is mounted on the probe 15 for measuring a signal to be measured 30 and transmitting it to the oscilloscope.

Therefore, the signal measured by the probe 15 for the measured object is wirelessly transmitted without limiting the measurement distance between the oscilloscope 170 and the object under test 30, and the signal transmitted is the oscilloscope 10 (1). Is received by the receiving device 60).

A process of transmitting a signal measured by the probe 15 for the object to be measured and a process of receiving the signal from the oscilloscope 100 will be described in detail with reference to FIG. 3.

As shown in FIG. 3, the configuration of the probe 15 includes a probe tip 17, a transmitter 20, and an antenna 70, and is connected to an input terminal side of the oscilloscope 100. 60 also connects the antenna wire 80.

The transmitter 20 modulates the signal input unit 21 (which may be considered as a probe tip portion) for inputting a specific signal of the object to be measured 30 and a signal suitable for transmitting the input signal. a modulator 23 for frequency modulation, an amplifier 25 for amplifying the frequency-modulated signal by a predetermined amount, and a transmitter 27 for transmitting a signal.

The receiving device 60 includes a receiving unit 61 for receiving a signal transmitted from the transmitting unit 27 of the transmitting device 20, an amplifying unit 63 for amplifying the received signal, and And a demodulator 65 for frequency demodulating the output signal of the amplifier 63 into the original signal, and an output unit 67 for applying the demodulated signal to the oscilloscope 100.

The process of transmitting and receiving a signal by the above configuration is not different from the process of transmitting and receiving a general signal.

First, the tip 17 of the probe 15 connected to the measurement object 30 inputs a signal while the oscilloscope 100 is ready to receive a signal. The input signal is input to the frequency modulator 23, modulated into a signal suitable for transmission, and the modulated signal is amplified by the amplifier 25 by a predetermined amount and transmitted through the transmitter 27.

The transmitted signal is received by the receiver 61, amplified by the medium width portion 7, and then demodulated into the original signal and applied to the input terminal of the oscilloscope 1 (10).

The signal input to the oscilloscope 100 by the above process is a desired signal measurement is made according to the user's request.

As described above, in the wireless probe according to the present invention, a wired probe for inputting a measurement signal for an object to be measured into the oscilloscope when the signal is measured by a conventional oscilloscope is limited by the measurement distance and the distance to the lead by the lead is The problem is that by using a wireless probe without a lead, the problem is eliminated, and the remote signal measurement is possible, thereby eliminating the need to move the oscilloscope during signal measurement.

Claims (1)

A wireless receiving device connected to the signal input end of the oscilloscope; A radio transmitting device is mounted on a probe for inputting a measurement signal for an object to be measured into the oscilloscope, and the radio transmitting device mounted on the probe includes an input unit for inputting a measurement signal for an object to be measured; A modulator for modulating the input signal into a signal suitable for transmission, the amplifying section amplifying an output signal of the modulating section; A radio receiver configured to transmit an output signal of the amplifier to the radio receiver, the radio receiver being provided on the signal input side of the oscilloscope, the receiver comprising: a receiver for receiving a signal transmitted from the transmitter; An amplifier for amplifying the signal of the receiver; And a demodulator for demodulating the output signal of the amplifier into an original signal and an output unit for applying the output signal of the demodulator to an input terminal of an oscilloscope.