JP2019036118A - measuring device - Google Patents

Abstract

To make it possible to generally manage unique information of a signal input device connected to a measuring device.SOLUTION: A measuring device includes a connector to be connected to a signal input device to which a RF tag for recording an identifier is attached as many as a plurality of channels. The measuring device includes an antenna for performing radio communication with an RF tag for each channel.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a measuring apparatus that performs non-contact communication with a signal input device.

  A measuring device such as a waveform measuring device represented by an oscilloscope, a power measuring device, and a data collecting device is used by connecting a signal input device such as a measuring probe and a measuring cable to the measuring device main body. Hereinafter, a case where a measurement probe is used as the signal input device will be described as an example.

  When the measurement probe is connected to the measurement device, the characteristics of the measurement device main body are adjusted according to the frequency characteristics of the measurement probe. For example, Patent Document 1 describes that a memory in which frequency response data is recorded is provided in a measurement probe, and the characteristics are automatically adjusted according to the frequency response data acquired from the measurement probe memory by the measurement apparatus. ing.

  In addition, as a technology related to providing a memory in a signal input device such as a measurement probe, Patent Document 2 includes a memory in a probe card and records information such as a unique number of the probe card and the total number of contacts in the memory. It is described to do.

  As described above, by mounting the memory in the signal input device, it is possible to manage information unique to each signal input device.

JP 2002-202325 A JP-A-5-297021

  In order to access a memory provided in a signal input device such as a measurement probe, it is necessary to supply power between the measurement apparatus and the signal input device. Cannot be applied as is.

  Even if an active measurement probe or measurement cable is used, unique information cannot be managed unless the model is pre-installed with a memory.

  SUMMARY OF THE INVENTION An object of the present invention is to enable general management of specific information of a signal input device connected to a measuring apparatus.

In order to solve the above problems, a measurement apparatus according to the present invention is a measurement apparatus having a plurality of connectors for connecting to a signal input device to which an RF tag having an identifier recorded is attached, and performs wireless communication with the RF tag. An antenna is provided for each channel.
Here, the antenna may be disposed around the connector.
At this time, the antenna may surround the connector.
Further, the antenna can periodically communicate with the RF tag.

  According to the present invention, it is possible to manage the unique information of the signal input device connected to the measuring apparatus for general purposes.

It is a block diagram explaining the measuring apparatus and measuring probe which concern on this embodiment. It is a figure which shows the example of attachment to the measurement probe of RF tag. It is a figure which shows the antenna arrange | positioned around the connector. It is a figure which shows the antenna arrange | positioned around the connector. It is a figure which shows the example which provided the wall in the upper and lower sides around the connector, and has arrange | positioned the antenna. It is a figure which shows the example which provided the wall surrounding the circumference | surroundings of a connector and has arrange | positioned the antenna.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a measurement apparatus 100 and a measurement probe 200 according to this embodiment. The measurement probe 200 is an example of a signal input device, and may be, for example, a measurement cable. The measurement probe 200 may be either an active type or a passive type.

  The measurement apparatus 100 includes a plurality of channels, and in the example of this figure, the measurement probe 200 is connected to the connector 107 of the channel Ch-D. Note that although attention is paid to the channel Ch-D and detailed description of the channels Ch-A to Ch-C is omitted, the same configuration as that of the channel Ch-D can be adopted.

  In the present embodiment, an RF tag 210 that records an identifier is attached to the measurement probe 200. The RF tag 210 may be embedded in the measurement probe 200 or may be attached to the outside. Information other than the identifier may be recorded. For example, information regarding the characteristics of the measurement probe 200, information regarding measurement, information regarding correction, manufacturing information, and the like.

  FIG. 2 is a diagram illustrating an example of attaching the RF tag 210 to the measurement probe 200. 2A to 2C are examples in which the RF tag 210 is embedded in the connector portion 201 of the measurement probe 200, and FIG. 2B shows a case where the RF tag 210 is arranged in the circumferential direction of the connector portion 201. 2B shows a case where the connector portion 201 is arranged in the longitudinal direction.

  FIGS. 2D and 2E show examples in which the RF tag 210 is attached to the measurement probe 200 by using a flexible material such as rubber or a tie wrap 203. FIG. FIG. 2E shows the case where the cable portion 202 is attached. As described above, the RF tag 210 can be attached to the measurement probe 200 later.

  In any case, the type of the RF tag 210 is not limited, and may be, for example, an IC tag or a coil type. However, a passive tag type that does not require a power supply is used.

  Returning to the description of FIG. 1, the measuring apparatus 100 includes a control unit 101, a calculation unit 102, an analog input circuit 103, a memory 104, a power source 105, a display unit 106, a connector 107, a transmission / reception circuit 108, and an antenna 109.

  Non-contact communication with the RF tag 210 attached to the measurement probe 200 connected to the connector 107 is performed by the transmission / reception circuit 108 and the antenna 109. In addition to reading data recorded in the RF tag 210, data may be written.

  As a non-contact communication method, for example, an HF band such as ISO / IEC14443 or ISO / IEC15693 which is an RFID standard can be used. Considering interference between channels, the communication distance is preferably about 10 mm to 20 mm. Communication between the RF tag 210 and the antenna 109 can be, for example, an electromagnetic induction method.

  The analog input circuit 103 inputs an analog signal measured by the measurement probe 200, converts it into a digital signal, and transmits it to the calculation unit 102. In the memory 104, data used for calculation processing of measurement data based on information acquired from the RF tag 210 of the measurement probe 200 is recorded. For example, correction values and parameters for each measurement probe 200 are used.

  For example, when an identifier is recorded in the RF tag 210, a correction value or the like for each individual measurement probe 200 can be recorded in the memory 104. Further, when the frequency characteristic is recorded in the RF tag 210, the memory 104 can record an adjustment value or the like according to the frequency characteristic.

  The calculation unit 102 performs a predetermined calculation on the analog value acquired from the analog input circuit based on the information recorded in the RF tag 210 acquired from the transmission / reception circuit 108 and the information recorded in the memory 104, and measured. Calculate the value.

  The control unit 101 displays the measurement values calculated by the calculation unit 102 on the display unit 106 such as a liquid crystal display device as waveform data.

  The transmission / reception circuit 108 receives power from the power source 105 and communicates with the RF tag 210 via the antenna 109. The transmission / reception circuit 108 detects the attachment / detachment of the measurement probe 200 by periodically communicating. The antenna 109 may be the same potential as the analog signal potential or may be insulated.

  When the transmission / reception circuit 108 detects that the measurement probe 200 is connected, the transmission / reception circuit 108 reads out the identifier from the RF tag 210, outputs the identifier to the computing unit 102, and records it in the memory 104. It is also possible to detect that the measurement probe 200 has been replaced by comparing the identifier recorded in the memory 104 with the identifier periodically acquired from the RF tag 210.

  The antenna 109 is disposed around the connector 107. As a result, erroneous communication with the RF tag 210 of the measurement probe 200 connected to the connector 107 of another adjacent channel is prevented.

  Specifically, as shown in FIG. 3, the antenna 109 is arranged so as to surround the connector 107. Here, the connector 107 is generally a BNC connector, but may be of other types. FIG. 4 is a layout diagram of the antenna 109 viewed from the connection direction with the measurement probe 200. Thereby, in addition to preventing miscommunication with another channel, 360 degree directivity around the connector 107 can be realized, so that the degree of freedom of the attachment position of the RF tag 210 of the measurement probe 200 can be increased.

  When the connectors 107 for each channel are arranged in the horizontal direction, as shown in FIG. 5, a wall 120 is formed in the vertical direction of the connector 107, and the antenna 109 is sandwiched between the walls 107 inside the both walls 120. May be arranged. This reduces the antenna sensitivity in the horizontal direction and prevents communication with the RF tag 210 of the measurement probe 200 connected to the adjacent connector 107 of another channel.

  Alternatively, as shown in FIG. 6, a wall 130 surrounding the periphery of the connector 107 may be formed, and the antenna 109 may be disposed inside the wall 130. The shape of the wall 130 is not limited to an annular shape, and may be a polygonal annular shape. Also in this case, since the directivity of 360 degrees around the connector 107 can be realized, the degree of freedom of the attachment position of the RF tag 210 of the measurement probe 200 can be increased.

  As described above, since the measurement apparatus 100 according to the present embodiment can communicate with the measurement probe 200 to which the RF tag 210 is attached, the unique information of the measurement probe 200 can be managed for a general purpose.

  In addition, since the antenna 109 for communicating with the RF tag 210 is disposed around the connector 107, communication with the RF tag 210 of the measurement probe 200 connected to the connector 107 of another adjacent channel is prevented. It is out.

DESCRIPTION OF SYMBOLS 100 ... Measuring apparatus, 101 ... Control part, 102 ... Operation part, 103 ... Analog input circuit, 104 ... Memory, 105 ... Power supply, 106 ... Display part, 107 ... Connector, 108 ... Transmission / reception circuit, 109 ... Antenna, 120 ... Wall , 130 ... wall, 200 ... measurement probe, 201 ... connector part, 202 ... cable part, 203 ... tie wrap, 210 ... RF tag

Claims (4)

A measuring apparatus comprising a plurality of channels for connecting to a signal input device to which an RF tag having an identifier recorded is attached,
A measuring apparatus comprising an antenna for performing wireless communication with the RF tag for each channel.   The measuring apparatus according to claim 1, wherein the antenna is arranged around the connector.   The measuring apparatus according to claim 2, wherein the antenna surrounds the connector.   The measurement apparatus according to claim 1, wherein the antenna periodically communicates with the RF tag.