KR101907859B1 - The system for digital signal measurement and automatic probe-recognition of logic analyzer using wireless terminal - Google Patents

Abstract

The present invention relates to a digital signal measurement method of a logic analysis measuring device operated in a remote wireless manner through a terminal. More specifically, the present invention relates to a method for probe automatic recognition and digital signal measurement of a logic analysis measuring device using a wireless terminal which automatically recognizes a probe mounted on a measuring device in a wireless terminal and receives a setting value from the logic analysis measuring device when the setting value suitable for the number of recognized probes is transmitted, thereby measuring a digital signal suitable for a condition. The logic analysis measuring device comprises: the probe; a connector; a probe recognizing part; a communication module; and a control logic part.

Description

TECHNICAL FIELD The present invention relates to a method and apparatus for automatically recognizing a probe, a digital signal measuring system, and an automatic probe-recognition of a logic analyzer using a wireless terminal,

The present invention relates to a digital signal measurement method of a logic analysis instrument operating in a remote wireless manner via a terminal. More specifically, when a wireless terminal automatically recognizes a probe mounted on a logic analyzer and transmits a set value suitable for the number of recognized probes, the logic analyzer receives the received probe, The present invention relates to a method of automatically recognizing a probe and a digital signal measuring method of a logic analysis instrument using a terminal.

A logic analyzer is a device that measures digital signals for hardware verification of digital devices as well as for system firmware debugging.

The digital signal measured by the logic analyzer should be able to simultaneously measure multiple digital signals of not less than 1 bit but more than 2 bits. It should not be used to measure the exact voltage value of the digital signal, but rather it should be higher than the set threshold (Mapped to '0').

More specifically, when an oscilloscope is used to view an analog signal waveform, a logic analyzer is used to view the value of the digital signal. That is, it is used to check whether the digital signal is displayed normally as desired.

If you want to check if the data is broken in serial communication, you can not see the waveform when you increase the time step in the oscilloscope. If you decrease the time step, you can see the waveform correctly.

At this time, if you use a logic analyzer, the visible value is a digital value ("L" or "H"), but you can see a large amount of data in a narrow time step.

The logic analyzer is connected to a plurality of probes through a plurality of port channels in advance, and receives digital signals through the probe. The logic analyzer is connected to a predetermined sampling time When it is larger than the reference voltage, which is a threshold value, the operation of converting to '0' is repeatedly performed when the value is '1'.

The logic analyzer determines the channel number of the connected port channels, and then determines the trigger point that determines how the signal of the channel is viewed.

When the measurement is started, the data signal is stored when it meets the trigger point set by the logic analyzer, and then the stored value is displayed when the desired measurement capacity is reached.

In the case of an oscilloscope that measures analog signals, the number of measurement probes is less than 2 or 4 channels, while the logic analyzer uses a larger number of probes than 16 channels, 32 channels, or 128 channels. It has a lot of port channels and it can be used to check the data of multi-channel digital lines at once, so it is used for correlation with other digital signals or for timing check.

Accordingly, a plurality of probes corresponding to the number of port channels prepared for the management efficiency of a plurality of probes is used as a bundle. Since a large number of probes are installed in advance, the process of mounting the probe on the measurement object and the complexity of the connection after mounting are very high.

Furthermore, even if only a part of the probe is used without mounting all probes on the object to be measured, it is cumbersome to manage the remaining unused probes so as not to interfere with the measurement operation in a limited space.

Particularly, in the case of a wireless logic analyzer that physically separates the measuring unit and the display unit and transmits signals wirelessly to each other while ensuring ease of use, unused probes will become more troublesome to conduct the measurement.

In addition, the conventional logic analyzer has the following problems.

1 is a view showing a monitoring screen of a conventional logic analyzer. Referring to the drawings, a conventional monitoring screen displays all the port channels (channels) of a probe connected in advance to the connector as one fixed screen.

For example, for a logic analyzer with 32 channels, all probes are connected and the monitor has a fixed screen with all 32 channels visible.

As shown, in the case of channel 3, channel 5, and channel 7, although the probe signal is not transmitted, basically, the monitor screen of the logic analyzer displays the status of all channels.

Therefore, there is a problem in that it is difficult to find out from the monitor screen which signal of the probe is transmitted from which channel in the multichannel of 32 channels.

Patent Document 1: Korean Patent Registration No. 10-1219101 (registration date: 2013.01.11)

In order to solve the above problems, in the present invention, the probes are prepared in a single housing or in a bundle in a small number of units, and only the port channel recognized is recognized by recognizing the attachment / detachment state of each probe to the connector port terminal of the measurement unit to which the probe is to be mounted And to provide a method of automatically recognizing and measuring a probe so that the probe can be performed.

Another object of the present invention is to provide a method configured to monitor only a corresponding channel when a probe is recognized as being connected to a connector of a logic analysis instrument.

According to an aspect of the present invention, there is provided a digital signal measurement system for a measurement object via a logic analysis instrument, the logic analysis instrument comprising: a probe including a signal measurement terminal mounted on the measurement object and transmitting a digital signal; ; A connector having a pin to which a signal measurement terminal of the probe is connected; A probe recognition unit connected to the pin of the connector to recognize the signal measurement terminal when the terminal is connected to the pin of the connector; A communication module for receiving a signal from the probe recognition unit and transmitting the signal to the terminal; And a control circuitry for measuring a digital signal transmitted from the pin of the connector,
The probe includes three terminals including the signal measurement terminal and two terminals shorted together. The pin of the connector has a connection terminal for signal measurement connected to the signal measurement terminal, The probe identification terminal is configured to be connected to the probe recognition unit while the probe identification terminal is in contact with any one of the terminals, and the terminal is in communication with the communication module and controls the logic analysis instrument. do.

The connector is configured to be independently extendable in a plurality of, and each connector is configured to be connected to the probe recognition unit.

The structure of the connector comprises a pin having three terminals corresponding to each probe,
The three terminals include: a signal measurement connection terminal connected to the signal measurement terminal; A probe recognition terminal connected to the probe recognition section; And a terminal connected to the GND.

A method for automatic recognition of a probe and a digital signal measuring method of a logic analyzer using a wireless terminal according to the present invention includes a probe including a measurement object and a terminal for measuring a signal mounted on the object and transmitting a digital signal, A probe recognition unit connected to the pin of the connector so as to recognize the signal measurement terminal when the terminal for signal measurement is connected to the pin of the connector; a communication unit for receiving a signal from the probe recognition unit and transmitting the signal to the terminal; And a control logic unit for measuring a digital signal transmitted from the pin of the connector, the method comprising the steps of: automatically recognizing a probe of a logic analyzer and using a digital signal measuring system,
Transmitting a signal to the terminal through the communication module when the probe recognition unit recognizes a probe mounted on the connector; Displaying the signal related to the channel number of the probe recognized by the probe recognition unit so that only the signal related to the probe number recognized by the probe recognition unit is monitored on the screen when receiving the signal from the terminal; Transmitting to the control logic unit a setting value that sets a sampling frequency, a trigger condition, and a measurement capacity in consideration of a channel number and a number of probes received from the terminal; The control unit compares the voltage of a signal input from the probe recognized by the probe recognition unit with a predetermined reference voltage at a cycle corresponding to a sampling frequency (time step), and converts the voltage of the signal into '0' Repeatedly performing the steps; Receiving a measurement start signal from the terminal, storing the converted values in a memory if the converted value satisfies a trigger condition; And transmitting the converted values stored in the memory to the terminal at the same time when the converted values satisfy the measured capacity.

Wherein the displaying of the port channel of the connector operates independently so that a signal of the corresponding port channel is generated and displayed in a screen of the terminal in an independent module format whenever the probe is recognized in each port channel of the connector .

The probe recognition unit maintains a high level in a state of being pulled up to a Vcc level. When the probe recognition unit receives a signal from the probe recognition terminal, the probe recognition unit is converted to a low level to determine whether the probe is mounted.

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The following effects can be achieved through automatic recognition of a probe and digital signal measurement system of a logic analyzer using the wireless terminal of the present invention.

It is possible to provide a convenient measuring environment by connecting only the necessary probes by removing the probe which is not used in the measuring part through the present invention and it is possible to measure the digital signal by connecting only the probe necessary for the measuring object, It becomes possible to appropriately manage the probe which has been obstructed in the measurement operation.

In addition, since the screen of the terminal has a fluctuating screen that varies according to the number of port channels of a connector to which a probe is attached rather than a fixed screen as in the conventional art, a screen displayed on the terminal is a probe, And only the signal of the channel of the mounted connector is displayed, so that there is an advantage that it can be monitored more clearly.

1 is a state diagram showing a monitoring screen of a conventional logic analyzer.
2 is a block diagram of a probe automatic recognition and digital signal measurement system of a logic analysis instrument using a wireless terminal according to the present invention.
3 is a state diagram illustrating a method of recognizing a probe mounted on a connector according to an embodiment of the present invention by the probe recognition unit.
4 is a state diagram illustrating a method of recognizing a probe mounted on a connector according to another embodiment of the present invention by a probe recognition unit.
5 to 7 are diagrams showing a monitoring screen of signals received from a plurality of probes in the terminal of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an automatic probe recognition and measurement method of a wireless logic analyzer according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a probe automatic recognition and digital signal measurement system of a logic analysis instrument using a wireless terminal according to the present invention.

Referring to the drawings, the present invention relates to a digital signal measurement system for a measurement object through a logic analysis instrument.

The probe 100 according to the present invention includes a signal measurement terminal 100a mounted with a measurement object and transmitting a digital signal.

The logic analyzer 200 is provided with a connector 210 having pins to which the signal measurement terminal 100a of the probe 100 is connected.

The number of the connectors 210 may be fixed and the number of the probe recognition terminals 210b of the connectors 210 may be all connected to the probe recognition unit 240 And can be continuously expanded independently in a slot format.

Each pin of the connector may be composed of a plurality of terminals 210a, 210b and 210c.

The logic analyzer 200 may further include a probe recognition unit 200 connected to the pin of the connector 210 to recognize the signal measurement terminal 100a of the probe 100 when the probe 100 is connected to the pin of the connector 210 240).

The logic analyzer 200 includes a communication module 250 that receives a signal from the probe recognition unit 240 and transmits the signal to the terminal 300.

The logic analyzer 200 includes a control unit 220 for measuring the digital signal transmitted from the pin of the connector while the signal measuring terminal 100a of the probe 100 is connected to the pin of the connector. do.

The control circuit 220 repeatedly performs the operation of comparing the voltage of the digital signal with the set reference voltage and converting the voltage of the digital signal to '1' when the voltage is greater than the reference voltage and to '0' when the voltage is greater than the reference voltage.

The memory 230 stores the converted value when the conversion value measured by the control logic unit 220 satisfies a set value such as a sampling frequency, a trigger condition, and the like.

In addition, the present invention includes a terminal 300 for controlling the logic analysis instrument 200 while communicating with the communication module.

3 is a state diagram illustrating a method of recognizing a probe mounted on a connector according to an embodiment of the present invention by the probe recognition unit.

Three terminals including two terminals 100b and 100c shorted to each other including the signal measurement terminal 100a are formed in the pin formed in the probe 100. [

The pin of the connector 210 is provided with a signal measurement connection terminal 210a connected to the signal measurement terminal 100a and a probe recognition terminal 210b contacting any one of the two shorted terminals . The probe recognition terminal 210b is configured to be connected to the probe recognition unit 240.

More specifically, the pin of the probe 100 has three terminals, one of which is the signal measurement terminal 100a and the other two terminals of which are mutually short-circuited.

The structure of the connector 210 of the logic analyzer according to the present invention includes a signal measurement connection terminal 210a that constitutes a pin having three terminals corresponding to each probe 100, The other terminal 210b is connected to the probe recognition terminal 210b connected to the probe recognition unit 240 and the last terminal 210c is connected to GND. The terminal 210c of each connector connected to the GND may be shared.

Referring to FIG. 3, the probe recognition unit 240 maintains a state of being pulled up to 5 V, which is a Vcc level. Once received, the probe recognition unit 240 is logicized to be converted into a low level of 0 V when receiving a signal from the probe recognition terminal 210b, And determine whether or not the probe is mounted.

That is, when the probe 100 is not mounted on the connector 210, the probe recognition unit 240 is recognized as a 'high' level by a pullup. When the probe 100 is mounted, the probe recognition unit 240 It is connected to GND and recognizes whether the probe is mounted using the difference recognized as 'low' level.

Hereinafter, the operation of the probe automatic recognition and digital signal measurement system of the logic analysis instrument using the wireless terminal of the present invention will be described.

When the probe recognition unit 240 recognizes the probe 100 mounted on the connector 210, it transmits a signal to the terminal 300 through the communication module 250. In the terminal 300, A trigger condition, and a measurement capacity in consideration of the channel number and the number of probes recognized by the probe recognition unit 240, To the cutting unit (220).

That is, when the probe recognition terminal 210b is connected to the probe recognition unit 240, the probe recognition unit 240 recognizes the presence or absence of the probe mounted on the probe recognition terminal 210b and identifies the channel number and the number of the probe And wirelessly or wiredly transmits information to the terminal 300 through the communication module 250. [

Various methods such as RS-232, RS422, RS-485, and CAN may be used as the wired method of the communication module 250, and Bluetooth, Radio Frequency Identification (RFID) , Infrared data association (IrDA), ultra wideband (UWB), or ZigBee.

The logic analyzer 200 has a control circuit 220 for measuring a digital signal transmitted from the pin of the connector while the signal measuring terminal 100a of the probe 100 is connected to the pin of the connector.

In detail, when measurement is started in the terminal 300, information such as the channel number and the number of probes recognized from the probe recognition unit 240 is received first.

5 to 7 are diagrams showing a monitoring screen of signals received from a plurality of probes in the terminal of the present invention.

The state diagram shows a case where the receiving terminal is a wireless terminal such as a smart phone.

In the present invention, when the probe recognition unit 240 recognizes the probe 100 mounted on the connector 210, the signal is transmitted to the terminal 100 through the communication module 250, When receiving the signal from the terminal 300, only a signal related to the channel number of the probe 100 recognized by the probe recognition unit 240 is monitored on the screen of the terminal 300.

That is, in the present invention, the screen of the terminal 300 is configured to monitor the channel of the probe 100 on the screen only when the probe 100 mounted on the connector 210 is recognized.

In other words, when the probe 100 is mounted on the connector 210 and recognized by the probe recognition unit 240, the probes 100 are displayed on the screen of the terminal 300 for each port channel of the mounted connector 210.

Each port channel of the connector 210 independently operates so that the signal of the port channel is displayed on the screen of the terminal 300 in an independent module format every time the probe 100 is recognized in each port channel of the connector 210 And displayed.

Accordingly, the screen of the terminal 300 expands or shortens the channel according to the number of the port channels of the probe recognized by the probe recognition unit 240, and appropriately displays the corresponding state.

That is, according to the present invention, the screen of the terminal 300 has a variation screen that varies according to the number of the port channels of the connector 210 on which the probe 100 is mounted, The signal on the channel of the connector 210 on which the probe 100 is mounted is displayed instead of the screen of all the channels, so that the screen can be more clearly monitored.

The setting value such as the sampling frequency, the trigger condition, and the measurement capacity is transmitted to the control unit 220 through the wireless communication module 250 in consideration of the channel number and the number of the probe received from the terminal 300.

Upon receiving a set value such as a sampling frequency, a trigger condition, and a measurement capacity from the terminal 300 through the communication module 250 in the control circuit unit 220, the control circuit 220 determines whether the sampling frequency The voltage of the signal input from the probe recognized by the probe recognition unit 240 is compared with the set reference voltage and the operation of converting the signal into '0' when the value is '1' is repeated.

Next, when the measurement start signal is received from the terminal 300, if the converted value satisfies the trigger condition, the converted values are stored in the memory 230.

Next, when the converted values stored in the upper memory 230 satisfy the measurement capacity, the conversion values stored at the same time as the storage is stopped are transmitted to the terminal 300.

4 is a state diagram illustrating a method of recognizing a probe mounted on a connector according to another embodiment of the present invention by a probe recognition unit.

The overall description is the same as described above, and only the probe recognition configuration through the probe 100, the connector 210, and the probe recognition unit 240 will be described.

The probe 100 comprises the signal measurement terminal 100a. The pin of the connector 210 is formed with a signal measuring connection terminal 210a connected to the signal measuring terminal 100a and a switch 210d physically contacting the probe 100. [

As shown in the figure, a signal generated by physically pressing the switch 210d formed on the pin of the connector while the probe 100 is mounted is connected to the probe recognition unit 240 to determine whether the probe is mounted.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, .

100: probe
200: Logic Analyzer 210: Connector
220: control circuit 230: memory
240: probe recognition unit 250: communication module
300:

Claims (7)

A digital signal measuring system for a measurement object via a logic analyzer,
The logic analysis instrument,
A probe mounted on the measurement object and including a signal measurement terminal for transmitting a digital signal;
A connector having a pin to which a signal measurement terminal of the probe is connected;
A probe recognition unit connected to the pin of the connector to recognize the signal measurement terminal when the terminal is connected to the pin of the connector;
A communication module for receiving a signal from the probe recognition unit and transmitting the signal to the terminal; And
And a control circuit for measuring a digital signal transmitted from the pin of the connector,
Wherein the probe comprises three terminals including the signal measurement terminal and two terminals shorted together,
Wherein a pin of the connector is provided with a signal measurement connection terminal connected to the signal measurement terminal and a probe recognition terminal contacting with one of the two shorted terminals so that the probe recognition terminal is connected to the probe recognition section Respectively,
And a terminal for controlling the logic analyzer while communicating with the communication module. The system of claim 1, The method according to claim 1,
Wherein the connector is configured to be independently extendable to a plurality of connectors, and each of the connectors is connected to the probe recognition unit, wherein the probe is automatically recognized and the digital signal is measured by the logic analyzer. The method according to claim 1,
The structure of the connector comprises a pin having three terminals corresponding to each probe,
The three terminals,
A signal measurement connection terminal connected to the signal measurement terminal;
A probe recognition terminal connected to the probe recognition section; And
And a terminal connected to the GND. The automatic signal recognition and digital signal measurement system of a logic analyzer using a wireless terminal. A connector including a pin to which a signal measuring terminal of the probe is connected; a signal measuring terminal connected to the pin of the connector for recognizing the signal; And a controller for receiving a signal from the probe recognition unit and transmitting the signal to the terminal and a control logic unit for measuring a digital signal transmitted from the pin of the connector, A method for automatic recognition of a probe and a digital signal measuring system of a logic analyzer,
Transmitting a signal to the terminal through the communication module when the probe recognition unit recognizes a probe mounted on the connector;
Displaying the signal related to the channel number of the probe recognized by the probe recognition unit so that only the signal related to the probe number recognized by the probe recognition unit is monitored on the screen when receiving the signal from the terminal;
Transmitting to the control logic unit a setting value that sets a sampling frequency, a trigger condition, and a measurement capacity in consideration of a channel number and a number of probes received from the terminal;
The control unit compares the voltage of a signal input from the probe recognized by the probe recognition unit with a predetermined reference voltage at a cycle corresponding to a sampling frequency (time step), and converts the voltage of the signal into '0' Repeatedly performing the steps;
Receiving a measurement start signal from the terminal, storing the converted values in a memory if the converted value satisfies a trigger condition; And
And transmitting the stored conversion values to the terminal when the converted values stored in the memory satisfy the measurement capacity. The method as claimed in claim 1, Signal measuring method. 5. The method of claim 4,
Wherein the displaying comprises:
Wherein each port channel of the connector independently operates so that a signal of the corresponding port channel is generated and displayed on the screen of the terminal in an independent module format whenever the probe is recognized in each port channel of the connector. Automatic recognition of probe and digital signal measurement method of logic analysis instrument using terminal. 5. The method of claim 4,
Wherein the probe recognition unit is maintained at a high level in a state of being pulled up to a Vcc level, and when the signal is received from the probe recognition terminal, the probe recognition unit is converted to a low level to determine whether the probe is mounted. Automatic recognition and digital signal measurement method. A digital signal measuring system for a measurement object via a logic analyzer,
In the logic analysis instrument,
A probe mounted on the measurement object and including a signal measurement terminal for transmitting a digital signal;
A connector having a pin to which a signal measurement terminal of the probe is connected;
A probe recognition unit connected to the pin of the connector to recognize the signal measurement terminal when the terminal is connected to the pin of the connector;
A communication module for receiving a signal from the probe recognition unit and transmitting the signal to the terminal; And
And a control circuit for measuring a digital signal transmitted from the pin of the connector,
And a terminal for communicating with the communication module and controlling the logic analysis instrument,
Wherein the probe comprises the signal measuring terminal,
Wherein a pin of the connector is constituted by a signal measuring connection terminal connected to the signal measuring terminal and a switch physically contacting the probe,
Wherein the controller is configured to determine whether the probe is mounted while the signal generated by pressing the switch is connected to the probe recognition unit.

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