JP7229983B2 - Waveform observation device and waveform observation method - Google Patents

Description

The present invention relates to a waveform observation apparatus and a waveform observation method for converting a signal under measurement input as an optical signal from an object under measurement into an electrical signal and observing the waveform thereof.

For example, as a measurement system used in the inspection stage of optical devices (or optical modules) such as optical transceivers and optical interfaces, a system configuration using a sampling oscilloscope (Sampling Oscillo Scope) 60 as shown in FIG. 8 is known. ing. In this system configuration, a device under test (DUT) 70 is, for example, an optical transceiver, which is attached (connected) to an evaluation board 70A during testing.

In the system configuration shown in FIG. 8, a signal generator (Pulse Pattern Generator: PPG) 67 sends a data signal (Data) to the DUT 70 . The DUT 70 receives the data signal from the PPG 67 , outputs the data signal as an optical signal to the sampling oscilloscope 60 , and also outputs a trigger clock signal to the sampling oscilloscope 60 . The sampling oscilloscope 60 converts the data signal input as an optical signal into an electrical signal by an optical/electrical converter (O/E) 61 and sends it to the sampler 62, while the trigger clock signal input from the DUT 70 Based on this, the sampling pulse generator 63 generates a sampling pulse and inputs it to the sampler 62 . The sampler 62 samples the data signal sent by the O/E 61 at a sampling timing corresponding to the sampling pulse from the sampling pulse generator 63, and the signal waveform processor 64 performs waveform analysis processing on the data signal. Waveform observation is performed by displaying the results of waveform analysis processing on a display unit (not shown).

Equipped with an optical signal input device (equivalent to a photoelectric converter (O/E)) that converts an optical signal into an electrical signal, the electrical signal is amplified by an amplifying means and displayed as an optical signal waveform on a Braun tube for optical signal observation. A device is known (see, for example, Patent Document 1).

JP-A-56-90611

As described in Patent Document 1 (for example, 2nd to 4th lines in the upper right column on page 2), in an apparatus for observing the waveform of an optical signal, an element (photoelectric As a conversion element), for example, there is one using a photodiode. Taking the sampling oscilloscope shown in FIG. 8 as an example, the optical input section is provided with an O/E 61. A photodiode employed in the O/E 61 converts an optical signal into an electrical signal, and then The electrical signal is sampled.

It is known that a photodiode used in a photoelectric converter outputs a current corresponding to the input level of an optical signal, for example, and the current (dark current) changes with temperature when there is no input. Conventionally, as a countermeasure against measured value fluctuations caused by changes in dark current, a calibration operation is performed before starting measurement to determine the output (L _D ) of a photoelectric converter with no optical signal input. It is common to remove the measurement error caused by the measuring device by measuring and adding this measured value when calculating the measured value in subsequent measurements.

On the other hand, since the dark current of the photoelectric converter changes with temperature changes and affects the measurement results, it is essential to perform calibration each time the temperature changes. In this case, the temperature is measured by a thermometer (TM; denoted by reference numeral 65 in FIG. 8) mounted on the photoelectric converter.

When performing calibration, the input of the photodiode must be set to no input. In addition, depending on the light source, there are cases where some light leaks out even with the non-output setting, which may cause a deviation in the calibration result. In order to completely remove the output so as to disable the output, it is necessary to remove the connector each time, which takes time and effort.

In addition, there is a problem that reproducibility of the measurement results is deteriorated due to the change of the system, which is affected by the change of the shape of the optical cable and the influence of dirt and scratches on the end face of the connector. In addition, even if a temperature change alarm is displayed on the screen, the user sometimes does not perform calibration, and there is a problem that the measurement result deviates from the true value when there is a temperature change.

Patent Document 1 also describes that a light-receiving element (photoelectric conversion element) that performs photoelectric conversion changes with temperature, deteriorating measurement accuracy, and that changes in dark current are a problem (see, for example, page 2). 7th to 10th lines in the upper right column). From this, it is inferred that calibration is performed in the conventional waveform observation device.

However, even Japanese Unexamined Patent Application Publication No. 2002-200000 does not suggest a technique that can solve the above-described problems in the conventional sampling oscilloscope shown in FIG. Ultimately, with conventional waveform observation equipment, it takes time and troublesome work, such as disconnecting the connector, to turn off the optical signal completely during calibration. There were problems such as deterioration in the reproducibility of results, and the accuracy of measurement results being reduced due to forgetting to perform calibration in response to temperature change warnings.

In particular, automated measurements using programs are required in the manufacturing stage of optical devices. For this reason, troublesome work such as disconnecting the connector must be avoided at all costs. In many cases, the input of the optical signal to the light-receiving part of the photodiode cannot be completely cut off.

SUMMARY OF THE INVENTION The present invention has been made to solve such conventional problems. An object of the present invention is to provide an improved waveform observation device and waveform observation method.

In order to solve the above problems, a waveform observing apparatus according to claim 1 of the present invention includes a photoelectric conversion element ( 31); waveform analysis processing means (43) for performing waveform analysis processing of the signal under measurement output from the photoelectric conversion means; calibration control means (5e) for detecting a dark current output from the photoelectric conversion means and executing calibration control relating to the waveform analysis processing of the waveform analysis processing means based on the dark current; and the photoelectric conversion element. provided in the light input path (31b) to the light receiving part (31a) of the light receiving part (31a), and can be opened and closed in an open state that does not interfere with the input of the signal to be measured which is the optical signal to the light receiving part, or in a closed state that blocks the input optical shutter means (2) having an optical shutter (2a); optical shutter opening / closing control means (5e3) for switching and controlling the optical shutter from the open state to the closed state during execution of the calibration control; a start condition judging section (5e1) for judging whether or not the calibration starting condition is satisfied; a storage section (6) for storing a control data table (6a) storing information indicating the calibration starting condition; , and the optical shutter opening/closing control means, when it is determined that the calibration start condition is satisfied, keeps the optical shutter open for a period from immediately before the start of the calibration control until the end of the calibration control. is controlled to the closed state, a calibration UI screen for setting the calibration start condition is displayed on the display unit (8) as an operation mode, and an operation unit (7 ), a table setting mode for setting the calibration start condition for the control data table, and the start condition determination that the calibration start condition set in the table setting mode is established. a calibration execution mode in which the calibration execution control section (5e2) automatically sets and performs calibration when determined by the section; A UI screen for setting a signal standard and a transmission rate is displayed on the display unit, and according to the setting operation on the operation unit, It is characterized in that the standard and transmission rate of the signal under measurement can be set .

With this configuration, the waveform observing apparatus according to claim 1 of the present invention is provided with an optical shutter in the light input path to the light receiving section of the photoelectric conversion means, and the optical shutter is closed to detect the signal to be measured which is the optical signal to the light receiving section. Since the input can be cut off completely, there is no need to remove the connector one by one in order to completely remove the output from the photoelectric conversion means. High measurements can be made. In addition, since there is no need to remove the connector one by one, the system change does not occur, so it is possible to improve the reproducibility of the measurement results. With this configuration, the waveform observation apparatus according to claim 1 of the present invention can set the calibration start condition in advance, and can completely disable the optical shutter by closing the optical shutter each time the calibration start condition is satisfied. Accurate calibration can be performed in a state close to the input, no complicated work by the user is required, and the user will not be conscious of forgetting to perform calibration.

Further, the waveform observing apparatus according to claim 2 of the present invention further includes temperature measuring means (9a) provided in the vicinity of the photoelectric conversion element, and the start condition judging section determines that the temperature measured by the temperature measuring means is A configuration may be adopted in which it is determined that the calibration start condition is established when a predetermined temperature set in advance is reached.

With this configuration, in the waveform observation apparatus according to claim 2, calibration is performed in a state in which the light receiving part of the photoelectric conversion element is blocked by the optical shutter when the predetermined temperature is reached. Fluctuations in measurement results due to temperature fluctuations are automatically corrected in real time, so users do not need to be aware of or forget to perform calibration, and the accuracy of measurement results can be extremely high.

Further, in the waveform observing apparatus according to claim 3 of the present invention, the start condition determination unit calculates a temperature change amount based on the temperature measured by the temperature measuring means, and the temperature change amount is a preset temperature change. A configuration may also be adopted in which it is determined that the calibration start condition is established when the amount has been reached.

With this configuration, the waveform observation apparatus according to claim 3 closes the light receiving part of the photoelectric conversion element with the optical shutter when the preset temperature change amount is reached, and performs calibration according to the temperature change amount. calibration can be performed automatically, users will not be conscious of or forget about calibration, and moreover, the accuracy of measurement results can be expected to improve.

Further, the waveform observation apparatus according to claim 4 of the present invention further comprises timer means (9b) for measuring time, and the start condition judging section measures a predetermined time interval preset by the timer means. The configuration may be such that it is determined that the calibration start condition is satisfied when the calibration start condition is satisfied.

With this configuration, the waveform observing apparatus according to claim 4 of the present invention performs calibration according to the amount of temperature change in a state where the light receiving portion of the photoelectric conversion element is closed by the optical shutter at each preset time interval. Since the calibration is performed automatically, the user will not be conscious of or forget about the calibration, and moreover, the accuracy of the measurement results can be improved.

Further, in the waveform observation apparatus according to claim 5 of the present invention, the start condition determination unit may determine that the calibration start condition is satisfied by receiving a manual calibration start operation.

With this configuration, the waveform observing apparatus according to claim 5 can manually perform calibration in real time with the light receiving part of the photoelectric conversion element closed by the optical shutter, and an improvement in the accuracy of the measurement result can be expected.

Further, in the waveform observation apparatus according to claim 6 of the present invention, the optical shutter is an electro-absorption (EA) optical modulator, a lithium niobate (LN) optical modulator, an optical variable attenuator, or a mechanical optical shutter. may be configured.

With this configuration, the waveform observation device according to claim 6 can select the optimum type of optical shutter using physical durability, reaction speed, cost, etc. as indicators, and even if any optical shutter is installed, , calibration can be performed with the optical shutter closed, and the accuracy of measurement results can be improved.

Further, in the waveform observation apparatus according to claim 7 of the present invention, when the calibration execution mode is set manually and when the calibration execution mode is set after acceptance of the waveform observation start operation, an execution mode screen is displayed on the display unit. and the execution mode screen may be updated and displayed according to the progress of the calibration control.

Further, in the waveform observation apparatus according to claim 8 of the present invention, when the calibration start condition is established during waveform observation, the start condition determination unit determines whether or not calibration is necessary, and the calibration is completed. When it is determined that the calibration is necessary, after displaying on the display section that the calibration is necessary, a manual calibration start operation may be accepted.

In order to solve the above problems, a waveform observation method according to claim 9 of the present invention is a waveform observation method for observing the waveform of the signal under measurement using the waveform observation apparatus according to any one of claims 1 to 8 . A calibration UI screen for setting the calibration start condition is displayed on the display unit, and the calibration is performed on the calibration UI screen according to a setting operation on the operation unit. setting a start condition for the control data table; displaying on the display unit a UI screen for setting the standard and transmission rate of the signal under measurement; a step of setting the standard and transmission rate of the signal under measurement; a step of storing the control data table storing information indicating the calibration start condition; and a step of determining whether a predetermined calibration start condition is satisfied. a start condition determination step (S11, S15) for determining the calibration start condition, an optical shutter closing control step (S12) for switching and controlling the optical shutter to the closed state by determining that the calibration start condition is satisfied; When the start condition determination unit determines that the calibration start condition set in the table setting mode is established, the calibration execution control unit automatically sets the calibration execution mode and performs calibration. a calibration execution step (S2, S5, S13) of executing the calibration control while the optical shutter is controlled to be in the closed state; an optical shutter opening control step (S17) for controlling switching to the open state; a waveform analysis processing step (S3) of converting the photoelectric conversion element (31) into an electric signal and outputting it from the photoelectric conversion means (3), and performing waveform analysis processing of the output signal under measurement (S3); It is characterized by

With this configuration, in the waveform observation method according to claim 9 of the present invention, the optical shutter provided in the light input path to the light receiving section of the photoelectric conversion means is closed to completely prevent the input of the signal to be measured, which is the optical signal, to the light receiving section. Therefore, it is not necessary to remove the connector one by one in order to completely remove the output in order to turn off the photoelectric conversion means. It can be carried out. In addition, since there is no need to remove the connector one by one, system change does not occur, and reproducibility of measurement results can be improved. With this configuration, in the waveform observation method according to claim 9 of the present invention, by setting the calibration start condition in advance, the optical shutter is closed every time the calibration start condition is satisfied, and the waveform is completely disabled. Accurate calibration can be performed in a state close to the input, no complicated work by the user is required, and the user will not be conscious of forgetting to perform calibration.

INDUSTRIAL APPLICABILITY The present invention can provide a waveform observation apparatus and a waveform observation method that can perform high-precision calibration in a state as close to no input as possible without requiring complicated work, and that can improve the accuracy of measurement results. .

1 is an overall configuration diagram of a sampling oscilloscope according to an embodiment of the present invention; FIG. 3 is a block diagram showing the functional configuration of the control section of the sampling oscilloscope according to one embodiment of the present invention; FIG. 3 is a block diagram showing the functional configuration of an optically variable ATT employed as an optical shutter in the sampling oscilloscope according to one embodiment of the present invention; FIG. 4 is a flowchart showing waveform observation processing operations of the sampling oscilloscope according to one embodiment of the present invention. FIG. 4 is a flowchart showing details of calibration control operations in steps S2 and S5 of FIG. 3 of the sampling oscilloscope according to one embodiment of the present invention; FIG. It is a graph which shows the temperature dependence characteristic of the dark current in O/E of a waveform observation apparatus. It is a figure which shows the observation waveform model for demonstrating the definition and temperature dependence of the extinction ratio in a waveform observation apparatus. 1 is a diagram showing the configuration of a conventional sampling oscilloscope used for waveform observation of an optical device; FIG.

Embodiments of a waveform observing apparatus and a waveform observing method according to the present invention will be described below with reference to the drawings.

First, the configuration of a sampling oscilloscope 1 according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. The sampling oscilloscope 1 is an example of a waveform observation apparatus according to the present invention, and receives an optical signal (optical data) output as a signal under measurement from a DUT 50, which is an object to be measured, and converts the optical signal into an electrical signal (data ) and perform waveform analysis (waveform observation) processing. The signal under measurement is, for example, a signal such as a PRBS pattern signal (pseudo-random signal).

During the above waveform observation, a data signal (measured signal) is input from the PPG 67 to the DUT 50, and the DUT 50 outputs the data signal to the sampling oscilloscope 60 as an optical signal. , and that the DUT 50 is mounted (connected) to the evaluation board 70A and used is the same as the conventional system configuration shown in FIG.

As the DUT 50, various optical devices such as an optical transceiver having a function of transmitting optical signals are used. The DUT 50 is of various types that can transfer an optical signal having any transmission rate (standard rate) among a plurality of transmission rates to which respective standards are allocated, or an optical signal having an arbitrary transmission rate. is prepared. The sampling oscilloscope 1 is of various types that can transfer optical signals of various standard rates or optical signals of any transmission rate based on, for example, the Fast Ethernet (registered trademark) standard defined in IEEE802.3. DUT 50 is selectively connected (replaced) to observe (waveform analysis process) the optical signal (signal to be measured) output from the DUT 50 . Examples of optical device standards include QSFP, QSFP-28, QSFP-56, and QSFP-DD.

In order to perform the waveform observation described above, the sampling oscilloscope 1 according to the present embodiment includes an O/E 3, a waveform observation section 4, a control section 5, a storage section 6, an operation section 7, and a display section 8, as shown in FIG. , a thermometer (SM) 9a.

The O/E 3 comprises an optical shutter section 2, a photodiode 31 and an amplifier 32. FIG. The optical shutter section 2 has an optical shutter 2 a provided in an optical signal input path 31 b to the light receiving section 31 a of the photodiode 31 . The O/E 3 constitutes the photoelectric conversion means of the present invention, and the optical signal input path 31b constitutes the optical input path of the present invention.

The optical shutter 2a has a configuration that can be opened and closed in an open state that does not block the input of the optical signal to the light receiving portion 31a of the photodiode 31 or in a closed state that blocks the input of the optical signal. Opening/closing control of the optical shutter 2a between the open state and the closed state is performed by an optical shutter opening/closing control section 5e3, which will be described later. Here, the optical signal input to the light receiving section 31a when the optical shutter 2a is in the open state is output from the DUT 50 according to the input of the data signal from the PPG 67 during waveform observation, and is taken in from the optical signal input terminal Tin1. This is the signal to be measured that is input via the optical signal input path 31b.

The optical shutter 2a employed in the optical shutter unit 2 is, for example, electrolyzed to a semiconductor, so that the amount of light absorption can be adjusted to a state in which light is transmitted (corresponding to the open state described above) or a state in which light is absorbed (equivalent to the open state described above). an electro-absorption (EA) optical modulator controllable to a closed state), a state in which laser light is input and no laser light is output in response to an applied voltage (corresponding to the closed state) or the above A lithium niobate (LN) optical modulator capable of controlling a state in which laser light is output (corresponding to the above open state), and light that controls the attenuation of optical signals to 0 or maximum to switch between the above open state and closed state It can be realized with a variable attenuator (ATT). Also, the optical shutter 2a can be a mechanical optical shutter that switches an optical shutter plate that shields an optical signal between the open state and the closed state. It is desired that these various optical shutter units 2 can attenuate light to a level equal to or lower than the reception sensitivity of the sampling oscilloscope 1 in the closed state. The optical shutter section 2 constitutes optical shutter means of the present invention.

FIG. 3 shows the functional configuration of an optical shutter section 2B, which is an example of the optical shutter section 2 according to this embodiment. The optical shutter section 2B employs an optical variable attenuator (ATT) 2a1 as the optical shutter 2a. is controlled to 0 or maximum to switch the variable optical attenuator (ATT) 2a1 to the open state or the closed state.

The photodiode 31 receives an optical signal (signal to be measured) input from the DUT 50 via the optical signal input path 31b provided with the optical shutter section 2 with the light receiving section 31a and converts the optical signal into an electric signal. It functions as a photoelectric conversion element. The amplifier 32 amplifies the electrical signal output from the photodiode 31 and outputs it to the waveform observing section 4 .

The waveform observation section 4 has a sampling pulse generation section 41 , a sampler 42 and a signal waveform processing section 43 . The sampling pulse generator 41 generates a timing signal used as a sampling timing for operating the sampler 42 based on the trigger clock signal output from the DUT 50 and input from the clock input terminal Tin2. The generated timing signal is a low-speed timing signal of several 100 kHz, and is supplied to the sampler 42 and signal waveform processing section 43 (FPGA to be described later). The sampler 42 performs a switching operation at, for example, several 100 kHz using the timing signal generated by the sampling pulse generator 41 as a sampling timing, and converts the signal under measurement (input data signal) converted into an electrical signal by the O/E 3 to Sampling.

The signal waveform processing unit 43 performs waveform analysis processing on data (sample data) signals sampled by the sampler 42 . More specifically, the signal waveform processing unit 43 amplifies the output signal level from the sampler 42 with an IF (Intermediate Frequency) circuit and converts it into digital data with an ADC (Analog to Digital Converter). The digitally converted data is analyzed by software processing by an FPGA (Field-Programmable Gate Array) and a CPU, and the eye pattern analysis result is displayed on the display unit 8 as the final result. The signal waveform processing section 43 constitutes waveform analysis processing means of the present invention.

The control unit 5 performs timing signal (sampling pulse) generation processing in the sampling pulse generation unit 41, data signal sampling processing in the sampler 42, waveform analysis processing of the signal under measurement in the waveform observation unit 4, and calibration described later. It controls the overall operation of the sampling oscilloscope 1, such as control.

As shown in FIG. 2, the control section 5 includes a CPU 5a and an external interface (I/F) section 5f. The CPU 5a executes programs stored in the storage unit 6, for example, to implement functional units such as a setting control unit 5b, a measurement control unit 5c, a display control unit 5d, and a calibration control unit 5e.

The setting control unit 5b performs various setting processes such as setting of simulation parameters for measurement (waveform observation) of the DUT 50 and calibration start conditions related to calibration control.

The measurement control section 5c controls each section related to the measurement (observation) of the signal under measurement, such as detection processing of the waveform of the signal under measurement based on the sample data from the sampler 42 in the signal waveform processing section 43. FIG.

The display control unit 5d performs display control for causing the display unit 8 to display various information related to waveform observation of the signal under measurement. The display control unit 5d performs display control for displaying a UI screen on the display unit 8 when a data signal (signal under measurement) is input from the DUT 50 to the sampling oscilloscope 1, for example. As the UI screen, an input screen having a screen configuration that allows inputting of a specified transmission rate or an arbitrary transmission rate in association with the signal to be input (signal to be measured), and a signal related to re-input. is mentioned. The display control unit 5d also provides a calibration UI screen that allows input of control conditions (calibration start conditions, etc.) related to calibration control performed on the waveform observation unit 4 (in particular, the signal waveform processing unit 43), Display control of the waveform analysis processing result of the signal under measurement in the signal waveform processing section 43 can also be executed.

The calibration control unit 5e is, for example, a functional unit that performs operation control related to calibration performed prior to waveform observation of the signal under measurement. Specifically, the calibration control unit 5e accepts an operation for setting control conditions for calibration using the UI screen for calibration described above, sets the control conditions, and sets the calibration start conditions, which are one of the control conditions. is established, calibration control is executed based on the set calibration control conditions each time.

The calibration control section 5e has a start condition determination section 5e1, a calibration execution control section 5e2, and an optical shutter opening/closing control section 5e3.

The start condition determination unit 5e1 performs processing for determining whether or not a preset calibration start condition is satisfied. The calibration start condition can be set by the setting control section 5b according to the operation input on the operation section 7. FIG. Specific calibration start conditions include the fact that a calibration start operation has been performed on the operation unit 7, as well as time (time to start, time interval) and temperature (temperature to start, temperature change amount). Can be set using parameters. The start condition determination unit 5e1 constitutes start condition determination means of the present invention.

A thermometer 9a for detecting the ambient temperature is provided in the vicinity of the photodiode 31 in order to realize a calibration start condition determination function using parameters related to temperature (start time, time interval). The thermometer 9a constitutes temperature measuring means in the present invention.

Further, the control unit 5 includes a clock circuit (TK) 9b for clocking time in order to realize a function of determining calibration start conditions using parameters related to time (start time, time interval). The clock circuit 9b constitutes the clock means in the present invention.

The calibration execution control section 5 e 2 has a control function of executing calibration related to waveform analysis processing in the signal waveform processing section 43 of the waveform observation section 4 . Specifically, when the start condition determination unit 5e1 determines that the calibration start condition is satisfied, the calibration execution control unit 5e2 starts the O/E 3 with no input of the optical signal that is the signal to be measured. An output current (dark current) is detected, and calibration control relating to waveform analysis processing in the signal waveform processing section 43 of the waveform observation section 4 is executed based on the dark current. The calibration execution control section 5e2 constitutes calibration control means of the present invention together with the calibration control section 5e.

The optical shutter opening/closing control unit 5e3 sets the optical shutter 2a of the optical shutter unit 2 to an open state that does not interfere with the input of the signal under measurement, which is an optical signal, to the light receiving unit 31a of the photodiode 31, or to a closed state that blocks the input. This is a functional part that controls opening and closing. For example, the optical shutter opening/closing control unit 5e3 normally switches the optical shutter 2a to the above-described open state. The optical shutter 2a is controlled to be switched to the closed state until the motion control ends. The optical shutter opening/closing control section 5e3 constitutes the optical shutter opening/closing control means of the present invention.

The external I/F unit 5f has an interface function for accessing external equipment via the network 10. In this embodiment, the network 10 is connected between the sampling oscilloscope 1 and the external control device 11 (see FIG. 1). It also provides an interface function for sending and receiving signals via In this embodiment, the sampling oscilloscope 1 can be configured to operate according to commands from an external control device 11 via a network 10 in addition to being controlled by its own control unit 5 . The system operation in this case can be realized by providing a control unit (not shown) of the control device 11 with a functional unit equivalent to the control unit 5 .

The storage unit 6 stores programs necessary for the CPU 5a to realize each functional unit such as the setting control unit 5b, the measurement control unit 5c, the display control unit 5d, and the calibration control unit 5e, as well as controls used for various controls. A data table 6a is stored. The control data table 6a stores at least information indicating the calibration start conditions described above.

The operation unit 7 is composed of an operation panel such as switches and buttons. The operation panel may have a touch panel function. The operation unit 7 instructs to start or stop the calibration performed before the waveform observation of the DUT 50, instructs to start or stop the subsequent waveform observation of the DUT 50, and various kinds necessary for performing desired display on the display unit 8. Various settings required for waveform measurement of the DUT 50, including information settings, can be selectively executed.

The display unit 8 is composed of a display device such as a liquid crystal panel, and displays various information related to waveform measurement of the DUT 50 . In this embodiment, the display unit 8 displays the above-described UI screen for calibration and the display screen for displaying the result of calibration measurement under the control of the display control unit 5d.

Next, operation of the sampling oscilloscope 1 will be described. This sampling oscilloscope 1 has a table setting mode, a calibration execution mode, and a waveform observation mode. When the table setting mode is set, the display control unit 5d causes the display unit 8 to display a calibration UI screen for setting calibration start conditions. The user can set the above-described various calibration start conditions for the control data table 6a on the UI screen for calibration, for example, according to the setting operation on the operation unit 7. FIG. In addition, in the table setting mode, after displaying a UI screen for setting the standard and transmission rate of the signal under measurement on the display unit 8, the user can set the standard and transmission rate of the signal under measurement from the operation unit 7. You can also make settings.

The calibration execution mode can be set manually by the user, for example, by performing a predetermined calibration start operation on the operation unit 7 . In addition, the calibration execution mode is automatically set by the calibration execution control section 5e2 when the start condition determination section 5e1 determines that the calibration start condition set in advance in the table setting mode is established. It is also possible to

When the calibration execution mode is set, calibration control is started under the control of the calibration execution control section 5e2. Here, when the calibration execution mode is manually set, or when the calibration execution mode is set in response to acceptance of the waveform observation start operation, for example, the execution mode screen is displayed on the display unit 8 by the display control unit 5d. The update display of the execution mode screen is performed according to the progress of the calibration control. When the calibration execution mode is automatically set, the execution mode screen does not necessarily have to be displayed.

The waveform observation mode can be set manually by the user, for example, by performing a predetermined waveform observation start operation on the operation unit 7 . When the waveform observation mode is set, the waveform observation screen is displayed on the display section 8 by the display control section 5d, and the waveform observation processing operation is started under the control of the measurement control section 5c. The waveform observation screen is updated and displayed according to the progress of the waveform observation operation.

The waveform observation operation of the sampling oscilloscope 1 according to this embodiment will be described below with reference to the flowchart shown in FIG. For this waveform observation, as calibration start conditions, for example, "at reception of waveform observation start operation", a predetermined "temperature change amount", and a predetermined "time interval" are set. "At reception of waveform observation start operation" is used as a condition for starting calibration control in step S2, and "temperature change amount" and "time interval" are used as conditions for starting automatic calibration in step S6.

As shown in FIG. 4, the sampling oscilloscope 1 receives a manual waveform observation start operation (step S1) and executes calibration control (step S2). At this time, in the calibration control unit 5e of the control unit 5, the start condition determination unit 5e1 detects that the calibration start condition is established by accepting the waveform observation start operation, and the calibration execution control unit 5e2 performs calibration control. is set to start.

When the calibration control in step S2 is started, first, the optical shutter opening/closing control section 5e3 puts the optical shutter 2a of the optical shutter section 2 into a closed state in which the optical signal input to the light receiving section 31a of the photodiode 31 is cut off. Switching is controlled. In this state, the calibration execution control unit 5e2 detects the dark current output from the O/E 3 with no input of the signal under measurement, and analyzes the waveform of the signal waveform processing unit 43 based on the dark current. Perform calibration control to obtain correction values for processing functions. The calibration control in step S2 will be described in detail later with reference to FIG. 5 together with the automatic calibration control in step S6.

When the calibration control in step S2 is completed, waveform observation processing of the signal under measurement is performed (step S3). At this time, first, the optical shutter opening/closing control unit 5e3 in the control unit 5 switches and controls the optical shutter 2a to an open state in which the input of the optical signal to the light receiving unit 31a of the photodiode 31 is not blocked. Next, the measurement control unit 5c controls to transmit the signal under measurement from the PPG 67 to the DUT 50, transmit the optical signal from the DUT 50, and input the optical signal to the O/E 3.

In the O/E 3 , the input optical signal is converted into an electrical signal by the photodiode 31 , amplified by the amplifier 32 , and output from the O/E 3 to the waveform observing section 4 . In the waveform observation unit 4, the signal under measurement input from the O/E 3 is sampled by the sampler 42, the sampled signal under measurement is subjected to waveform analysis processing by the signal waveform processing unit 43, and the waveform analysis result is displayed. It is controlled to display on the unit 8.

During execution of the waveform observation process in step S3, the measurement control unit 5c monitors whether or not an operation for ending waveform observation has been performed (step S4). If it is determined that the waveform observation end operation has not been performed (NO in step S4), the measurement control section 5c controls to continue the waveform observation control in step S3.

On the other hand, if it is determined that the waveform observation end operation has been performed (YES in step S4), the control section 5 controls the sampling oscilloscope 1 to the standby state (step S5).

In the standby state, the calibration execution control section 5e2 executes automatic calibration control based on preset calibration start conditions (step S6). Here, the start condition judging section 5e2 monitors whether or not preset calibration start conditions (automatic calibration start conditions such as "temperature change amount" and "time interval") are established. When it is determined that the calibration start condition is established, the calibration execution control unit 5e2 automatically starts calibration control, and thereafter continues the calibration control until the calibration ends.

The automatic calibration control in step S6 is realized by the same control as the calibration control in step S2 except that it is automatically performed on the condition that it is determined that the calibration start condition is met. As a result, in step S6, for example, when the amount of temperature change measured by the thermometer 9a reaches a predetermined "temperature change", or when the time interval measured by the clock circuit 9b is set in advance. Automatic calibration is executed when the set predetermined "time interval" is reached.

When the automatic calibration control in step S6 ends, the measurement control section 5c monitors whether or not the waveform observation start operation has been performed (step S7). If it is determined that the waveform observation start operation has not been performed (NO in step S7), the measurement control unit 5c executes automatic calibration control while maintaining the standby state, and monitors the waveform observation start operation. (steps S5, S6, S7).

If it is determined that the waveform observation start operation has been performed during this period (YES in step S7), the process returns to step S1, and thereafter the control after step S1 is performed.

Next, the calibration control operation in steps S2 and S6 in FIG. 4 (step S6 is automatically activated) will be described in detail with reference to the flowchart shown in FIG.

As shown in FIG. 5, in the sampling oscilloscope 1 according to the present embodiment, during standby, the start condition determination unit 5e1 monitors whether or not a preset calibration start condition is satisfied (step S11). If it is determined that the calibration start condition is not established (NO in step S11), the above monitoring is continued.

On the other hand, if the start condition determination unit 5e1 determines that the calibration start condition is satisfied (YES in step S11), then the optical shutter opening/closing control unit 5e3 outputs the optical signal to the light receiving unit 31a of the photodiode 31. Control is performed to close the optical shutter 2a so as to cut off the input (step S12).

After performing the closing control of the optical shutter 2a, the calibration execution control section 5e2 detects the dark current of the O/E 3 with no input of the signal to be measured, which is an optical signal from the DUT 50. FIG. Subsequently, the calibration execution control section 5e2 executes calibration control for obtaining a correction value related to the waveform analysis processing of the signal waveform processing section 43 based on the detected dark current (step S13).

Further, the calibration execution control section 5e2 checks whether or not the calibration control has ended (step S14). Here, if it is determined that the calibration control has ended (YES in step S14), the optical shutter opening/closing control unit 5e3 is placed in an open state so as not to interfere with the input of optical signals to the light receiving unit 31a of the photodiode 31. Control is performed to open the optical shutter 2a (step S15).

Next, the control unit 5 returns the process to step S11, and thereafter performs control so that the calibration control of steps S11 to S15 is repeatedly executed. During this time, in the control unit 5, the measurement control unit 5c receives a manual waveform observation start operation as shown in FIG. 4, performs calibration control, and then executes waveform observation processing (see steps S1 to S3). be able to. Thereafter, the control unit 5 accepts a waveform observation end operation (see step S4 in FIG. 4) and controls to end a series of waveform observation processes.

Note that in the waveform observation process shown in FIG. 4, if automatic calibration (see step S6) is being performed during standby, depending on the situation, calibration control in step S2 may be performed after receiving the waveform observation start operation. may not be performed.

In the waveform observation processing shown in FIG. 4, it is assumed that calibration control is not performed during waveform observation in order to avoid interference with waveform observation. As a modification of the waveform observation processing shown in FIG. 4, calibration control may be performed during the waveform observation processing within a range that does not interfere with waveform observation. In this case, for example, when the calibration start condition is established during waveform observation, it is monitored whether or not the situation particularly requires calibration. After warning, the user may accept permission and perform calibration. Here, a situation in which calibration is particularly required is a case where the amount of temperature change reaches a preset threshold value (for example, 5° C.).

As described above, the sampling oscilloscope 1 according to the present embodiment, for example, accepts a waveform observation start operation and executes calibration control (see step S2 in FIG. 4), and automatically executes calibration control during standby. (See step S5 in FIG. 4). During the calibration control period, the optical shutter 2a is controlled to be closed so that no optical signal is input to the light receiving portion 31a of the photodiode 31. FIG.

In particular, by setting, for example, temperature, temperature change amount, time interval, etc., as calibration start conditions for automatic calibration, the sampling oscilloscope 1 performs calibration control according to patterns related to operation control 1 to 5 shown below. can be realized.

Motion control 1:
By setting "when the calibration start operation is received" as the calibration start condition, the user can manually perform the calibration start operation at an arbitrary timing, and the calibration control can be executed each time. can.

Motion control 2:
By setting a predetermined "temperature (for example, 25 degrees Celsius)" as a calibration start condition, calibration control is automatically executed when the temperature detected by the thermometer 9a reaches a predetermined temperature. can do. Before executing the calibration control, a notification to the effect that the calibration control will be executed may be made.

Motion control 3:
By setting the "temperature change amount" as a calibration start condition, calibration control is automatically performed when it is recognized that the set temperature change amount has been reached based on the temperature detected by the thermometer 9a. can be executed. As the value of the amount of temperature change, for example, 1° C. or 1 millivolt (mV) is set. Here, 1 mV is the change in the extinction ratio when observing the waveform at O/E3 with a photoelectric conversion gain of 170 V/W, assuming a waveform with an input light level of -3 dBm and an extinction ratio of 4 dB. This value is determined taking into consideration the span that is sufficiently small as less than 0.1 dB.

Motion control 4:
By setting a predetermined "time interval (for example, 1 second)" as a calibration start condition, calibration control can be automatically executed each time the time interval is counted by the clock circuit 9b. . The value of the predetermined time interval is desirably set in consideration of the fact that the measurement accuracy can sufficiently follow changes in environmental temperature.

Motion control 5:
By setting "at reception of waveform observation start operation" as the calibration start condition, calibration control can be reliably executed immediately before waveform observation is started.

(Optical shutter 2a, its operating characteristics, and opening/closing control function)
As the optical shutter 2a of the optical shutter unit 2, as described above, in addition to the mechanical optical shutter, an EA optical modulator, an LN optical modulator, an optical variable ATT, and the like can be applied.

The mechanical optical shutter includes a physically movable opaque optical shutter plate arranged to close the optical signal input path 31b to the light receiving portion 31a of the photodiode 31, and a driving source such as a motor for driving the optical shutter plate. configured with The optical shutter opening/closing control unit 5e3 corresponding to the mechanical optical shutter has an optical shutter plate in an open state in which an optical signal (measured signal) can be input to the light receiving unit 31a of the photodiode 31, and in a closed state in which the optical signal is blocked. It can be realized by driving and controlling the driving source so as to switch between and.

An EA optical modulator changes the energy level difference (bandgap) between the conductor and the valence band by applying an electric field to a semiconductor microstructure (quantum well), which changes the amount of light absorbed (semiconductor (electroabsorption effect) can be used to selectively establish a state in which light is absorbed or a state in which light is less absorbed. The optical shutter opening/closing control unit 5e3 corresponding to the optical modulation type shutter is configured to be able to control the EA optical modulator to increase or decrease the bandgap. Here, by increasing the bandgap, a transparent state (corresponding to an open state in the present embodiment) with less light absorption (transmitting as it is) can be achieved, and by decreasing the bandgap, light is absorbed. (light is blocked) state (corresponding to the closed state).

The LN optical modulator (optical intensity modulator) is configured by forming a branch waveguide and an electrode on an LN substrate, and depending on the voltage applied to the electrode, the laser light from the outside is not output or the laser light is output. It has a configuration that can be controlled to a state where The optical shutter opening/closing control unit 5e3 corresponding to the LN optical modulator places the LN optical modulator in a state in which laser light is not output (corresponding to the closed state in this embodiment) or in a state in which laser light is output (similar to the open state). (equivalent to ) can be realized with a device having a control function that can be controlled.

The variable optical ATT 2a1 is composed of a VOA (Variable Optical Attenuator), and as shown in FIG. 3, is arranged in the optical signal input path 31b to the light receiving section 31a of the photodiode 31 to constitute the optical shutter section 2B. The optical shutter opening/closing control unit 5e3 corresponding to the optical shutter unit 2B sets the optical variable ATT 2a1 to an attenuation amount of an optical signal of 1 (an open state in which an optical signal can be input to the light receiving unit 31a of the photodiode 31), It can be realized by having an attenuation amount switching control function for switching the attenuation amount to either 0 (a closed state in which the input of the optical signal to the light receiving portion 31a of the photodiode 31 is blocked).

For the optical shutter section 2B having the configuration shown in FIG. established. Since there are some optical variable ATTs whose attenuation can be adjusted manually, the optical shutter unit 2B can also be configured using a manually adjustable optical variable ATT.

The variable light ATT 2a1 mounted on the optical shutter section 2B has the advantage of having higher physical durability than the mechanical optical shutter and extending the maintenance cycle. The optically tunable ATT2a1 also has the advantage of good reaction speed. Physically moving mechanical optical shutters and optical switches can only handle operations up to several tens of Hz, but the optically variable ATT 2a1 has a response speed of about MHz and can handle high-speed operations. The response speed is directly linked to shortening of the calibration control time, and according to the sampling oscilloscope 1 using the optical shutter section 2B equipped with the optical variable ATT 2a1, there is an advantage that the calibration control can be realized in a shorter time. have.

(Regarding the advantages of the configuration in which the optical shutter section 2 is provided)
Next, the operation characteristics related to calibration in the sampling oscilloscope 1 according to the present embodiment will be described in detail, focusing mainly on improvements over existing waveform observation devices.

First, the temperature dependence of the dark current in the O/E of the existing waveform observation device will be described with reference to FIG. As shown in the graph of FIG. 6, the current output from the O/E when no optical signal is input, that is, the dark current _LD of the O/E gradually increases as the temperature rises. It has the following characteristics. The graph of FIG. 6 particularly shows the temperature dependence characteristic of the observed voltage converted from the dark current _LD via a TIA (Transimpedance Amplifier).

Next, with reference to the observed waveform model shown in FIG. 7, the definition and temperature dependency of the extinction ratio in the existing waveform observation device will be described. In the observed waveform model shown in FIG. 7, the level indicated by symbol L1 is the 1 level (mV), the level indicated by symbol L0 is the 0 (zero) level (mV), and the level indicated by symbol LD is when there is no light input. , the ratio of the level (mV) when there is an optical input and the level (mV) when there is no optical input, that is, the extinction ratio (dB) is given by the following formula (1). can be represented.
Extinction ratio = 10log10 {(L1-LD)/(L0-LD)} (1)

In FIG _. 7, the level L _D when there is no light input is ideally L _D =0 (zero). deviation occurs. In order to correct this deviation, the _LD is normally held when no optical signal is input, and the held _LD value is subtracted from the actual measurement value at the time of actual measurement and calculation. A measured value that is as close as possible to the true value is calculated. However, in this case, due to the temperature dependence characteristic of the O/E dark current (observed voltage) shown in FIG.

An example of calculation of the allowable range of measured values considering the influence of changes in observed voltage due to temperature changes will be described. Here, it is assumed that a photoelectric conversion gain (Conversion Gain) in O/E is 170 V/W (5.88 uW/mV) for a waveform with Average=3 dBm and extinction ratio=4 dB. Under this assumption, when the temperature changes by 1°C, a deviation of about 1 mV (= 6uW) occurs per 1°C, and the extinction ratio considering the _LD deviation is calculated as 4.07dB, which is an error of 0.07dB from the true value. Within 1dB.

Taking into consideration the above-mentioned temperature dependence of dark current (see Fig. 6) and existence of extinction ratio and its temperature dependence (see Fig. 7), it is essential to perform calibration control to remeasure _LD when temperature changes. Become. In addition, when performing calibration control, it is important to ensure that no optical signal is input, because the calculation will be off track if the optical signal is not input. Regarding this point, in the existing waveform observation device, even though the output of the optical signal from the DUT 50 to the O/E is set to no output, some output leaks and is input to the O/E. Such a minute input sometimes caused a deviation in the measured value. As a countermeasure for this, in existing waveform observation devices, in order to prevent the above-mentioned slight leakage, work such as removing the connectors one by one is performed.

As described above, from the descriptions of FIGS. 6 and 7, it is necessary to perform calibration in order to avoid the influence of changes in the dark current _LD of the O/E when the temperature changes. It can be understood that accurate calculation cannot be expected unless the optical signal is input.

In response to such a request, the sampling oscilloscope 1 according to the present embodiment has an open state that does not block the input of optical signals to the light receiving portion 31a of the photodiode 31 of the O/E 3, or a closed state that blocks the input of optical signals. It has a switching optical shutter 2a and an optical shutter opening/closing control function for switching the optical shutter 2a between the open state and the closed state during execution of calibration control. According to this configuration, during the execution period of the calibration control, it is possible to reliably shut out the slight input to the O/E caused by the slight output leakage described above. As a result, it is possible to obtain accurate measurement values without having to remove the connectors one by one, which is required in existing waveform observation devices.

As described above, the sampling oscilloscope 1 according to this embodiment includes the O/E 3 having the photodiode 31 that converts the signal under measurement input from the DUT 50 as an optical signal into an electrical signal and outputs the electrical signal, and the output from the O/E 3. and a signal waveform processing unit 43 that detects the dark current output from the O/E 3 with no input of the signal under measurement, and based on the dark current, the signal waveform processing unit 43 and a calibration control unit 5e for executing calibration control related to the waveform analysis processing of 1, and an optical signal input path 31b for the light receiving unit 31a of the photodiode 31, which inputs the signal under measurement, which is an optical signal, to the light receiving unit 31a. An optical shutter unit 2 having an optical shutter 2a that can be opened and closed in an open state that does not interfere or a closed state that blocks the input, and light that controls switching of the optical shutter 2a from the open state to the closed state during calibration control. and a shutter opening/closing control unit 5e3.

With this configuration, the sampling oscilloscope 1 according to the present embodiment is provided with the optical shutter 2a in the optical signal input path 31b to the light receiving portion 31a of the O/E 3, and the optical shutter 2a is closed to receive the optical signal to the light receiving portion 31a. Since the input of the measurement signal can be completely cut off, there is no need to remove the connector one by one in order to completely remove the output of the O/E3, and calibration can be performed without time and effort. , it is possible to make highly accurate measurements. In addition, since there is no need to remove the connector one by one, the system change does not occur, so it is possible to improve the reproducibility of the measurement results.

Further, the sampling oscilloscope 1 according to the present embodiment has a start condition determination section 5e1 that determines whether or not a predetermined calibration start condition is satisfied. When it is determined that the optical shutter 2a is closed, the optical shutter 2a is controlled to be closed during the period from immediately before the start of the calibration control until the end of the calibration control.

With this configuration, the sampling oscilloscope 1 according to the present embodiment can set the calibration start condition in advance, so that each time the calibration start condition is satisfied, the optical shutter 2a is closed and no input is made. Accurate calibration can be performed in a similar state, no complicated work by the user is required, and the user is not made aware of forgetting to perform calibration.

The sampling oscilloscope 1 according to the present embodiment further includes a thermometer 9a provided near the photodiode 31, and the start condition determination unit 5e1 determines whether the temperature measured by the thermometer 9a reaches a predetermined temperature. The configuration is such that it is determined that the calibration start condition is established when the time is reached.

With this configuration, the sampling oscilloscope 1 according to the present embodiment is calibrated in a state where the light receiving portion 31a of the photodiode 31 is blocked by the optical shutter 2a when the predetermined temperature is reached. /E3 automatically and in real time compensates for fluctuations in measurement results due to temperature fluctuations, so users do not need to be aware of or forget to calibrate, and the accuracy of measurement results can be extremely high. Become.

Further, in the sampling oscilloscope 1 according to the present embodiment, the start condition determination unit 5e1 calculates the amount of temperature change based on the temperature measured by the thermometer 9a, and when the amount of temperature change reaches a preset temperature change amount, In this configuration, it is determined that the calibration start condition is satisfied.

With this configuration, the sampling oscilloscope 1 according to the present embodiment closes the light receiving part 31a of the photodiode 31 with the optical shutter 2a when the preset temperature change amount is reached. The calibration can be automatically performed, and the user will not be conscious of or forget about the calibration, and moreover, the accuracy of the measurement result can be improved.

Further, the sampling oscilloscope 1 according to the present embodiment has a clock circuit 9b for measuring time, and the start condition determination unit 5e1 performs calibration when a predetermined time interval preset by the clock circuit 9b is clocked. This is a configuration in which it is determined that the session start condition is established.

With this configuration, the sampling oscilloscope 1 according to the present embodiment automatically performs calibration according to the amount of temperature change with the light receiving portion 31a of the photodiode 31 closed by the optical shutter 2a at predetermined time intervals. Since the calibration is performed in , the user will not be conscious of or forget about calibration, and moreover, the accuracy of the measurement results can be expected to be improved.

Further, the sampling oscilloscope 1 according to the present embodiment is configured such that the start condition determination unit 5e1 determines that the calibration start condition is satisfied by receiving a manual calibration start operation.

With this configuration, the sampling oscilloscope 1 according to the present embodiment can be manually calibrated in real time with the light receiving part 31a of the photodiode 31 closed by the optical shutter 2a, and the accuracy of measurement results can be improved.

Also, in the sampling oscilloscope 1 according to the present embodiment, the optical shutter 2a is composed of an electro-absorption (EA) optical modulator, a lithium niobate (LN) optical modulator, an optical variable attenuator 2a1, or a mechanical optical shutter. be.

With this configuration, the sampling oscilloscope 1 according to the present embodiment can select the optimum type of optical shutter 2a based on physical durability, reaction speed, cost, etc. Even in this case, calibration can be performed with the optical shutter 2a closed, and an improvement in the accuracy of measurement results can be expected.

Further, the waveform observation method according to the present embodiment is a waveform observation method for observing the waveform of the signal under measurement using the sampling oscilloscope 1 having the above-described configuration. a start condition determination step (S11, S15) for determining whether a A calibration execution step (S2, S5, S13) in which calibration control is executed while the shutter 2a is controlled to be in the above-described closed state, and a control for switching the optical shutter 2a to the above-described open state by completing the calibration control. In the optical shutter opening control step (S17), and in the state where the optical shutter 2a is controlled to the open state, the signal to be measured input as an optical signal from the DUT 50 is converted into an electrical signal by the photodiode 31, and is sent from the O/E 3 and a waveform analysis processing step (S3) of outputting and performing waveform analysis processing of the output signal under measurement.

With this configuration, in the waveform observation method according to the present embodiment, the optical shutter 2a provided in the optical signal input path 31b for the light receiving portion 31a of the photodiode 31 is closed, and the signal to be measured, which is an optical signal, is input to the light receiving portion 31a. can be completely shut off, so there is no need to remove the connector one by one to completely remove the output in order to make the O/E3 non-output. measurements can be made. In addition, since there is no need to remove the connector one by one, system change does not occur, and reproducibility of measurement results can be improved.

As described above, the waveform observation apparatus and waveform observation method according to the present invention can perform high-precision calibration in a state as close to no input as possible without requiring complicated work, and can improve the accuracy of measurement results. A waveform observation apparatus for analyzing a signal to be measured input from an object to be measured by converting it from an optical signal to an electrical signal and displaying the analysis result on a display unit for waveform observation, and a waveform It is useful for all observation methods.

1 Sampling oscilloscope (waveform observation device)
2 Optical shutter section (optical shutter means)
2a optical shutter 3 photoelectric converter (O/E) (photoelectric conversion means)
4 waveform observation unit 5 control unit 5e calibration control unit (calibration control means)
5e1 start condition determination unit (start condition determination means)
5e2 calibration execution control unit (calibration control means)
5e3 Optical shutter opening/closing control unit (optical shutter opening/closing control means)
9a thermometer (SM) (temperature measuring means)
9b timer circuit (TK) (timer means)
31 photodiode (photoelectric conversion element)
31a light receiving portion 31b optical signal input path (optical input path)
43 Signal waveform processing unit (waveform analysis processing means)
50 DUT (object to be measured)

Claims (9)

a photoelectric conversion means (3) having a photoelectric conversion element (31) for converting a signal to be measured input as an optical signal from an object to be measured (50) into an electrical signal and outputting the electrical signal;
waveform analysis processing means (43) for performing waveform analysis processing of the signal under measurement output from the photoelectric conversion means;
Calibration for detecting a dark current output from the photoelectric conversion means while the signal under measurement is not input, and performing calibration control related to the waveform analysis processing of the waveform analysis processing means based on the dark current. a control means (5e);
An open state provided in an optical input path (31b) to the light receiving section (31a) of the photoelectric conversion element, and not blocking the input of the signal under measurement, which is the optical signal, to the light receiving section, or a closed state blocking the input. an optical shutter means (2) having an optical shutter (2a) that can be opened and closed;
an optical shutter opening/closing control means (5e3) for switching and controlling the optical shutter from the open state to the closed state during execution of the calibration control;
a start condition determination unit (5e1) for determining whether or not a predetermined calibration start condition is satisfied;
a storage unit (6) storing a control data table (6a) in which information indicating the calibration start condition is stored;
When it is determined that the calibration start condition is satisfied, the optical shutter opening/closing control means causes the optical shutter to be in the closed state for a period from immediately before the start of the calibration control until the end of the calibration control. control and
As an operation mode, a calibration UI screen for setting the calibration start condition is displayed on the display unit (8), and on the calibration UI screen, according to the setting operation on the operation unit (7) , a table setting mode for setting the calibration start condition to the control data table;
When the start condition determination unit determines that the calibration start condition set in the table setting mode is met, the calibration execution control unit (5e2) automatically sets and performs calibration. has at least two modes of operation of
In the table setting mode, a UI screen for setting the standard and transmission rate of the signal under measurement is displayed on the display unit, and the standard and transmission rate of the signal under measurement are displayed according to the setting operation on the operation unit. A waveform observation device characterized by being able to set further comprising temperature measuring means (9a) provided near the photoelectric conversion element,
2. The waveform according to claim 1, wherein the start condition determination unit determines that the calibration start condition is satisfied when the temperature measured by the temperature measuring means reaches a predetermined temperature. observation equipment. The start condition determining unit calculates a temperature change amount based on the temperature measured by the temperature measuring means, and determines that the calibration start condition is established when the temperature change amount reaches a preset temperature change amount. 3. The waveform observation device according to claim 2, wherein the waveform observation device determines. Having a timer (9b) for measuring time,
4. The start condition determination unit determines that the calibration start condition is established when a predetermined time interval set in advance by the timer is timed. Waveform observation device according to the item. 5. The waveform observing apparatus according to claim 2, wherein the start condition determination unit determines that the calibration start condition is satisfied by receiving a manual calibration start operation. 6. The optical shutter according to any one of claims 1 to 5, wherein the optical shutter is composed of one of an electro-absorption (EA) optical modulator, a lithium niobate (LN) optical modulator, an optical variable attenuator, and a mechanical optical shutter. 1. The waveform observation device according to 1. When the calibration execution mode is set manually, or when the calibration execution mode is set after receiving the waveform observation start operation, an execution mode screen is displayed on the display unit, and the execution mode screen is displayed according to the progress of the calibration control. 7. The waveform observing apparatus according to any one of claims 1 to 6, wherein an update display of is performed. When the calibration start condition is established during waveform observation, the start condition determination unit determines whether or not calibration is necessary,
8. The method according to any one of claims 1 to 7, wherein when it is determined that calibration is necessary, a manual calibration start operation is accepted after displaying that calibration is necessary on the display unit. Waveform observation device according to. A waveform observation method for observing the waveform of the signal under measurement using the waveform observation device according to any one of claims 1 to 7,
A calibration UI screen for setting the calibration start condition is displayed on the display unit, and the calibration start condition is set on the calibration UI screen according to a setting operation on the operation unit. setting for the control data table;
displaying a UI screen for setting the standard and transmission rate of the signal under measurement on the display unit, and setting the standard and transmission rate of the signal under measurement according to the setting operation on the operation unit; ,
a step of storing the control data table in which information indicating the calibration start condition is stored;
a start condition determination step (S11, S15) for determining whether or not a predetermined calibration start condition is satisfied;
an optical shutter closing control step (S12) for switching and controlling the optical shutter to the closed state by determining that the calibration start condition is satisfied;
When the start condition determination unit determines that the calibration start condition set in the table setting mode is established, the calibration execution control unit automatically sets the calibration execution mode and performs calibration. a step;
a calibration execution step (S2, S5, S13) of executing the calibration control while the optical shutter is controlled to the closed state;
an optical shutter opening control step (S17) for switching and controlling the optical shutter to the open state by the end of the calibration control;
While the optical shutter is controlled to the open state, the signal to be measured input as an optical signal from the object to be measured (50) is converted into an electric signal by the photoelectric conversion element (31), and the photoelectric conversion is performed. a waveform analysis processing step (S3) for performing waveform analysis processing of the signal under measurement output from means (3);
A waveform observation method comprising:

Images