JP2009133683A - Apd measuring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable observation while easily changing conditions for display such as display range and graph form of an amplitude probability distribution to a change in time, with graphic display of the amplitude probability distribution made as the fundamentals every many channels. <P>SOLUTION: Frequency components of a signal to be measured are analyzed at a frequency analysis section 100, the amplitude of each frequency component (each channel) is detected respectively at a level detection section 200, and an amplitude probability which is an amplitude probability per unit time and within a predetermined probability range is acquired at each passage of a time concerning each frequency component at an APD section 300. A display controller 500 is so structured as to make a display section 600 display the amplitude probability distributions being within the predetermined probability range for each frequency component on a graph whose one axis represents the magnitude of an amplitude and the other axis represents time, in response to the output of the APD section 300. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention analyzes the frequency components of the received signal, and the probability that the magnitude of each frequency component exceeds a predetermined threshold (referred to as amplitude probability distribution or simply as a time rate, hereinafter referred to as “APD”). The present invention relates to an APD measuring apparatus for measuring. In particular, it is an APD measuring apparatus that makes it easy to observe changes in APD.

  An APD measurement technique has been conventionally used. For example, there is a technique of Patent Document 1 that measures APD with high amplitude resolution and time resolution. As an example of applying various techniques to a spectrum analyzer or the like, various displays have been proposed. There is technology.

  On the other hand, recently, there has been a demand for a communication method to simultaneously measure APDs of predetermined multiple frequency components in parallel. For example, as described in Non-Patent Document 1, a standard for digital terrestrial broadcasting is defined as an ARIB standard by the Radio Industries Association (ARIB), and a modulation method based on OFDM (Orthogonal Frequency Division Multiplex Operation Mode) is defined. In this OFDM system, transmission data is divided into thousands of low-speed data in a predetermined band, and digital modulation is performed. For example, the predetermined band is 5.6 MHz, and the transmission data is divided into 1 KHz carrier units, and is digitally modulated in a total of 5,600 lines.

  Therefore, it is desired that the APD measurement in the OFDM system is performed by analyzing the frequency of the signal component every 1 KHz and measuring the APD of each frequency component in parallel. Moreover, it can measure in parallel with the APD described in Patent Documents 1 and 2.

  Regarding the display of the APD, in Patent Document 2, the probability distribution is displayed in a band for each probability range, so that the distribution is identified and displayed so as to be easily visible.

Japanese Patent No. 3156152 Japanese Patent No. 3374154 Toshiba Review VOL. 58 No. 12 (2003), p2-6

  By the way, like APD measurement in the above terrestrial digital broadcasting, the number of frequencies for which APD should be measured simultaneously (in parallel) is large, and the statistical tendency of incoming signals (or noise) is investigated or monitored. Therefore, since the time required for measurement is a long time (a few hours to 24 hours may be exceeded), the measurement results of the frequency components being simultaneously measured are displayed as much as possible at the time of display. It is desirable to be able to display the results for the entire measurement time.

  However, since the display area is finite, for example, if the entire range of the time axis is 24 hours, the data resolution of the time axis becomes wide and detailed observation cannot be performed. Furthermore, there is a demand for not only a change in probability with respect to time but also a change in probability with respect to a level change. A demand for fine observation or changing the coordinate axis may be required during measurement. For example, if these requirements are satisfied after 24 hours of measurement time, the efficiency is poor.

  An object of the present invention is to provide a technique that enables easy observation by changing display conditions such as a display range and a graph form based on a graph display of an amplitude probability distribution with respect to a time change for each of many channels.

  In order to achieve the object of the present invention, the invention of claim 1 includes a frequency analysis unit (100) for analyzing frequency components of a measurement signal, and a level detection unit (200) for detecting the amplitude of each analyzed frequency component. And an APD unit (300) for obtaining an amplitude probability per unit time for each detected frequency component for each elapsed time, and a memory for storing the amplitude probability of each frequency component output by the APD unit in correspondence with the elapsed time Based on the instructions from the unit (400), the display unit (600), the operation unit (700), and the operation unit, one axis is the magnitude of the amplitude and the other axis is the time for each frequency component. And a display control unit (500) that allows the amplitude probability of each frequency component stored in the storage unit to be identified in parallel and displayed on the display unit.

  According to a second aspect of the present invention, in the first aspect of the invention, the display control unit sets the right end of the time axis to be displayed as the current time when the probability is updated and displayed every time it is updated. The graph is displayed by scrolling the time axis by the difference from the time at the previous update.

  The invention according to claim 3 is the invention according to claim 1 or 2, wherein the display control unit divides the APD part of at least one frequency component of the frequency components into a plurality of different predetermined probability ranges. The amplitude probability of each predetermined probability range is obtained, and the display control unit is identified on the graph or / and the enlarged graph for each predetermined probability range and displayed on the display unit so as to be visible. The display unit displays a magnified graph in which the scale of the designated time range is enlarged by the zone marker 2 when a zone marker of the designated time range is attached at the position designated by the operation unit in the above-described manner. Zone enlargement display control means (511) to be displayed.

  According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects, the display control unit specifies and reduces the graph of at least one frequency component of the frequency components by the operation unit. A full span display control means (511) is provided for displaying a graph with a reduced scale of the time axis of the graph on the display unit upon receiving an instruction.

  The invention according to claim 5 is the invention according to any one of claims 1 to 4, wherein the APD unit obtains an amplitude probability of each predetermined probability range and classifies it into a plurality of different predetermined probability ranges, The display control unit is configured to be identified on the graph and / or the enlarged graph for each predetermined probability range and to be displayed on the display unit so as to be visible.

  The invention according to claim 6 is the invention according to any one of claims 1 to 5, wherein the display control unit is for each frequency component obtained by the APD unit and for each predetermined probability range. The amplitude probability at the latest time or at a specified time is displayed numerically.

  The invention according to claim 7 is the invention according to any one of claims 1 to 6, wherein the APD unit has a maximum amplitude value within a specified probability range of a frequency component specified by the operation unit. And a peak search means (540) for obtaining the amplitude probability and the time thereof, and the display control unit is arranged on the displayed graph or / and the enlarged graph with respect to the display unit. And a peak marker display control unit (530) for displaying a visible peak marker at a position corresponding to the maximum amplitude value and the time.

  The invention according to claim 8 is the invention according to claim 7, wherein the peak marker display control unit displays the peak marker on the display unit, and the maximum amplitude value and the probability at that time. It was set as the structure which displays a numerical value.

  The invention according to claim 9 is the invention according to any one of claims 1 to 8, wherein the display control unit receives a graph change instruction by the operation means and designates the graph or / and the enlarged graph. Amplitude / probability graph having one axis as the amplitude and the other axis as the probability based on the amplitude probability at the selected time position or the amplitude probability at the time of the graph change instruction is displayed on the display unit. Probability graph display control means (560) provided

According to the first aspect of the present invention, since the change in the amplitude probability with respect to the time change of the plurality of frequency components (channels) can be updated and displayed in parallel, each channel can be observed in parallel. Since the time axis of each channel is abscissa and the amplitude is ordinate, it is classified into a plurality of amplitude probability ranges on the coordinate and displayed so as to be identifiable. In order to identify, for example, if a plurality of amplitude probability ranges are displayed in different colors, a tendency can be visually recognized from a distance even in a crowded display screen. In other words, the display screen can be used effectively.
According to the second aspect of the present invention, when the graph is updated, the right end of the time axis is corrected (scrolled) to the update time, and the display data is updated. Therefore, the entire horizontal axis range is used effectively.
According to the third aspect of the present invention, since a desired range can be enlarged and displayed, fine observation becomes possible.
According to the fourth aspect of the invention, since the horizontal axis can be reduced and displayed, it is easy to grasp the overall tendency and the progress of measurement.
According to the fifth aspect of the present invention, it is possible to display the band shape and the probability distribution for each probability range so as to be visible.
According to the sixth, seventh, and eighth aspects of the present invention, since a numerical value can be displayed, a value at a desired position that is difficult to read on a graph can be read quantitatively.
According to the seventh aspect of the invention, it is possible to easily know the maximum level and the position of the time within the specified probability range.
According to the ninth aspect of the present invention, the graph can be displayed after being converted into a graph of amplitude versus probability at a specified time position.

  Embodiments according to the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating an overall functional configuration of an embodiment according to an APD measurement apparatus. FIG. 2 is a diagram illustrating a display example of a probability distribution on the coordinates of amplitude (sometimes referred to as level) on the vertical axis and time on the horizontal axis. FIG. 3 is a diagram for explaining a full span display function, a zone marker function, and a zone enlarged display function. FIG. 4 is a diagram for explaining the peak marker function. FIG. 5 is a diagram for explaining the designated marker function. FIG. 6 is a display example of amplitude / probability when an amplitude probability value is designated. FIG. 7 is a display example of amplitude / probability when an amplitude value is designated. FIG. 8 is a display example of the amplitude / probability on the coordinates of the function scale.

Based on FIG. 1, a structure and operation | movement are demonstrated in order of operation | movement.
In FIG. 1, a frequency analysis unit 100 selects an input signal in a desired frequency band (broadband) to be measured, and further selects a desired signal in a narrower desired frequency band (narrowband). Section 110, A / D conversion means 120, and filter bank 130. As the band selection unit 110, for example, if noise in a high-frequency communication frequency band is to be measured, a so-called heterodyne method can be adopted as disclosed in Patent Document 2. That is, the input signal (noise) is mixed by a local oscillator and converted to a low frequency signal, and is limited to a frequency component in a necessary frequency band by using a band pass filter of a desired frequency band (δF). Note that the band selection unit 110 is not necessarily required if the frequency band of the signal to be measured is low and the frequency band can be used by the A / D converter.

  The A / D conversion means 120 receives the frequency component (signal) of the low frequency band-limited by the band selection unit 110, and is fine with an amplitude (level) width ΔL by a clock of a period from a clock generator (not shown). (There is a threshold corresponding to this fineness.) Sampling (sampling) and converting to digital data. The amplitude probability to be obtained later is obtained for each fineness of the level width ΔL at the time of sampling.

  The filter bank 130 receives a low-frequency signal over a frequency band of δF, and is further finer by a band-pass filter group of n (hereinafter also referred to as n (numerical value) channel or n (numerical value) CH). Divide into frequency bands (δF / n). For example, if the channel of the communication line is every 1 kHz, n band-pass filters BPF1 to BPFn having a center frequency shifted by 1 kHz and a frequency band of approximately 1 kHz are provided. The filter bank 130 can be obtained by performing FFT processing in software using a CPU.

  The level detector 200 includes detector detectors DET1 to DETn that detect the amplitude corresponding to each of the bandpass filters of the filter bank 130, that is, the amplitude of each channel, and each channel frequency component (the center frequency of the bandpass filter). The amplitude (level) is detected.

  The APD unit 300 includes APD1 to APDn which are APD detectors that measure amplitude probabilities corresponding to the detectors DET1 to DETn, a clock generation unit 310, and a range classification unit 320. The configurations and operations of the APD1 to APDn are the same, and the amplitude probability is measured by logarithmically converting the outputs of the detectors DET1 to DETn with a LOG converter and converting the unit of amplitude to “dB”. Here, the conventional APD can be adopted as the APD. For example, the APD described in Patent Document 2 or the APD described in Japanese Patent Application No. 2006-253889 can be used.

  APD1 to APDn measure amplitude probability (distribution). The amplitude probability represents the number of times (the number of occurrences) that an input signal of the same magnitude is received within a predetermined time range (period: Δt). The fineness for discriminating the magnitude of the input signal is the same as the fineness ΔL of the A / D conversion means 120 in this example. The time range Δt for measuring the probability follows the control from the clock generator 310. The clock generator 310 uses a pulse generator and a timer, for example, as a time range Δt, such as 1 sec interval, 10 sec interval, or 1 min interval (both may be pulses of these time periods). Amplitude probability is measured by generating a signal and causing APD1 to APDn to measure the frequency of the magnitude of the input signal received within those time ranges. A configuration in which the time range Δt can be changed by changing the count time of the timer through the control unit 800 in accordance with an instruction from the operation unit 700 may be adopted.

  The range classification means 320 classifies into a certain range according to the value of the amplitude probability obtained by calculating each of APD1 to APDn. This is a function provided in order to classify into a range suitable for the survey with a resolution according to the survey purpose, although the survey may be performed with a resolution of 1%, for example. In this embodiment, according to an instruction from the operation unit 700, the amplitude probability is classified into four levels, 0 to 1%, 1% to 10%, 10% to 50%, and 50% to 100%. As a method of classification, for example, the value of the amplitude probability obtained by APD1 to APDn is compared with a plurality of threshold values corresponding to the classified range, and the classification identification tag of the range to which the comparison result belongs is attached. The classification range may be changed by changing to a desired threshold value through the control unit 800 in accordance with an instruction from the operation unit 700. Note that updated amplitude probability values are output from APD1 to APDn for each time range Δt at the earliest.

  The storage unit 400 stores the amplitude values output from the APD1 to APDn and the amplitude probability values over time. The time passage is stored at least for each time range Δt when the amplitude probability is measured. Furthermore, the memory | storage part 400 memorize | stores the classification identification tag when the range classification | category means 320 classify | categorizes corresponding to an applicable amplitude probability value. Note that the above range classification means 320 is not provided on the input side (APD unit 300 side) of the storage unit 400 but is provided on the output side (display control unit 500 side), and the stored amplitude probability value is output. In this case, it may be configured to determine which class the amplitude probability value belongs to, and output the determined class identification tag.

  The display control unit 500 includes the following elements (I) to (IV) for executing display. In other words, as means for receiving an amplitude probability value from the storage unit 400 as a component and displaying (I) a graph on the display unit 600, a graph display control unit 510, an amplitude / probability graph display control unit 560, and A function scale display control means 570; (II) a numerical display control means 520 for performing numerical display; and (III) a peak marker display control means 530, a peak search means 540, and a designation for displaying a marker. A marker display control unit 550; and (IV) a common coordinate information storage unit 580 and a display format storage unit 590 for performing each display. The display control unit 500 includes a program that represents the functions (I) to (IV), a storage unit, and a CPU that executes the program and realizes the functions. Note that the coordinate information stored in the coordinate information storage unit 580 is information necessary for specifying the position of the display screen such as a graph to be displayed, a scale, and each display column. However, it is used to specify the display position when trying to display. In the following description of each element, description of these coordinates is omitted.

  The function operations of the graph display control means 510, the amplitude / probability graph display control means 560, and the function scale display control means 570 in (I) above and the graphs output by them are switched by a switch S. The switch S corresponds to the selection setting when any one of the time / level probability graph display function, the amplitude / probability graph display function, or the function scale display function is selected and set by an instruction from the operation unit 700. The graph display control unit 510, the amplitude / probability graph display control unit 560, or the function display control unit 570 is caused to function.

  The graph display control means 510 has time / level probability display means 513 for displaying basic data in the present invention as shown in FIG. FIG. 2 shows an example in which data of five channels of 23.61 MHz, 24.61 MHz, 25.61 MHz, 26.61 MHz, and 27.61 MHz are displayed in four stages from bottom to top in the vertical direction. Since the display method is the same for each channel, the top 23.61 MHz channel will be described as a representative example. The time / level probability display means 513 acquires the time / level probability display format as shown in FIG. 2 from the display format storage unit 590 and acquires the data such as the amplitude probability value and the amplitude value of each channel from the storage unit 400. indicate.

  First, before the time / level probability display means 513 displays, each of the frequency analysis unit 100, the level detection unit 200, the APD unit 300, and the storage unit 400 is subjected to measurement conditions designated by the operation unit 700, for example, Frequency of all 5 channels, total measurement time (desired acquisition time of data or desired monitoring time), total display time (time that is a part of the total measurement time and is desired to be displayed, 250 sec in the example of FIG. 2), probability Amplitude probability measurement under the following conditions: measurement time range (eg, Δt = 1 sec), 0% to 1%, 1% to 10%, 10% to 50%, 50% to 100% classification range , And the storage is started in association with the measured amplitude probability value, amplitude value (level), and classification range tag.

  The time / level probability display means 513 receives the measurement conditions, the measured amplitude probability value, the amplitude value, and the classification identification tag from the storage unit 400, and reads the time / level probability display read from the display format storage unit 590. Displayed on the display unit 600 according to the format. At that time, the channel frequency is displayed numerically in the CH frequency display column 1010 of FIG. In the horizontal axis display column 1020, the entire display time is displayed with a scale. This is the horizontal axis scale common to the five channels. In the vertical axis display column 1030, the level scale is displayed in units of 10 dB (this is the display range of the amplitude value on the screen and the scale is set in advance as an initial condition). The time / level probability display means 513 plots the amplitude value stored in the storage unit 400 corresponding to the acquisition time, its probability value, and the corresponding classification range in the coordinate space 1040 indicated by the horizontal axis-vertical axis. In addition, it is classified into four levels of 0% to 1%, 1% to 10%, 10% to 50%, and 50% to 100%, and is classified and displayed so as to be visible. In other words, the time change of the probability distribution is displayed. As an example of four-stage identifiable display, the display is identified according to the display pattern as shown in the bottom of FIG. 2, but other methods such as color coding may be used. In FIG. 2, the probability distributions are classified and displayed in a band shape. The rightmost current time position 1060 indicates the latest data of the current time position.

  In the following description, in the case where the horizontal axis is the time axis, “scale” represents a physical dimension (for example, a scale at intervals of 1 cm), and “time scale” is “time” valued as “scale”. "(For example, the physical dimension is 1 cm, but it is 1 sec, 1 hour, or the time for pricing such as 16:38:00). Also, the “horizontal axis display field 1020” may be referred to as “horizontal axis”, and when the horizontal axis is time, it may be referred to as “time axis”. “Reduction and enlargement of the horizontal axis” means reduction and enlargement of the time scale to be priced, not reduction and enlargement of the physical scale. In other words, “the time per physical unit scale is small and large”.

  In FIG. 2, the numerical value display column 1050 is a display column in which [amplitude (level) value, amplitude probability value] is represented by [numerical value dB, numerical value%], that is, from the left, from 0% to 1%, from 1%. They are displayed side by side in four columns of 10%, 10% to 50%, and 50% to 100%. In this case, the numerical display control means 520 displays a numerical display of the current amplitude value and amplitude probability value at the current time position 1060. The current time position 1060 is updated every time range Δt at the earliest with the clock from the clock generation unit 310 and proceeds. When the graph function is switched by the switch S, the numerical display control means 520 does not use the current time position 1060 but the peak marker position shown in the figure, the amplitude value measured at the designated marker position shown in FIG. The probability value can be displayed in the numerical value display column 1050. Hereinafter, the operation of the numerical display control means 520 and the display contents of the numerical display column 1050 will be described in the description of the function of each element.

  In FIG. 2, the display for five channels is performed. However, if the actual measurement is also performed for other channels at the same time and the data is stored in the storage unit 400, the graph display control unit 510 has a function of scrolling in the vertical direction or a function of turning pages in the vertical direction, so that the probability distribution of other channels can also be observed.

  In addition, in the horizontal axis display column 1020, as shown in FIG. 2, the total display time that is scheduled to start from 0 is displayed. In other words, this is a time scale relative to the start. It is also possible to display the absolute time of acquisition time. The storage unit 400 is configured to store an amplitude probability value or the like corresponding to both the relative time and the time of the clock, and can be selected and displayed by an instruction from the operation unit 700. Can be implemented.

  As an example of display by the time / level probability display means 513, FIG. 2 has been described above, but FIG. 2 is an example when the display is reduced according to an instruction from the full span display control means 511 described later. In order to use effectively, in this embodiment, the time / level probability display means 513 performs display in the display format of FIG. In FIG. 3A, the total display time is designated from the operation unit 700 as [total current time position (time range Δt interval) −5 minutes] as the total display time, and the time / level probability display means 513. Has a timer, receives the designation, calculates the time scale of the horizontal axis display field 1020, and obtains the result of 16: 35: 0 to the current time (current time position 1060) 16:40:00 Display time. That is, the time memory 16:40:00 on the right end of the horizontal axis display column 1020 is the current time, and the time / level probability display means 513 calculates and updates the time scale for the entire horizontal axis for each time range Δt. is doing. The amplitude probability distribution is updated along with the change in the current time. Therefore, the time / level probability display means 513 updates the entire scale on the horizontal axis and the amplitude probability distribution over time. In the display in the horizontal axis display column 1020 in FIG. 3A, the entire area of the scale (full scale area) can be used effectively for displaying the probability distribution up to now. This is convenient for long-time measurements. In the case of FIG. 2, there is a difference between the total display time and the time at the current current time position 1060, and an empty space is generated on the display for the difference time.

  The graph display control unit 510 displays the basic graph by the time / level probability display unit 513, but the graph operates in cooperation with the time / level probability display unit 513 and the full span display control unit 511 and the zone. Enlarged display control means 512 is provided. Full span display means that the full scale (all scales) in the horizontal axis display column 1020 (horizontal axis) is displayed as the total measurement time scheduled for the end of measurement from the start time. In such a display, the displayed data waveform is displayed in a form in which the time scale on the horizontal axis is most reduced. However, the full span display control means 511 displays the total measurement time as a time scale on the horizontal axis as described above when the reduction ratio is maximized as described later (full span display). It is also possible to set a reduction ratio at an intermediate stage before the limit is reached, and display can be performed with a scale on the horizontal axis reduced to the intermediate interruption stage. The operation unit 700 counts the time during which the full span setting key is pressed to variably instruct the graph display control means 510 to reduce the reduction rate (zoom amount) of the time width, and calculates the reduction rate. And an encoder that outputs as an electrical signal. Further, the operation unit 700 has a zone enlargement display setting key (not shown) for variably instructing a zone range (observation desired time width). As the zone setting keys, there are a key for setting the center time Tc of the zone and a key (not shown) for setting the time width Tw as the zone width. Alternatively, a key for setting the zone start time Tst and the zone stop time Tsp may be used.

  For example, the full span display control unit 511 displays the total display time instructed to be reduced on all scales on the horizontal axis of the graph when there is an instruction to reduce with the full span setting key when the display of FIG. Data such as an amplitude probability value for the allocated time and the allocated time is read from the storage unit 400, and the time scale on the horizontal axis is reduced and displayed on the time / level probability display means 513 as shown in FIG. . As a result, the total display time is extended. In FIG.3 (b), the time range of a horizontal axis is expanded from 0 to 20 hours for the measurement start time. Accordingly, in FIG. 3 (b), the total display time is longer than that in FIG. 3 (a), but the waveform of the probability distribution data to be displayed is displayed at [Current time position—5 minutes] in FIG. 3 (a). The horizontal axis is reduced and displayed from the waveform of the probability distribution data. The time range on the horizontal axis can be expanded to the total measurement time (full span measurement: Full Span). Moreover, the reverse operation of these is also possible. That is, FIG. 3C can be obtained by instructing enlargement with the zone enlargement display setting key during the display of FIG.

  The full span display control unit 511 performs reduction according to the set reduction ratio with reference to the measurement start time 0 at the left scale end.

  The zone enlargement display control means 512 receives the zone center time Tc and the zone time width Tw, which are instructions from the zone enlargement display fixed key of the operation unit 700, generates markers representing them, and already displays them. A marker indicating the zone is attached to the position of the scale on the horizontal axis of the graph. FIG. 3B shows a display example in which the zone marker is represented by two lines. The interval between the two lines is the zone time width Tw, and the center is the center time Tc.

  When the zone enlargement setting key (confirmation key) of the operation unit 700 is set and confirmed in the display state of FIG. 3B, the zone enlargement display control means 512 is designated to the time / level probability display means 513. The zone marker range [Tc−Tw / 2] to “Tc + Tw / 2” is rescaled as a whole display range on the new horizontal axis, and a graph (enlarged graph) in which the probability of the range is expanded is displayed (FIG. 3 (c)).

  Further, in the state of FIG. 3C, by giving a reduction instruction with the full span display setting key, the control by the zone enlargement display control means 512 is canceled, and the horizontal axis is reduced by the full span display control means 511. The display state can be returned to the display of FIG.

  From the above, the graph display control means 510, that is, the time / level probability display control means 513, the full span display control means 511, and the zone expansion display control means 512 perform the following operations (i) to (iii). Do. (I) Display by default (see FIG. 3A). Set by default display setting key. (Ii) Reduced display is performed (FIG. 3B). Full span (total measurement time) can be displayed. It is set with the full span setting key. (Iii) Perform zone enlargement display (FIG. 3 (c)) Set with the zone enlargement setting key. Then, in response to the setting of each setting key set by the operation unit 700, the graph display control unit 510 smoothly performs the following switching operations (iv) to (vi). (Iv) The switching operation from (i) to (ii) and vice versa, (v) The switching operation from (ii) to (iii) and vice versa, (vi) The above (iii) ) To (i) and vice versa.

  The numerical display of amplitude and amplitude probability in each probability classification in the numerical display column 1050 is performed by the numerical display control means 520. As described above, when the graph is displayed based on the data being measured, the full span display is performed. When performing control and zone enlargement display control, the measured amplitude value and amplitude probability value of the current time (current time position 1060) are numerically displayed in the same manner as described above, regardless of the reduction of the graph display and the zone enlargement display. When not performing measurement and displaying a graph based on past data, when reducing the graph display and performing zone enlargement display, the full span display control means 511 and the zone enlargement display control means 512 are not being measured. Knowing from the control unit 800, it is possible to instruct the numerical display control means 520 not to perform numerical display. However, when the peak marker or the designated marker is set as will be described later, the amplitude value and the amplitude probability value at the position of the designated marker are displayed numerically. It is possible to cancel the numerical display even during measurement. The numerical display control means 520 operates in cooperation with each main part in the display control unit 500. For some, numerical display will be described together with the explanation of each main part.

  The peak search means 540 receives the instruction to turn on the peak marker function and the designation of the amplitude probability value classification range from the operation unit 700 when the display of FIG. The probability amplitude value and the amplitude value within the specified classification range are read out from the storage unit 400, and the maximum amplitude value within the entire display time on the horizontal axis currently displayed and within the specified classification range A corresponding amplitude probability value and time position are obtained. Then, the peak marker display control means 530 has a marker with a shape that is visible at the maximum amplitude value obtained by the peak search means 540 and the time position corresponding to the maximum amplitude value (stored in the display format storage unit 590). Is attached. In addition, an amplitude probability value corresponding to the maximum amplitude value is obtained in advance.

  When the peak marker function is on, the numerical display control means 520 displays the maximum amplitude value obtained by the peak search means 540 in the numerical display field 1050 in charge of the classification range to which the designated amplitude probability value belongs and the The corresponding amplitude probability value is numerically displayed so that it can be recognized that it is a peak function. At that time, the numerical value display control means 520 displays the amplitude value and the amplitude at the time position where the peak marker is present (the time position indicating the maximum amplitude value in the specified classification range) in the numerical value display column other than the specified classification range. Displays the probability value. A display example of these peak markers is shown in FIG. FIG. 4 shows that when the specified classification range is 10% <APD ≦ 50% and the CH frequency is 27.61 MHz, the maximum amplitude value = −45.0 dB, the amplitude probability value = 10.2%, Numeric values are displayed in white. If there are five channels, the same peak marker function can be executed at a time.

  Therefore, the peak marker is attached so as to indicate the position shown in the following (A) to (D). (A) When the designated classification range is 0% <APD ≦ 1%, it indicates coordinates determined by the maximum amplitude value in this range and the time position at that time. (B) When the specified classification range is 1% <APD ≦ 10%, it indicates coordinates determined by the maximum amplitude value in this range and the time position at that time. (C) When the designated classification range is 10% <APD ≦ 50%, it indicates coordinates determined by the maximum amplitude value in this range and the time position at that time. (D) When the specified classification range is 50% <APD ≦ 100%, it indicates coordinates determined by the maximum amplitude value in this range and the time position at that time.

  The designated marker display control means 550 receives the designation of the time position within the entire display time that is the horizontal axis of the currently displayed graph from the operation unit 700, and visually recognizes the designated time position on the displayed graph. A marker having a possible shape (stored in the display format storage unit 590) is attached. Then, the amplitude value and the amplitude probability value of each classification range at the designated time position are read from the storage unit 400 and displayed numerically on the numerical display control means 520. A display example is shown in FIG. In the figure, the designation marker is set at the same time position for each channel by designating one time position. The designated marker can be set by moving according to an instruction from the operation unit 700.

  If there is no instruction such as a designated marker or peak marker during measurement, the designated marker display control means 550 sets the marker position at the current time position (current position). In this case, it is not always necessary to attach a marker that is visible on the graph. This is because the right end of the data can be recognized as the current time position 1060 as shown in FIG. At this time, the numerical display is based on the measurement data (at the current time) (at the current time position 1060).

  Each of the specified marker function and the peak marker function can be performed in any of the above display states (i) to (iii) by the graph display control unit 510. That is, it can be implemented in each of the above-described zone enlargement display function and zoom display function. This is because the designated marker function and the peak marker function share the data handled by the zone enlargement display function and the zoom display function, but are independent of the operation. The simultaneous use of the designated marker function and the peak marker function is not used in this embodiment because the numerical value display field 1050 is limited, but can be used by switching.

  The designated marker function and the peak marker function can be operated independently for each channel when the display is displayed for five channels (FIG. 5 shows an example in which designated markers are attached at different time positions. ). However, in the designated marker function and the peak marker function, it is preferable to set the observation setting conditions, for example, the time position in the designated marker function or the classification range in the peak marker function in the same manner for each channel. This is because, for example, when setting the time position of observation, there is no reason to observe each channel at different times, but rather the same conditions are preferable to know the tendency.

  The amplitude / probability graph display control means 560 displays the measurement data in a coordinate space with the horizontal axis being level (amplitude) and the vertical axis being amplitude probability, for example (the horizontal axis may be amplitude probability and the vertical axis may be level). ). Specifically, as shown in FIG. 5, a specified marker is attached at a desired time position, and the “amplitude / probability display” key in the operation unit 700 is set, whereby the amplitude / probability graph display control means 560 The coordinate space display format with the horizontal axis as level and the vertical axis as shown in FIG. 6 is read out from the display format storage unit 590 and displayed, and the desired space designated by the designated marker in FIG. By receiving and plotting the amplitude probability value and level (amplitude value) at the time position from the storage unit 400, the amplitude / probability graph display as shown in FIGS. 6 and 7 is performed. FIG. 6 is a graph of amplitude / probability after a measurement elapsed time (time position of a designated marker) of about 60 seconds (time position of a designated marker in FIG. 5) in the time range of probability measurement Δt = 1 sec. The data for 5 channels are displayed in an identifiable manner.

  In the above example, the amplitude / probability graph display control unit 560 displays the graph of the amplitude / probability of each channel at the time designated by the designated marker from the display state of FIG. 5, but has been reduced by the zoom display function. Displaying the graph of the amplitude / probability at the time position designated by the designated marker in each display state of the display and the display enlarged by the zone enlargement display function can be performed in the same manner as described above. Further, although the designated marker is not designated in FIG. 5 or the like, when the numerical display function is operating at the current time position 1060 (although the designated marker is not displayed on the display unit 600, the designated marker is substantially By setting the “amplitude / probability display” key when the current time position 1060 is set, a graph of the amplitude / probability at the current time position 1060 can be displayed.

  Further, when the amplitude / probability graph display control means 560 is displaying an amplitude / probability graph, when a setting of a designated marker designating an amplitude probability value or an amplitude (level) value is received from the operation unit 700, The designated marker display control unit 550 attaches a marker to the position of the designated amplitude probability value or amplitude (level) value, and the amplitude value corresponding to the designated amplitude probability value or the amplitude probability corresponding to the designated amplitude value. The value is displayed in the numerical value display column 1070 by the numerical value display control means 520. FIG. 6 shows an example when the designated marker is set by designating 0.1% as the amplitude probability value (APD). The numerical value display column 1070 displays the amplitude value when the amplitude probability in each channel is 1%. FIG. 7 shows an example when the designated marker is set by designating −40 dB as the amplitude (level). In this example, the numerical value display column 1070 displays the amplitude probability value when the amplitude value in each channel = −40 dB. Note that FIG. 6 is a display based on the measurement result when the time position of FIG. 5 is 60 sec (a time other than the current time position 1060), and the probability value and the amplitude value are not updated. In FIG. 5, when the current time position 1060 is designated and switched, the amplitude / probability graph display control unit 560 in FIG. 6 obtains the amplitude value from the storage unit 400 at the time range Δt = 1 sec. In response, the data in FIG. 6 is updated. The data update mode in FIG. 7 is the same as that in FIG.

From the above, the designated marker has the following functions.
-Visually show the time position of the numerical display (Figs. 5, 3 etc.).
The current time position may be specified with a specified marker,
If not specified, the numerical display indicates the current time position.
-Indicates the time position that serves as a bridging reference when switching from the time / amplitude (level) graph to the display amplitude / probability graph (display switching from FIG. 5 to FIG. 6).
Specify an amplitude value or amplitude probability value and visually indicate the position on the amplitude / probability graph.

The function scale display control means 570 plots and displays the amplitude probability values received from the storage unit 400 using the coordinate space based on the function scale related to the amplitude probability distribution predicted for the signal to be measured as the display format. If the actual measured amplitude probability value is plotted on the coordinates to which such a function of the predicted distribution is applied, it can be easily determined whether or not the signal to be measured conforms to the predicted distribution. In general, predicted distributions include Rayleigh distribution, normal distribution, exponential distribution, χ2 distribution, etc., if the signal to be measured is noise. As for obtaining the function scale, there is a technique related to the present applicant and described in Japanese Patent No. 3374154. FIG. 8 shows a display example of the graph display of amplitude probability / amplitude (level) when the distribution whose measurement target is predicted as noise is the Rayleigh distribution.
Regarding the function scale display when the function scale has this Rayleigh distribution, the difference between FIG. 6 and FIG. 8 is different because the scale of the horizontal axis, that is, the scale of amplitude probability is converted. Scale conversion is performed as follows.

When the amplitude probability value x (smaller than 1 and larger than 0) in the scale range [ab] before conversion is displayed at the X position between the Rayleigh distribution scales [mn], the position X is expressed by the following equation. Indicated by
X = {(n−m) / (f (b) −f (a))} {f (x) −f (a)} + m
However, f (x) = log10log10 (1 / x)
Therefore, a display format to which the function of the Rayleigh distribution created by such calculation is applied is stored in the display format storage unit 590 in advance.

  An example of the function scale display is function scale display control means when the function / scale display function is set by an instruction from the operation unit 700 when the amplitude / probability graph display control means 560 is displaying FIG. 570 displays FIG. Another example is when the graph display control unit 510 sets the function display function in response to an instruction from the operation unit 700 during the display of FIG. 5 (in this case, the amplitude / The function scale display control means 570 performs the display of FIG. 8 (the probability graph display function can also be selected).

  An example of a specific operation will be described. When the “Rayleigh function display” function is set in the operation unit 700 while the display as shown in FIG. 6 is performed, the function display control unit 570 has the horizontal axis as the amplitude and the vertical axis as the amplitude probability. 8 is read out from the display format storage unit 590 and displayed in the display space, and the amplitude probability value and amplitude at the desired time position designated by the designated marker in FIG. 5 are displayed. By receiving values (levels) from the storage unit 400 and plotting them, a graph display of amplitude / probability using the Rayleigh distribution as a function scale as shown in FIG. 8 is performed.

  Further, even if the function scale display control means 570 is functioning, the designated marker function designating the amplitude value or the amplitude probability value can be operated. In FIG. 8, when the amplitude probability value is designated as 60%, a marker is attached at a position of 60% on the horizontal axis, and the amplitude value of each channel at that time is numerically displayed. This is the numerical display of the amplitude value of each channel at the amplitude probability value of 60% obtained by searching from the storage unit 400 by the function display control means 570 when the numerical display control means 520 is designated by a marker. This is done by the control means 520 displaying it in the numerical value display column 1050.

  As described above, the present invention can display the graph of the amplitude probability in the time / amplitude (level) coordinate system. Further, in the display, the reduced display function, the zone marker function or the enlarged display function, and the peak marker function are designated. The marker function can be executed. In addition, from the graph display of amplitude probability in the time / amplitude (level) coordinate system, graph display such as graph display in the amplitude / amplitude probability coordinate system or function graph display can be executed. The marker function can be activated. Both can be implemented on multiple channels.

It is a figure showing the whole functional composition of the embodiment concerning an APD measuring device. It is a figure which shows the example of a display of probability distribution on the coordinate of a vertical axis | shaft on an amplitude and a horizontal axis | shaft. It is a figure for demonstrating a full span display function, a zone marker function, and a zone expansion display function. It is a figure for demonstrating a peak marker function. It is a figure for demonstrating a designated marker function. It is an example of a display of amplitude / probability when an amplitude probability value is designated. It is a display example of amplitude / probability when an amplitude value is designated. It is a display example of the amplitude / probability on the coordinates made of a function scale.

Explanation of symbols

100 frequency analysis unit, 110 band selection means, 120 A / D conversion means,
130 filter bank, 200 level detector, 300 APD,
310 clock generation unit, 320 range classification means, 400 storage unit,
500 display control unit, 510 graph display control unit, 511 full span display control unit, 512 zone expansion display control unit, 513 time / level probability display unit,
520 numerical display control means, 530 peak marker display control means,
540 peak search means, 550 designated marker display control means,
560 amplitude / probability graph display control means, 570 function scale display control means,
580 seat table information storage means, 590 display format storage unit, 600 display unit, 700 operation unit,
1010 CH frequency display field, 1020 horizontal axis display field,
1030 vertical axis display field, 1040 coordinate space, 1050 numerical value display field,
1060 Current time position, 1070 Numerical value display column S: Switch

Claims (9)

  A frequency analysis unit (100) for analyzing the frequency component of the signal under measurement, a level detection unit (200) for detecting the amplitude of each analyzed frequency component, and an amplitude probability per unit time for each detected frequency component An APD unit (300) that calculates the frequency of each frequency component, a storage unit (400) that stores the amplitude probability of each frequency component output by the APD unit corresponding to the passage of time, a display unit (600), and an operation unit (700) and each frequency stored in the storage unit as a graph with the amplitude of one axis and the time of the other axis for each frequency component based on an instruction from the operation unit An APD measuring apparatus, comprising: a display control unit (500) that allows component amplitude probabilities to be identified in parallel and displayed on the display unit.   The display control unit displays the graph displayed by scrolling the time axis by the difference from the time at the previous update each time the update is performed, with the right end of the displayed time axis as the current time when the probability is updated and displayed. The APD measuring apparatus according to claim 1, wherein the APD measuring apparatus is performed.   The display control unit attaches a zone marker of a specified time range to a position specified by the operation unit on the graph of at least one frequency component of each frequency component, and when there is an enlargement instruction, 3. The APD measuring apparatus according to claim 1, further comprising: a zone expansion display control unit configured to display an enlarged graph obtained by enlarging the scale of the designated time range by a zone marker on the display unit. .   The display control unit receives a reduction instruction by designating the graph of at least one frequency component of each frequency component by the operation unit, thereby displaying a graph obtained by reducing the scale of the time axis of the graph. The APD measuring apparatus according to claim 1, further comprising a full-span display control unit (511) for displaying on the APD.   The APD unit obtains amplitude probabilities of each predetermined probability range and classifies them into a plurality of different predetermined probability ranges, and the display control unit identifies each predetermined probability range on the graph or / and the enlarged graph. The APD measuring device according to claim 1, wherein the APD measuring device is displayed on the display unit so as to be visible.   The display control unit displays numerically the amplitude probability at the latest time or at a specified time for each frequency component obtained by the APD unit and for each predetermined probability range. The APD measuring device according to any one of 1 to 5.   The APD unit includes peak search means (540) for obtaining a maximum amplitude value, an amplitude probability, and a time within a predetermined probability range in which a frequency component is designated by the operation unit, and further, the display control unit Is a peak marker display control that causes the display unit to display a visible peak marker at a position corresponding to the maximum amplitude value and the time on the displayed graph or / and the enlarged graph. The APD measuring apparatus according to claim 1, further comprising a section (530).   The APD measurement according to claim 7, wherein the peak marker display control unit displays the peak marker on the display unit and numerically displays the maximum amplitude value and a probability value at that time. apparatus.   The display control unit receives a graph change instruction from the operation means, and based on the amplitude probability at a specified time position of the graph or / and the enlarged graph or the amplitude probability at the time of the graph change instruction, 9. An amplitude / probability graph display control means (560) for generating an amplitude / probability graph having an axis as an amplitude and the other axis as a probability and displaying the graph on the display unit. The APD measuring device according to any one of the above.