JP2017166968A - Measurement device and measurement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a measurement device and measurement method that can display a measurement result and the like in an easy-to-view fashion without switching screens.SOLUTION: A spectrum analyzer 1 comprises: a display screen 14 that displays a measurement result image indicative of a measurement result; an imaging unit 31 that shoots measures; a visual line direction detection unit 32 that detects a visual line of the measurer on the basis of a shooting image shot by the imaging unit; an area-of-attention identification unit 33a that identifies an area of attention to which the measurer pays attention in the measurement result image on the basis of the visual line detected by the visual line direction detection unit 32; an enlargement image creation unit 33b that creates an area-of-attention enlargement image serving as an image having a prescribed area including the area of attention enlarged; and a display control unit 35 that controls to display the area-of-attention enlargement image on the display screen.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a measuring apparatus and a measuring method provided with a display screen for displaying measurement results of electrical characteristics.

  Conventionally, a signal analysis device described in Patent Document 1 is known as this type of measurement device.

  The conventional device described in Patent Document 1 includes a display device and an operation unit. The display device includes a main display unit that displays parameters for setting measurement conditions and a graph of measurement results, and a sub display unit that displays a plurality of function keys. The operation unit includes a display switch that is operated when setting and changing the parameter value.

  In this configuration, the conventional one is a menu in which each parameter that can be set and changed selectively displayed on the main display section is displayed on each of the plurality of function display keys F1 to F8 on the sub display section. Are displayed in the same color. As a result, the function display keys F1 to F8 to be operated to set and change desired parameter values can be specified by “different colors” determined in advance.

Japanese Patent Laying-Open No. 2015-52519

  However, in the conventional one, it is necessary to display a parameter setting screen, a graph of measurement results, etc. (hereinafter referred to as “measurement results, etc.”) in a limited screen area. The technique of switching and displaying the screen was taken. The technique of displaying the measurement result or the like in a small size has a problem that it becomes difficult to see the measurement result or the like. Further, the method of switching and displaying the screen has a problem that it takes time to switch.

  The present invention has been made to solve the conventional problems, and an object of the present invention is to provide a measuring apparatus and a measuring method capable of displaying a measurement result and the like in an easy-to-view manner without switching the screen.

  A measuring apparatus (1) according to claim 1 of the present invention includes a display screen (14) for displaying a measurement result image (40) showing a measurement result, an imaging means (31) for imaging a measurer, and the imaging means. The gaze direction detection means (32) for detecting the gaze direction of the measurer based on the captured image captured by the gaze direction, and the measurer is gazing based on the gaze direction detected by the gaze direction detection means Gaze area specifying means (33a) for specifying the gaze area (41a) of the measurement result image, and a gaze area enlarged image for generating a gaze area enlarged image (46, 48) that is an enlarged image of the predetermined area including the gaze area. The image forming apparatus includes a generation unit (33b) and a display control unit (35) that performs control to display the gaze area enlarged image on the display screen.

  With this configuration, the measurement apparatus according to claim 1 of the present invention specifies a gaze area of the measurement result image that the measurer is gazing at, and displays a gaze area enlarged image that is an enlarged image of the predetermined area including the gaze area. Since it is generated and displayed, it is possible to easily display the measurement result without switching the screen.

  In the measuring apparatus according to claim 2 of the present invention, the gaze area enlarged image generating means generates a gaze area enlarged image that moves on the measurement result image in accordance with movement of the gaze direction of the measurer. It has a configuration.

  With this configuration, the measurement apparatus according to claim 2 of the present invention generates and displays a gaze area enlarged image that moves on the measurement result image in accordance with the movement of the measurer in the line of sight direction, so that the screen is switched. The measurement results and the like can be displayed in an easy-to-see manner.

  The measurement apparatus (2) according to claim 3 of the present invention includes a display screen (14) for displaying a partial region in the measurement result image (60) indicating the measurement result as a display target region (61-65), An imaging means (31) for imaging the measurer, a gaze direction detection means (32) for detecting the gaze direction of the measurer based on the captured image taken by the imaging means, and according to the movement of the gaze direction Display control means (51, 52) for controlling the display target area to move and display on the display screen.

  With this configuration, the measurement apparatus according to claim 3 of the present invention uses a partial region in the measurement result image indicating the measurement result as a display target region, and moves the display target region according to the movement in the line-of-sight direction for display. Since it is displayed on the screen, it is possible to easily display the measurement result without switching the screen.

  The measurement method according to claim 4 of the present invention includes a display step (S12) for displaying a measurement result image (40) indicating a measurement result on a display screen (14), an imaging step (S13) for imaging a measurer, A gaze direction detection step (S14) for detecting the gaze direction of the measurer based on the captured image captured in the imaging step, and the measurer gazes based on the gaze direction detected in the gaze direction detection step. A gaze area specifying step (S17) for specifying the gaze area (41a) of the measurement result image, and gaze for generating a gaze area enlarged image (46, 48) that is an enlarged image of the predetermined area including the gaze area A configuration including a region enlarged image generation step (S17) and a display control step (S19) for performing control to display the gaze region enlarged image on the display screen. It has.

  With this configuration, the measurement method according to claim 4 of the present invention specifies a gaze area of the measurement result image that the measurer is gazing at, and displays a gaze area enlarged image that is an enlarged image of a predetermined area including the gaze area. Since it is generated and displayed, it is possible to easily display the measurement result without switching the screen.

  In the measurement method according to claim 5 of the present invention, a display step (S32) of displaying a partial area in the measurement result image (60) indicating the measurement result as a display target area (61 to 65) on the display screen (14). ), An imaging step (S33) for imaging the measurer, a gaze direction detection step (S34) for detecting the gaze direction of the measurer based on the captured image captured in the imaging step, and movement of the gaze direction And a display control step (36) for controlling the display target area to be moved and displayed on the display screen.

  With this configuration, in the measurement method according to claim 5 of the present invention, a partial area in the measurement result image indicating the measurement result is set as the display target area, and the display target area is moved according to the movement in the line-of-sight direction. Since it is displayed on the screen, it is possible to easily display the measurement result without switching the screen.

  The present invention can provide a measuring apparatus and a measuring method that have an effect of easily displaying a measurement result and the like without switching screens.

It is a block block diagram of the spectrum analyzer in 1st Embodiment of the measuring apparatus which concerns on this invention. It is an external appearance front view of the spectrum analyzer in a 1st embodiment of a measuring device concerning the present invention. It is a figure which shows an example of the measurement result image which the measurement result image generation part in 1st Embodiment of the measuring apparatus which concerns on this invention produces | generates. It is a figure which shows an example of the synthesized image which the image synthetic | combination part in 1st Embodiment of the measuring apparatus which concerns on this invention produces | generates. It is a flowchart which shows operation | movement of the spectrum analyzer in 1st Embodiment of the measuring apparatus which concerns on this invention. It is a block block diagram of the spectrum analyzer in 2nd Embodiment of the measuring apparatus which concerns on this invention. It is a figure which shows an example of the measurement result image which the measurement result image generation part in 2nd Embodiment of the measuring apparatus which concerns on this invention produces | generates. It is a figure which shows the state by which the upper left area was displayed on the display screen in 2nd Embodiment of the measuring apparatus which concerns on this invention. It is a figure explaining the screen displayed on the display screen in 2nd Embodiment of the measuring apparatus which concerns on this invention. It is a flowchart which shows operation | movement of the spectrum analyzer in 2nd Embodiment of the measuring apparatus which concerns on this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. An example in which the measurement apparatus of the present invention is applied to a spectrum analyzer will be described.

(First embodiment)
First, the configuration of the spectrum analyzer according to the first embodiment of the present invention will be described with reference to FIG.

  As shown in FIG. 1, the spectrum analyzer 1 in this embodiment includes an RF (Radio Frequency) processing unit 20, an ADC (analog / digital converter) 11, a measurement unit 12, a measurement result image generation unit 13, a display screen 14, and an enlarged image. An erasing unit 15 and a display control device 30 are provided. The spectrum analyzer 1 includes a microcomputer including a CPU, a ROM, a RAM, and an input / output circuit to which various interfaces are connected. The spectrum analyzer 1 executes a control program stored in advance in a ROM, thereby causing the microcomputer to function as an RF processing unit 20, an ADC 11, a measurement unit 12, a measurement result image generation unit 13, a display screen 14, and an enlarged image erasure unit 15. The display control device 30 is made to function. The spectrum analyzer 1 is an example of a measuring device.

  The RF processing unit 20 includes a signal mixer 21, a local oscillator 22, a sweep control unit 23, and a filter 24.

  The signal mixer 21 mixes the input signal under measurement and the local oscillation signal from the local oscillator 22 and outputs the mixed signal.

  The local oscillator 22 oscillates a local oscillation signal having a local oscillation frequency that can be swept in a designated frequency band, and outputs the local oscillation signal to the signal mixer 21.

  The sweep control unit 23 sets the frequency of the local oscillation signal to the local oscillator 22 in a predetermined step according to a reference frequency, a sweep width, the number of acquired samples, and the like specified by the operator operating an operation unit (not shown). It is supposed to be swept.

  The filter 24 extracts, for example, an intermediate frequency signal including the difference frequency component from the difference or sum frequency component between the signal under measurement and the local oscillation signal.

  The ADC 11 converts the intermediate frequency signal output from the filter 24 from an analog value signal to a digital value signal and outputs the converted signal to the measurement unit 12.

  The measurement unit 12 includes a waveform memory that stores the waveform data from the ADC 11 for each sweep, and performs predetermined measurement on the stored waveform data. For example, the measurement unit 12 performs measurement calculation processing of measurement items in communication standards determined by the measurer using an operation unit (not shown).

  The measurement result image generation unit 13 is configured to generate a measurement result image including measurement result data, a graph, and the like indicating the results measured by the measurement unit 12. This measurement result image is displayed on a display screen 14 to be described later.

  The display control device 30 includes an imaging unit 31, a line-of-sight direction detection unit 32, an enlarged image generation device 33, an image composition unit 34, and a display control unit 35.

  The imaging unit 31 includes a camera 31a, which will be described later, and images a measurer. For example, the imaging unit 31 captures the direction of the left and right eyes and face of the measurer. The imaged image data of the measurer is output to the line-of-sight direction detection unit 32. The imaging unit 31 is an example of an imaging unit.

  The line-of-sight direction detection unit 32 analyzes the captured image data from the imaging unit 31 and extracts, for example, an image of the eye part of the measurer using a known technique, based on the positional relationship between the pupil of the eye and the white of the eye, or In addition to detecting the gaze direction of the measurer from the orientation of the face, the movement of the gaze direction can also be detected. The line-of-sight direction detection unit 32 obtains the line-of-sight direction by, for example, averaging the movements in the line-of-sight direction so that relatively small movements in the line-of-sight direction can be ignored. The line-of-sight direction detection unit 32 is an example of a line-of-sight direction detection unit.

  The enlarged image generation device 33 includes a gaze area specifying unit 33a and an enlarged image generation unit 33b, and inputs data detected by the line-of-sight direction detection unit 32 and measurement result image data generated by the measurement result image generation unit 13. It is supposed to be.

  The gaze area specifying unit 33 a specifies the gaze area that the measurer is gazing at with respect to the measurement result image displayed on the display screen 14 based on the gaze direction detected by the gaze direction detection unit 32. ing. Specifically, the gaze area specifying unit 33a determines the gaze area when it is determined that the gaze direction of the measurer is substantially fixed for, for example, 3 seconds or more and the measurer is gazeing at the same area. It is specified as a gaze area. The gaze area specifying unit 33a is an example of a gaze area specifying unit.

  When the gaze area is specified by the gaze area specifying unit 33a, the enlarged image generation unit 33b generates a gaze area enlarged image that is an enlarged image of a predetermined area including the specified gaze area. Yes. The enlarged image generation unit 33b is an example of a gaze area enlarged image generation unit.

  The image composition unit 34 synthesizes the gaze region enlarged image and the measurement result image generated by the measurement result image generation unit 13 when the gaze region enlarged image is generated by the enlarged image generation unit 33 b. Is supposed to generate. In addition, when the gaze area enlarged image is not generated by the enlarged image generation unit 33b, the image synthesis unit 34 outputs only the data of the measurement result image.

  The display control unit 35 controls to display only the synthesized image synthesized by the image synthesizing unit 34 or the measurement result image on the display screen 14. The display control unit 35 is an example of a display control unit.

  The display screen 14 is composed of, for example, a liquid crystal panel, and displays a predetermined image in accordance with display control of the display control unit 35.

  The enlarged image erasing unit 15 includes, for example, a push button switch 15 a provided on the front panel of the spectrum analyzer 1. This push button switch 15a is used when erasing the gaze area enlarged image when the gaze area enlarged image is displayed on the display screen 14.

  Next, a detailed configuration and main functions of the spectrum analyzer 1 will be described with reference to FIGS.

  FIG. 2 shows an external front view of the spectrum analyzer 1 in the present embodiment. As shown in FIG. 2, the spectrum analyzer 1 includes a display screen 14. A camera 31 a that constitutes a part of the imaging unit 31 is provided in a substantially central part on the upper side of the display screen 14. 2 shows an example in which one camera 31a is provided, the present invention is not limited to this, and a configuration using, for example, a stereo camera may be used.

  Further, FIG. 2 shows a push button switch 15 a provided in the enlarged image erasing unit 15. When the gaze area enlarged image is displayed on the display screen 14, the gaze area enlarged image is not displayed on the display screen 14 when the measurer presses the push button switch 15 a. Instead of the push button switch 15a, for example, when the gaze direction detection unit 32 detects that the gaze direction of the measurer has moved to the outside of the display screen 14 for a predetermined number of seconds, a gaze area enlarged image is displayed. It is good also as a structure erase | eliminated from the screen 14. FIG.

  FIG. 3 shows an example of the measurement result image 40 generated by the measurement result image generation unit 13. As shown in FIG. 3, the measurement result image 40 includes various measurement items and data 41 indicating the results, data 42 indicating constellation characteristics, and data indicating the relationship between modulation accuracy (Error Vector Magnitude: EVM) and symbols. 43 and data 44 indicating the relationship between the amplitude error (Magnitude Error) and the symbol.

  In a state where the measurement result image 40 shown in FIG. 3 is displayed on the display screen 14, the gaze direction detection unit 32 detects the gaze direction of the measurer, and the gaze region specifying unit 33a gazes the region 41a, for example. When it is specified that the region is a gaze region, the enlarged image generation unit 33b generates a gaze region enlarged image 46 (see FIG. 4A) that is an enlarged image of a predetermined region including the region 41a that is the gaze region. To do.

  FIG. 4A is a diagram illustrating a composite image 45 generated by the image composition unit 34. The composite image 45 is an image in which the measurement result image 40 generated by the measurement result image generation unit 13 and the gaze area enlarged image 46 generated by the enlarged image generation unit 33b are combined.

  In a state where the composite image 45 shown in FIG. 4A is displayed on the display screen 14, when the gaze direction detection unit 32 detects that the gaze direction of the measurer has moved in the lower right direction in the figure. The gaze area enlarged image 46 moves in accordance with the movement in the line-of-sight direction, and for example, a gaze area enlarged image 48 (see FIG. 4B) is displayed. The gaze region enlarged image 48 is an image obtained by enlarging a part of the graph included in the data 44 (see FIG. 3).

  FIG. 4B is a diagram illustrating a composite image 47 generated by the image composition unit 34. The composite image 47 is an image in which the measurement result image 40 generated by the measurement result image generation unit 13 and the gaze area expansion image 48 generated by the enlarged image generation unit 33b are combined.

  The process in which the gaze area enlarged image 46 moves and the gaze area enlarged image 48 is displayed is an image that moves while partially enlarging the measurement result image using, for example, a magnifying glass.

  Next, the operation of the spectrum analyzer 1 in this embodiment will be described with reference to FIG. Note that the signal under measurement input by the spectrum analyzer 1 is processed by the RF processing unit 20 and sent to the ADC 11 and the measurement unit 12 to obtain predetermined measurement results. .

  The measurement result image generation unit 13 generates a measurement result image including measurement result data, a graph, and the like indicating the result measured by the measurement unit 12 (step S11). The generated measurement result image data is output to the display control unit 35 via the image synthesis unit 34.

  The display control unit 35 performs control to display the measurement result image generated by the measurement result image generation unit 13 on the display screen 14 (step S12).

  The imaging unit 31 captures an image of the measurer (step S13) and outputs the imaging data to the line-of-sight direction detection unit 32.

  The line-of-sight direction detection unit 32 analyzes the imaging data from the imaging unit 31 and detects the line-of-sight direction of the measurer (step S14). Data indicating the detected line-of-sight direction is output to the enlarged image generating device 33.

  The enlarged image generating device 33 determines whether or not the enlarged gaze area image is displayed on the display screen 14 (step S15). In FIG. 5, the gaze area enlarged image is abbreviated as an enlarged image.

  If it is not determined in step S15 that the gaze area enlarged image is displayed on the display screen 14, the gaze area specifying unit 33a determines whether or not the gaze area is specified (step S16).

  If it is determined in step S16 that the gaze area has been specified, the gaze area specifying unit 33a specifies the area being watched by the measurer as the gaze area, and the enlarged image generating unit 33b is the gaze area specifying unit. A gaze area enlarged image that is an image obtained by enlarging a predetermined area including the gaze area specified by 33a is generated (step S17). Specifically, the gaze area specifying unit 33a specifies, as the gaze area, the area where the measurer is gazing, for example, when it is determined that the measurer is gazing at substantially the same area for 3 seconds or more.

  On the other hand, if it is not determined in step S16 that the gaze area has been specified, the process returns to step S13.

  The image composition unit 34 generates a composite image obtained by combining the measurement result image generated by the measurement result image generation unit 13 and the gaze area enlarged image generated by the enlarged image generation unit 33b (step S18).

  The display control unit 35 performs control to display the combined image combined by the image combining unit 34 on the display screen 14 (step S19), and returns to the process of step S13.

  If it is determined in step S15 that the gaze area enlarged image is displayed on the display screen 14, whether the push button switch 15a for erasing the gaze area enlarged image has been pressed, that is, the gaze area enlarged image. It is determined whether or not an erase command has been executed (step S20).

  If it is determined in step S20 that the command for erasing the gaze area enlarged image has been executed, the enlarged image erasure unit 15 outputs a command for erasing the gaze area enlarged image to the image composition unit 34 (step S21). Return to step S12. As a result, the image composition unit 34 outputs only the measurement result image data generated by the measurement result image generation unit 13 to the display control unit 35, and only the measurement result image is displayed on the display screen 14. .

  If it is not determined in step S20 that the command to delete the gaze area enlarged image has been executed, the line-of-sight direction detection unit 32 determines whether the line-of-sight direction of the measurer has moved (step S22).

  If it is determined in step S22 that the gaze direction of the measurer has moved, the process proceeds to step S17. If it is not determined that the gaze direction of the measurer has moved, the process returns to step S13. Here, for example, when the line-of-sight direction moves from the upper left to the lower right of the display screen 14, a gaze area enlarged image is sequentially generated along with the movement of the line-of-sight direction and synthesized with the measurement result image. The enlarged image moves from the upper left to the lower right.

  As described above, the spectrum analyzer 1 according to the present embodiment identifies the gaze area of the measurement result image that the measurer is gazing at, and generates a gaze area enlarged image that is an enlarged image of the predetermined area including the gaze area. Therefore, it is possible to easily display the measurement result without switching the screen.

(Second Embodiment)
First, the configuration of the spectrum analyzer 2 in the second embodiment will be described.

  As shown in FIG. 6, the spectrum analyzer 2 in this embodiment is obtained by changing a part of the configuration of the first embodiment (see FIG. 1), and includes a measurement result image generation unit 16 and a display control device 50. ing. The spectrum analyzer 2 is an example of a measuring device. In addition, the same code | symbol is attached | subjected to the structure similar to 1st Embodiment, and the overlapping description may be abbreviate | omitted.

  The measurement result image generation unit 16 generates a measurement result image with a predetermined image size larger than the display area of the display screen 14. That is, a part of the measurement result image generated by the measurement result image generation unit 16 is displayed on the display screen 14. In the present embodiment, the screen resolution of the display screen 14 is set to horizontal 1280 pixels × vertical 1024 pixels.

  The display control device 50 includes an imaging unit 31, a line-of-sight direction detection unit 32, a display area instruction unit 51, and a display control unit 52.

  The display area instruction unit 51 instructs the display control unit 52 to move the display target area of the measurement result image displayed on the display screen 14 in accordance with the movement of the gaze direction detected by the gaze direction detection unit 32. ing. The display area instruction unit 51 is an example of a display control unit.

  The display control unit 52 performs control to display a part of the measurement result image generated by the measurement result image generation unit 16 on the display screen 14 as a display target region based on an instruction from the display region instruction unit 51. ing. That is, the display screen 14 displays a partial area in the measurement result image indicating the measurement result as a display target area. The display control unit 52 is an example of a display control unit.

  Next, functions of the measurement result image generation unit 16 and the display area instruction unit 51 will be described with reference to FIGS.

  FIG. 7 shows an example of the measurement result image 60 generated by the measurement result image generation unit 16. For explanation, the measurement result image 60 includes a left upper region 61, an upper right region 62, a central region 63, a lower left region 64, and a lower right region 65 as partial regions in the measurement result image 60. To do. Similar to the display area of the display screen 14, each of these areas 61 to 65 is composed of horizontal 1280 pixels × vertical 1024 pixels. In addition, the measurement result image 60 is configured with a predetermined image size larger than the display area of the display screen 14, for example, an image of 2800 pixels wide × 2200 pixels vertically. The upper left area 61, the upper right area 62, the central area 63, the lower left area 64, and the lower right area 65 are examples of display target areas.

  FIG. 8 shows a state in which the upper left area 61 is displayed on the display screen 14 of the spectrum analyzer 2. In FIG. 8, even if the gaze direction detection unit 32 detects that the gaze direction of the measurer is substantially fixed for 3 seconds or more and the gaze direction is gazing near the left side or the top side of the upper left region 61, Since the left side and the upper side of the partial area 61 are the outer edges of the measurement result image (see FIG. 7), the display area instruction unit 51 does not give an instruction to move the display target area, and the screen of the display screen 14 does not change.

  Next, when the gaze direction detection unit 32 detects that the measurer is gazing near the right side of the upper left region 61, the display area instruction unit 51 determines that the gaze direction from the gaze direction detection unit 32 is the right direction. Is directed to move the display target area to the right of the upper left area 61.

  Similarly, when the gaze direction detection unit 32 detects that the measurer is gazing near the lower side of the upper left area 61, the display area instruction unit 51 determines that the gaze direction is lower than the gaze direction detection unit 32. Is directed to move the display target area downward in the upper left area 61.

  FIG. 9 is a diagram for explaining a screen displayed on the display screen 14. As described above, for example, when the upper left region 61 is displayed on the display screen 14, the gaze direction detection unit 32 detects that the measurer keeps gazing near the lower side of the upper left region 61. In this case, the display area instruction unit 51 gives an instruction to move the display target area downward in the upper left area 61, so that the lower left area 64 is finally displayed on the display screen 14.

  Further, for example, in a state where the lower left area 64 is displayed on the display screen 14, when the gaze direction detection unit 32 detects that the measurer keeps gazing near the upper right area of the lower left area 64, The display area instruction section 51 gives an instruction to move the display target area in the upper right direction of the lower left area 64, so that after the display of the central area 63, the upper right area 62 is finally displayed on the display screen 14. Is displayed.

  Next, the operation of the spectrum analyzer 2 in the present embodiment will be described with reference to FIG.

  The measurement result image generation unit 16 generates a measurement result image including measurement result data, graphs, and the like indicating the results measured by the measurement unit 12 in a predetermined size larger than the display area of the display screen 14 (step S31). ). Data of the generated measurement result image is output to the display control unit 52.

  The display control unit 52 performs control to display an image of a predetermined region, for example, the upper left region 61 (see FIG. 7) on the display screen 14 among the measurement result images generated by the measurement result image generation unit 16. (Step S32).

  The imaging unit 31 captures an image of the measurer (step S33) and outputs the imaging data to the line-of-sight direction detection unit 32.

  The line-of-sight direction detection unit 32 analyzes the imaging data from the imaging unit 31 and detects the movement of the measurer in the line-of-sight direction (step S34). Data indicating the detected movement in the line-of-sight direction is output to the display area instruction unit 51.

  The display area instruction unit 51 determines whether there is a display area that can be displayed in the detected line-of-sight direction (step S35). Specifically, for example, when the upper left region 61 is displayed on the display screen 14 (see FIG. 8), the gaze direction detection unit 32 gazes near the left side of the upper left region 61. If detected, since the left side of the upper left area 61 is the outer edge of the measurement result image (see FIG. 7), the display area instruction unit 51 determines that there is no displayable display area.

  On the other hand, in the same state, when the gaze direction detection unit 32 detects that the measurer is gazing near the right side of the upper left region 61, a measurement result image exists on the right side of the upper left region 61. Therefore (see FIG. 7), the display area instruction unit 51 determines that there is a display area that can be displayed.

  If it is determined in step S35 that there is no display area that can be displayed, the process returns to step S33.

  On the other hand, if it is determined in step S35 that there is a display area that can be displayed, the display area instruction unit 51 displays the measurement result image to be displayed on the display screen 14 in accordance with the movement of the gaze direction of the measurer. Control for moving the target region is performed on the display control unit 52 (step S36). As a result, a measurement result image corresponding to the movement of the measurer in the line-of-sight direction is displayed on the display screen 14.

  As described above, the spectrum analyzer 2 according to the present embodiment is configured to display the display target area on the display screen 14 by moving the display target area in accordance with the movement of the gaze direction of the measurer. Can be displayed easily.

  As described above, the display device according to the present invention has an effect that the measurement result and the like can be displayed in an easy-to-see manner without switching the screen, and the measurement device including the display screen that displays the measurement result of the electrical characteristics. And it is useful as a measuring method.

1, 2 Spectrum analyzer (measuring device)
13, 16 Measurement result image generation unit 14 Display screen 15 Enlarged image deletion unit 15a Button switch 31 Imaging unit (imaging means)
31a Camera 32 Gaze direction detection unit (Gaze direction detection means)
33 Enlarged image generating device 33a Gaze area specifying unit (gaze area specifying means)
33b Enlarged image generating unit (gaze area enlarged image generating means)
34 Image composition section 35 Display control section (display control means)
40, 60 Measurement result image 41a area (gaze area)
45, 47 Composite image 46, 48 Gaze area enlarged image 51 Display area instruction section (display control means)
52 Display Control Unit (Display Control Unit)
61 Upper left area (display target area)
62 Upper right area (display area)
63 Central area (display area)
64 Lower left area (display target area)
65 Lower right area (display area)

Claims (5)

A display screen (14) for displaying a measurement result image (40) showing a measurement result;
Imaging means (31) for imaging the measurer;
Gaze direction detection means (32) for detecting the gaze direction of the measurer based on a captured image captured by the imaging means;
Gaze area specifying means (33a) for specifying the gaze area (41a) of the measurement result image that the measurer is gazing based on the gaze direction detected by the gaze direction detection means;
Gaze area enlarged image generating means (33b) for generating a gaze area enlarged image (46, 48) which is an image obtained by enlarging the predetermined area including the gaze area;
Display control means (35) for performing control to display the gaze area enlarged image on the display screen;
A measuring apparatus (1) comprising:   2. The measurement according to claim 1, wherein the gaze area enlarged image generation unit generates a gaze area enlarged image that moves on the measurement result image in accordance with movement of the gaze direction of the measurer. apparatus. A display screen (14) for displaying a partial area in the measurement result image (60) indicating the measurement result as a display target area (61-65);
Imaging means (31) for imaging the measurer;
Gaze direction detection means (32) for detecting the gaze direction of the measurer based on a captured image captured by the imaging means;
Display control means (51, 52) for performing control to move the display target area in accordance with the movement in the line-of-sight direction and display on the display screen;
A measuring device (2) comprising: A display step (S12) for displaying the measurement result image (40) indicating the measurement result on the display screen (14);
An imaging step (S13) for imaging the measurer;
A gaze direction detection step (S14) for detecting the gaze direction of the measurer based on the captured image captured in the imaging step;
A gaze area specifying step (S17) that specifies a gaze area (41a) of the measurement result image that the measurer is gazing based on the gaze direction detected in the gaze direction detection step;
A gaze area enlarged image generating step (S17) for generating a gaze area enlarged image (46, 48) that is an image obtained by enlarging the predetermined area including the gaze area;
A display control step (S19) for performing control to display the gaze area enlarged image on the display screen;
A measurement method comprising: A display step (S32) for displaying a partial area in the measurement result image (60) indicating the measurement result on the display screen (14) as a display target area (61-65);
An imaging step (S33) for imaging the measurer;
A gaze direction detecting step (S34) for detecting the gaze direction of the measurer based on the captured image captured in the imaging step;
A display control step (36) for performing control to move the display target area in accordance with the movement in the line-of-sight direction and display on the display screen;
A measurement method comprising:

Images