JP2023133014A - Portable terminal, analysis system, and program - Google Patents

Abstract

To leave information about the analysis of a sample as an evidence with the result of the analysis.SOLUTION: The present invention includes: an analysis processing unit for analyzing a sample on the basis of information of a spectroscopic spectrum obtained by a spectrometer on the basis of reflected light from the sample; a display control unit for displaying the result of analysis by the analysis processing unit in the display unit; and an information acquisition unit for acquiring information about the analysis of the sample. The display control unit displays the information related to the analysis of the sample in relation to the result of analysis, in the display unit.SELECTED DRAWING: Figure 12

Description

The present invention relates to a mobile terminal, an analysis system, and a program.

Nowadays, used home appliances such as air conditioners, television receivers, refrigerators, freezers, washing machines, and clothes dryers are being recycled. Used home appliances are crushed into small pieces at a home appliance recycling factory, then sorted and collected by material type using magnetism, wind power, vibration, etc., and recycled as recycled materials. Among resin materials, polypropylene (hereinafter referred to as PP), polystyrene (hereinafter referred to as PS), and acrylonitrile butadiene styrene (hereinafter referred to as ABS) are often used in home appliances. The resin is sorted and collected by type using a sorting device that utilizes its structure's absorption characteristics in the near-infrared region (wavelength range of 800 to 2,500 nm).

Patent Document 1 describes a spectroscopic analysis that uses light in the wavelength range of 400 nm to 2500 nm to distinguish components in each sample and measure the characteristics of the components, and displays measurement results such as validation error SEV and validation correlation rVal. A method is disclosed.

However, according to conventional analysis systems, including the technique disclosed in Patent Document 1, information related to sample analysis cannot be left as evidence together with the analysis results.

The present invention has been made in view of the above, and an object of the present invention is to preserve information related to analysis of a sample as evidence together with the analysis results.

In order to solve the above-mentioned problems and achieve the objects, the present invention provides an analysis processing unit that analyzes the sample based on information on a spectroscopic spectrum obtained by a spectrometer based on reflected light from the sample; A display control unit that displays the analysis result by the analysis processing unit on a display unit, and an information acquisition unit that acquires information related to the analysis of the sample, the display control unit displaying information related to the analysis of the sample. , displayed on the display unit in association with the analysis result.

According to the present invention, there is an effect that information related to sample analysis can be left as evidence together with the analysis results.

FIG. 1 is a diagram showing the system configuration of an analysis system according to an embodiment. FIG. 2 is a sectional view showing the configuration of the spectrometer. FIG. 3 is a diagram showing a movable mirror. FIG. 4 is a block diagram showing the hardware configuration of a processing section provided in the spectrometer. FIG. 5 is a functional block diagram showing the functional configuration of the processing section of the spectrometer. FIG. 6 is a block diagram showing the hardware configuration of the mobile terminal. FIG. 7 is a functional block diagram showing the functional configuration of the mobile terminal. FIG. 8 is a flowchart showing the flow of processing in the mobile terminal. FIG. 9 is a diagram showing an example of a measurement completion screen. FIG. 10 is a diagram showing an example of a measurement result details screen. FIG. 11 is a diagram showing an example of a photo attachment screen. FIG. 12 is a diagram showing another example of the measurement result details screen. FIG. 13 is a diagram showing an example of a memo input screen.

Embodiments of a mobile terminal, an analysis system, and a program will be described in detail below with reference to the accompanying drawings.

(System configuration)
FIG. 1 is a diagram showing the system configuration of an analysis system according to an embodiment. In FIG. 1, an analysis system 100 includes a spectrometer 102 and a mobile terminal 110. Note that the analysis system 100 may include a plurality of spectrometers 102 for one mobile terminal 110 instead of one spectrometer 102 for one mobile terminal 110.

The spectrometer 102 includes a processor 106 that processes the output, including the intensity of light provided over time by a photodetector provided in the infrared spectroscopy unit 120 . The communication circuit 104 outputs to the outside information in which the output including the time and light intensity of the optical spectrum processed by the processor 106 is associated.

Mobile terminal 110 has an interface 114 and a processor 116. Note that as the mobile terminal 110, for example, a mobile device such as a mobile phone, a tablet terminal, or a smartphone can be used. Furthermore, the mobile terminal 110 has a camera function. Further, the mobile terminal 110 is not limited to a mobile device, and may be an information processing device such as a personal computer, a server, or a notebook PC (Personal Computer). Furthermore, the mobile terminal 110 may be a dedicated analysis device.

The processor 116 calculates the time of the light based on information relating the output including the time and light intensity of the spectroscopic spectrum processed by the processor 106 of the spectrometer 102 and the vibration frequency of the movable mirror of the spectrometer 102. This is converted into wavelength to obtain spectral information consisting of the relationship between the intensity of light for each wavelength of light.

A display 112 serving as a display unit displays information on the spectroscopic spectrum measured by the spectrometer 102 and analysis results such as composition determination results.

In such an analysis system 100, the spectrometer 102 transmits data to the mobile terminal 110 via the communication circuit 104 using wireless serial communication such as Bluetooth (registered trademark). Mobile terminal 110 receives data from spectrometer 102 and processes and analyzes it by processor 116 . Then, the analysis results, such as spectral information and composition determination results, are displayed on the display 112. In addition, the processor 116 may display information on the resin type, composition ratio, additives, etc. on the display 112.

(Detailed configuration of spectrometer)
FIG. 2 is a cross-sectional view showing the configuration of the spectrometer 102. As shown in FIG. 2, the spectrometer 102 includes a light source 216 and a processing section 215a.

The light source 216 irradiates the sample 108 and the like to be subjected to spectroscopic analysis with light in a desired wavelength range. For example, it is an LED (light emitting diode) or a halogen lamp. Light source 216 is located outside of outer frame 210. As the light source 216, a light source that irradiates the object of spectroscopic analysis with light in an appropriate wavelength band is selected and arranged.

The processing unit 215a performs calculations to obtain a spectroscopic spectrum based on the electrical signal input from the photodetector 214. The processing unit 215a also controls the movable mirror 203 to emit light of a desired wavelength to the photodetector 214, and further controls the irradiation of light by the light source 216, for example, the intensity of the light.

The spectrometer 102 also includes an entrance slit 201, a concave diffraction grating 202, a movable mirror 203, and an exit slit 204. The dotted line in the figure shows a portion of the light beam that enters the spectrometer 102, is reflected inside the spectrometer 102, is emitted, and is emitted to the photodetector 214.

The entrance slit 201 is a thin rectangular opening, and guides the light incident from the tapered hole 212 of the outer frame 210 into the frame 209 . The width of the opening of the entrance slit 201 in the lateral direction is, for example, several tens of micrometers to several hundred micrometers. The entrance slit 201 is formed by providing a rectangular through hole in a metal substrate such as nickel. However, the material of the substrate is not limited to metal, and may be semiconductor, resin, or the like. Further, the entrance slit 201 is not limited to a rectangular opening, but may be a circular opening, such as a pinhole. Light that enters the spectroscope 102 from the entrance slit 201 enters the concave diffraction grating 202 .

The concave diffraction grating 202 is an optical element in which thin lines are formed at equal intervals on the surface of a metal concave mirror. However, the material of the base material of the concave diffraction grating 202 is not limited to metal, and may be semiconductor, glass, resin, or the like. Furthermore, the thin lines in the concave diffraction grating 202 may be formed directly on the base material, or may be formed on a thin layer of resin or the like formed on the base material. The concave diffraction grating 202 has a light dispersion function using a diffraction grating and a condensing function using a concave mirror. The light incident on the concave diffraction grating 202 is diffracted and dispersed by the concave diffraction grating 202, and is focused toward the movable mirror 203. Note that light dispersion refers to a phenomenon in which incident light is separated into wavelengths.

The movable mirror 203 is, for example, a MEMS (Micro Electro Mechanical System) mirror in which a movable part provided with a mirror part is integrally formed on a substrate with an elastic beam part as a connecting part. The mirror portion reflects incident light. Moreover, the movable part is rotated by the elastic movement of the elastic beam part, and the mirror surface provided on the movable part is rotated accordingly.

FIG. 3 is a diagram showing the movable mirror 203. Of these, FIG. 3(a) is a side view of the movable mirror 203, and FIG. 3(b) is a plan view of the movable mirror 203. As shown in FIGS. 3A and 3B, in the movable mirror 203, a movable portion 207 is supported by a support portion 206 via a connecting portion 208. The connecting portion 208 has the function of a torsion spring. By applying a driving force such as a piezoelectric drive, an electrostatic drive, or an electromagnetic drive from the drive part, the movable part 207 moves in the direction shown in FIG. 3(a) with the axis AA' in FIG. Rotate in the direction indicated by the dashed-dotted arrow.

By monolithically forming the driving part that rotates the movable part 207 in the support part 206, the movable part 207 can be driven without using an external drive means such as a motor, and the movable part 207 can be made smaller. can do. Although this is just one example, the support portion 206 can be formed of Si (silicon), glass, or the like. If a semiconductor material such as Si is used for the support portion 206, highly accurate microfabrication using a semiconductor process becomes possible.

Returning to FIG. 2, the movable mirror 203 reflects the light dispersed by the concave diffraction grating 202 toward the output slit 204. The angle of reflection of the reflected light is variable by rotating the movable part 207 having a mirror.

The exit slit 204 is a thin rectangular opening, and acts as an opening for exiting the dispersed light from the spectroscope 102 . The exit slit 204 can have the same material and shape as the entrance slit 201.

The exit slit 204 is arranged at the imaging position of the light dispersed by the concave diffraction grating 202 . The imaging position of the light dispersed by the concave diffraction grating 202 is laterally shifted according to the wavelength. Therefore, by changing the reflection angle by the movable mirror 203 and changing the wavelength of the light passing through the output slit 204, it is possible to selectively output light of a desired wavelength among the dispersed light to the photodetector 214. . The photodetector 214 is a photoelectric conversion element such as a Si photodiode, and optical information is output as an electrical signal to perform spectroscopic analysis or the like.

(Hardware configuration of spectrometer processing section)
FIG. 4 is a block diagram showing the hardware configuration of the processing section 215a provided in the spectrometer 102. As shown in FIG. 4, the processing unit 215a includes a CPU (Central Processing Unit) 351, a ROM (Read Only Memory) 352, and a RAM (Random Access Memory) 353. The processing unit 215a also includes an NVRAM (Non Volatile Memory) 354, an output interface (output I/F) 355, an A/D (Analog/Digital) conversion circuit 356, and a mirror drive circuit 357. These are interconnected via a system bus 358.

The CPU 351 centrally controls the operation of the processing section 215a. Further, the CPU 351 calculates a spectroscopic spectrum based on the electrical signal output by the photodetector 214.

The light source drive circuit 359 is electrically connected to the light source 216 and outputs a voltage or current indicating the light intensity of the irradiated light to the light source 216. The light source 216 emits light with an intensity corresponding to the voltage or current input from the light source drive circuit 359.

The processing unit 215a performs calculations to obtain a spectroscopic spectrum based on the input electrical signal. Furthermore, the processing unit 215a also controls the movable mirror 203 using the mirror drive circuit 357 in order to selectively emit light of a desired wavelength.

(Functional configuration of spectrometer processing section)
FIG. 5 is a functional block diagram showing the functional configuration of the processing section 215a of the spectrometer 102. Note that each processing function performed in each functional block shown in FIG. 5 may be realized in whole or in part by a program executed by the CPU 351 described above, or by hardware such as wired logic. It may be realized by

In FIG. 5, the processing section 215a includes an A/D conversion section 461, a spectrum acquisition section 462, a storage section 463, an output section 464, a drive control section 465a, a mirror drive section 466, and a light source drive section 467. has.

The A/D converter 461 receives the analog electrical signal output from the photodetector 214, converts it into a digital signal, and outputs it to the spectrum acquisition section 462, the storage section 463, and the like. The A/D conversion section 461 is realized by the A/D conversion circuit 356 and the like.

The spectrum acquisition unit 462 receives the digital signal output from the A/D conversion unit 461 and calculates the spectrum of the light incident on the spectrometer 102. The calculation results are output to the storage section 463, output section 464, etc. The spectrum acquisition unit 462 is realized by the CPU 351 and the like.

The storage unit 463 stores the calculation results by the spectrum acquisition unit 462 and the digital data output from the A/D conversion unit 461, and outputs these to the output unit 464 in response to a request. The storage unit 463 is realized by the NVRAM 354 or the like.

The output unit 464 outputs the calculation result by the spectrum acquisition unit 462 or the digital signal data output by the A/D conversion unit 461 to the mobile terminal 110. The output unit 464 is realized by the output I/F 355 or the like.

The drive control section 465a outputs a control signal to control the mirror drive section 466 and the light source drive section 467. The drive control section 465a is realized by the CPU 351 and the like.

The mirror drive section 466 outputs a voltage or current to the movable mirror 203 in accordance with the control signal, and rotates the movable section 207 so as to obtain a desired reflection angle. The mirror drive section 466 is realized by the mirror drive circuit 357 and the like.

Here, the spectrometer 102 has a battery 218 as shown in FIG. The spectrometer 102 also includes a housing 217 that houses the spectroscopic analysis unit 200, the processing section 215a, and the battery 218.

The battery 218 supplies power to the processing unit 215a. For example, it is a lithium ion battery, a dry battery, a PSU (Power Supply Unit), or the like.

The processing unit 215a may include a communication control unit, and may be capable of transmitting and receiving calculation results of spectra by short-range communication or communication via the Internet.

Alternatively, the outer frame 210 and the housing 217 may be integrally formed. A thermometer may be provided on the outer frame 210.

In this way, by providing the battery 18 for supplying power, there is no need to prepare and install a power source separately from the spectrometer 102. This makes it easy to perform spectroscopic analysis on various objects at any location or time.

(Hardware configuration of mobile terminal)
FIG. 6 is a block diagram showing the hardware configuration of the mobile terminal 110. As shown in FIG. 6, the mobile terminal 110 includes a CPU 401, a ROM 402, a RAM 403, an EEPROM 404, a CMOS sensor 405, an image sensor I/F 406, an acceleration/direction sensor 407, a media I/F 409, and a GPS receiving section 411. ing.

Among these, the CPU 401 controls the overall operation of the mobile terminal 110. The ROM 402 stores the CPU 401 and programs used to drive the CPU 401 such as IPL. RAM 403 is used as a work area for CPU 401. The EEPROM 404 reads or writes various data such as application programs, reference resin data, and measurement data under the control of the CPU 401. The CPU 401, ROM 402, RAM 403, and EEPROM 404 constitute the processor 116 described above.

A CMOS (Complementary Metal Oxide Semiconductor) sensor 405 is a type of built-in imaging means (camera) that images a subject (mainly a self-portrait) and obtains image data under the control of the CPU 401. Note that instead of a CMOS sensor, an imaging means such as a CCD (Charge Coupled Device) sensor may be used. The image sensor I/F 406 is a circuit that controls driving of the CMOS sensor 405.

The acceleration/direction sensor 407 is a variety of sensors such as an electronic magnetic compass, a gyro compass, and an acceleration sensor that detect geomagnetism. A media I/F 409 controls reading or writing (storage) of data to a recording medium 408 such as a flash memory. GPS receiving section 411 receives GPS signals from GPS satellites.

The mobile terminal 110 also includes a long distance communication circuit 412, a CMOS sensor 413, an image sensor I/F 414, a microphone 415, a speaker 416, a sound input/output I/F 417, a display 112, an external device connection I/F (Interface) 419, It includes a short-range communication circuit 420, an antenna 420a of the short-range communication circuit 420, and a touch panel 421.

Among these, the long distance communication circuit 412 is a circuit that communicates with other devices via a communication network. The CMOS sensor 413 is a type of built-in imaging means (camera) that images a subject and obtains image data under the control of the CPU 401. The image sensor I/F 414 is a circuit that controls driving of the CMOS sensor 413.

Microphone 415 is a built-in circuit that converts sound into electrical signals. The speaker 416 is a built-in circuit that converts electrical signals into physical vibrations to produce sounds such as music and voice. The sound input/output I/F 417 is a circuit that processes input/output of sound signals between the microphone 415 and the speaker 416 under the control of the CPU 401 .

The display 112 is a type of display means such as a liquid crystal or organic EL (Electro Luminescence) that displays an image of a subject, various icons, and the like.

The external device connection I/F 419 is an interface for connecting various external devices. The near field communication circuit 420 corresponding to the above-mentioned interface 114 is a communication circuit such as NFC (Near Field Communication) or Bluetooth (registered trademark), and is used for communication with the spectrometer 102. The touch panel 421 is a type of input means by which the user operates the mobile terminal 110 by pressing the display 112.

The mobile terminal 110 also includes a bus line 410. The bus line 410 is an address bus, a data bus, etc. for electrically connecting each component such as the CPU 401 shown in FIG. 6.

(Functional configuration of information processing device)
FIG. 7 is a functional block diagram showing the functional configuration of the mobile terminal 110. Note that each processing function performed in each functional block shown in FIG. 5 may be realized in whole or in part by a program executed by the above-mentioned processor 116, or by hardware such as wired logic. This can also be achieved with clothing.

As shown in FIG. 7, the mobile terminal 110 includes an analysis processing section 1101, a display control section 1102, and an information acquisition section 1103.

The analysis processing unit 1101 analyzes the composition of the sample 108 based on the information of the spectroscopic spectrum obtained by the spectrometer 102 based on the reflected light from the sample 108 .

In addition, the analysis processing unit 1101 stores the analysis results in the EEPROM 404 in a manner that can be shared with external devices (such as another smartphone or PC).

The display control unit 1102 displays the analysis result by the analysis processing unit 1101 on the display 112. Furthermore, the display control unit 1102 displays information related to the analysis of the sample 108 on the display 112 in association with the analysis results.

The information acquisition unit 1103 acquires information related to the analysis of the sample 108.

For example, the information acquisition unit 1103 acquires photographic data of the sample 108 as information related to the analysis of the sample 108. In this case, the display control unit 1102 displays photographic data of the sample 108 on the display 112 in association with the analysis results.

Further, for example, the information acquisition unit 1103 acquires text data related to the analysis of the sample 108 as information related to the analysis of the sample 108. In this case, the display control unit 1102 displays text data related to the analysis of the sample 108 on the display 112 in association with the analysis results. Further, for example, the information acquisition unit 1103 acquires audio data related to the analysis of the sample 108 as information related to the analysis of the sample 108. In this case, the information acquisition unit 1103 converts audio data related to the analysis of the sample 108 into text data. The display control unit 1102 displays the text data converted by the information acquisition unit 1103 on the display 112 in association with the analysis result. Alternatively, the display control unit 1102 may display a link of the audio data in association with the analysis result on the display 112 so that the audio data can be output.

(Inspection flow)
Next, an inspection method for determining the composition of the resin-containing sample 108 using such an analysis system will be described.

First, the operator turns on the spectrometer 102, starts the mobile terminal 110, and starts an application program by, for example, tapping an app icon.

Next, the operator places the window 211 of the spectrometer 102 facing the sample 108 containing resin, and presses a measurement start button provided on the casing 217 of the spectrometer 102. As a result, the sample 108 is irradiated with near-infrared light emitted from the light source 216 of the spectrometer 102. (irradiation process)

Note that this irradiation step may be performed by pressing a measurement start button provided on the housing 217, but may also be performed by pressing a button provided on the mobile terminal 110, or by pressing a button on the display 112 of the mobile terminal 110. This may be done by pressing the displayed measurement start button B1 (see FIG. 9).

Next, reflected light generated by irradiating the sample 108 with the irradiation light is guided to the photodetector 214 via the entrance slit 201. The electrical signal output from the photodetector 214 is supplied to the processing section 215a. Such an operation may be repeated multiple times to reduce repeat measurement errors. Measurement accuracy improves by repeating the operation.

The processing unit 215a performs a calculation to obtain a spectroscopic spectrum based on the input electrical signal (obtains a spectroscopic spectrum). The processing unit 215a transmits this optical spectrum to the mobile terminal 110 via the communication circuit 104.

Here, FIG. 8 is a flowchart showing the flow of processing in the mobile terminal 110. As shown in FIG. 8, the analysis processing unit 1101 of the mobile terminal 110 performs averaging, smoothing, normalization, differentiation, scattering correction, baseline correction, and peak shift correction on the spectroscopic spectrum received from the spectrometer 102. , or a combination thereof to calculate a plurality of parameter values corresponding to each wavelength point (step S1).

After the processing step, the analysis processing unit 1101 of the mobile terminal 110 performs an analysis step (step S2). In the analysis process, the analysis processing unit 1101 of the mobile terminal 110 applies a plurality of reference spectra (reference resin data) stored in the EEPROM 404, which is a storage unit of the processor 116, to the parameter values calculated in the processing process. , a value representing the degree of similarity between the composition of the resin-containing sample 108 and the plurality of candidate compositions, or in other words, the probability, is calculated.

The degree of similarity is, for example, a correlation coefficient. For the degree of similarity, a score value of principal component analysis, etc. can also be used. The EEPROM 404, which is a storage unit of the processor 116, stores reference spectra derived from resin materials mainly used in home appliances or OA equipment. For example, sample 108, which is a resin material used in home appliances or OA equipment, mainly consists of general-purpose resins such as PE (polyethylene), PP (polypropylene), PVC (polyvinyl chloride), PS (polystyrene), and PET (polyethylene). terephthalate), ABS (acrylonitrile, butadiene, styrene copolymer synthetic resin), and PC (polycarbonate). Note that a mixture of PC and PS or a mixture of PC and ABS is also common.

Next, the analysis processing unit 1101 of the mobile terminal 110 performs a determination process (step S3). In the determination step, the analysis processing unit 1101 determines the candidate composition with the highest degree of similarity among the degrees of similarity calculated in the analysis step as the composition of the sample 108 containing resin.

Next, the analysis processing unit 1101 of the mobile terminal 110 stores the measurement data, which is the analyzed and determined result, in the EEPROM 404 in a manner that can be shared with an external device (another smartphone, PC, etc.) (step S4).

Note that the mobile terminal 110 can export data (measured data, reference resin data) stored in the EEPROM 404 and export data (measured data, reference resin data) to the EEPROM 404 by transmitting and receiving data via Bluetooth connection or the like with an external device. Import is possible.

Note that in this embodiment, the measurement data is stored in the EEPROM 404 of the mobile terminal 110, but the measurement data is not limited to this, and may be stored in an external storage device, a server, or the like.

Subsequently, the display control unit 1102 of the mobile terminal 110 displays the thus analyzed and determined results on the display 112 of the mobile terminal 110 as a measurement completion screen D1 (see FIG. 9) (step S5).

Here, FIG. 9 is a diagram showing an example of the measurement completion screen D1. As shown in FIG. 9, the measurement completion screen D1 displays, in addition to the measurement date and time a, the name b of the measured resin as the determination result. The example shown in FIG. 9 shows that the composition of sample 108 is determined to be ABS resin, for example. In addition, in the example shown in FIG. 9, a correlation coefficient c indicating the degree of similarity with the measured resin is displayed below the name b of the measured resin. In the example shown in FIG. 9, the measurement start button B1 mentioned above is also displayed.

Further, the measurement completion screen D1 shown in FIG. 9 displays a [View details] icon d and an [Attach photo] icon e.

Note that when the volume of the mobile terminal 110 is not muted, the display control unit 1102 may output the name b of the measured resin as a sound from the speaker 416 at a set volume.

Next, detailed confirmation of the measurement results will be explained.

When the operator taps the "View details" icon d on the measurement completion screen D1, the display control unit 1102 of the mobile terminal 110 displays the measurement result details screen D2 on the display 112 of the mobile terminal 110 (see FIG. 10).

Here, FIG. 10 is a diagram showing an example of the measurement result details screen D2. As shown in FIG. 10, the measurement result details screen D2 includes, in addition to the measurement date and time a, the name of the measured resin b, and the correlation coefficient c, which were explained in the measurement completion screen D1, a list of judgment results f and the measured A spectral graph g of the spectral waveform of the resin is displayed. On the measurement result details screen D2, data can be confirmed by scrolling up and down.

In the example shown in FIG. 10, in addition to ABS resin, PVC (polyvinyl chloride) and PE (polyethylene) are listed as candidates along with the degree of similarity in the list f of determination results.

In the example shown in FIG. 10, the spectrum graph g of the measured spectral waveform of the resin has the horizontal axis as the wavelength and the vertical axis as the value (absorbance) obtained by calculation in the analysis processing unit 1101. Note that when the operator taps the spectrum graph g, the display control unit 1102 of the mobile terminal 110 enlarges/reduces the graph and displays it.

Further, the measurement result details screen D2 shown in FIG. 10 has a list button B2. When the operator taps the list button B2, the display control unit 1102 of the mobile terminal 110 displays a list of measurement data on the display 112.

In addition, the measurement result details screen D2 shown in FIG. 10 includes a [take photo] icon h for adding or changing a photo, a photo display field i, and a [memo] icon j for adding or editing a memo. and a memo column k are displayed. These are examples of screens, and the [Memo] icon j may be on the screen shown in FIG. 9.

Next, attaching a photo of the measured resin will be explained.

When the worker taps the "Attach photo" icon e on the measurement completion screen D1 or taps the "Take photo" icon h on the measurement result details screen D2, the display control unit 1102 of the mobile terminal 110 A photo attachment screen D3 is displayed on the display 112 (see FIG. 11).

Here, FIG. 11 is a diagram showing an example of the photo attachment screen D3. As shown in FIG. 11, the photo attachment screen D3 displays a [take photo] icon l and a [album photo] icon m.

When the worker taps the "take photo" icon l, the information acquisition unit 1103 of the mobile terminal 110 activates the CMOS sensor 413, which is the camera of the mobile terminal 110. The operator photographs the measured resin using the CMOS sensor 413 of the mobile terminal 110. The information acquisition unit 1103 of the mobile terminal 110 stores the photographed data in the EEPROM 404. The display control unit 1102 of the mobile terminal 110 displays photographic data of the measured resin in the photo display column i of the measurement result details screen D2.

On the other hand, when the worker taps the [album photo] icon m, the information acquisition unit 1103 of the mobile terminal 110 selects a desired photograph (photograph data) from among the photographs (photograph data) stored in the EEPROM 404 of the mobile terminal 110. ) can be selected. The display control unit 1102 of the mobile terminal 110 displays the selected photographic data in the photo display column i of the measurement result details screen D2.

Here, FIG. 12 is a diagram showing another example of the measurement result details screen D2. As shown in FIG. 12, photographic data obtained by photographing the measured resin is displayed in the photograph display column i of the measurement result details screen D2.

Next, adding a memo to the measurement results will be explained.

When the operator taps the "memo" icon j on the measurement completion screen D1, the display control unit 1102 of the mobile terminal 110 displays a memo input screen D4 on the display 112 of the mobile terminal 110 (see FIG. 13).

Here, FIG. 13 is a diagram showing an example of the memo input screen D4. As shown in FIG. 13, the memo input screen D4 displays a memo input field n and a save icon o.

When the worker taps the memo input field n on the memo input screen D4, the information acquisition unit 1103 of the mobile terminal 110 displays a keyboard. The operator uses the displayed keyboard to input the content he/she wishes to record regarding the measurement results. The input contents include measurement date and time, measurement location, business negotiation records (interview destination, location, etc.), and the number written on the resin. For example, up to 200 characters can be entered in the memo input field n.

When the operator taps the save icon o after completing the input to the memo input field n of the memo input screen D4, the information acquisition unit 1103 of the mobile terminal 110 saves the input content in the EEPROM 404 as text data related to the analysis of the sample 108. do.

For example, when the information acquisition unit 1103 acquires audio data related to the analysis of the sample 108 as information related to the analysis of the sample 108, the memo input screen D4 shown in FIG. It may also include a button. When the worker taps the voice input (recording) button on the memo input screen D4, the information acquisition unit 1103 of the mobile terminal 110 converts the voice data related to the analysis of the sample 108 input from the microphone 415 into text data. do. The display control unit 1102 stores the text data converted by the information acquisition unit 1103 in the EEPROM 404. Note that a button for audio input (recording) may be provided on the screen shown in FIGS. 9 and 10.

Note that when the operator taps the memo field k on the measurement result details screen D2, the display control unit 1102 of the mobile terminal 110 displays the entire text of the entered content on the display 112 as a memo.

As described above, according to this embodiment, information related to the analysis of the sample 108 can be left as evidence together with the analysis results.

For example, by acquiring photographic data of the sample 108 as information related to the analysis of the sample 108 and displaying it on the display 112 in association with the analysis results, the photographic data at the time of measurement can be attached to the measurement history. Therefore, the condition (stain, color, shape, mixture, etc.) of the waste plastic sample 108 can be confirmed. In other words, depending on the condition of the waste plastic, it becomes possible to set an appropriate transaction price (sellers can set a high price, buyers can set an appropriate price).

In addition, by acquiring text data related to the analysis of the sample 108 as information related to the analysis of the sample 108 and displaying it on the display 112 in association with the analysis results, it is possible to leave notes related to the analysis. You can leave a record of. This makes it easier to remotely check goods and determine whether a transaction is possible.

Further, according to the present embodiment, the analysis results are stored in the storage unit (for example, EEPROM 404) in a manner that can be shared with external equipment, so that the analysis results can be stored in the storage unit (e.g., EEPROM 404). It is now possible to share data on waste plastics, and analysis results can be shared between multiple devices. This makes it possible to ensure the safety and security of both parties' transactions. Furthermore, by sharing data, it is possible to match the destinations of waste and those that receive it. Furthermore, it becomes easier to construct a database.

As described above, according to the present embodiment, in conventional resin transactions, even if the sample 108 that is the object of transaction contains impurities, the receiving party has no choice but to be depressed. ) and memos (text data) can serve as evidence, and with evidence, you can trade at a higher price and ensure the safety of your business.

Note that in this embodiment, the mobile terminal 110 includes the analysis processing section 1101, the display control section 1102, and the information acquisition section 1103, but the invention is not limited to this. 1101, a display control section 1102, and an information acquisition section 1103.

Finally, the embodiments described above are presented as examples and are not intended to limit the scope of the present invention. This new embodiment can be implemented in various other forms, and various omissions, substitutions, and changes can be made without departing from the gist of the invention. Furthermore, the embodiments and modifications of the embodiments are included within the scope and gist of the invention, and are also included within the scope of the invention described in the claims and its equivalents.

100 Analysis System 102 Spectrometer 108 Sample 110 Mobile Terminal 112 Display Unit 404 Storage Unit 1101 Analysis Processing Unit 1102 Display Control Unit 1103 Information Acquisition Unit

Patent No. 4710012

Claims (6)

an analysis processing unit that analyzes the sample based on information on a spectroscopic spectrum obtained by a spectrometer based on the reflected light from the sample;
a display control unit that displays the analysis result by the analysis processing unit on a display unit;
an information acquisition unit that acquires information related to analysis of the sample;
Equipped with
The display control unit displays information related to the analysis of the sample on the display unit in association with the analysis result.
A mobile terminal characterized by: The information acquisition unit acquires photographic data obtained by photographing the sample as information related to analysis of the sample,
The display control unit displays photographic data obtained by photographing the sample on the display unit in association with the analysis result.
The mobile terminal according to claim 1, characterized in that: The information acquisition unit acquires text data related to the analysis of the sample as information related to the analysis of the sample,
The display control unit displays text data related to the analysis of the sample on the display unit in association with the analysis result.
The mobile terminal according to claim 1, characterized in that: The analysis processing unit stores the analysis results in a storage unit in a manner that can be shared with an external device.
The mobile terminal according to any one of claims 1 to 3, characterized in that: a spectrometer that obtains spectroscopic information based on light reflected from the sample;
A mobile terminal according to any one of claims 1 to 4,
An analysis system comprising: computer,
an analysis processing unit that analyzes the sample based on information on a spectroscopic spectrum obtained by a spectrometer based on the reflected light from the sample;
a display control unit that displays the analysis result by the analysis processing unit on a display unit;
an information acquisition unit that acquires information related to analysis of the sample;
It is a program to function as
The display control unit displays information related to the analysis of the sample on the display unit in association with the analysis result.
A program characterized by:

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