JP6848822B2 - Device status display device - Google Patents

Description

The present invention relates to a device status display device.

A device for notifying an alarm cause by using a plurality of LEDs and a plurality of switches is known. For example, Patent Document 1 discloses a method for displaying detailed alarms of a printer. The printer includes three switches and two LEDs. In the alarm detail display method of the printer, a plurality of alarm causes are identified by a combination of three switch on / off states and a combination of two LED lighting patterns. For example, when the three switches are in the off, off, and on states, and the lighting patterns of the two LEDs are in the off and on states, respectively, the alarm detail display method is that the printer status is the alarm cause 1. Identify that. As described above, in the alarm detail display method of the printer, a plurality of alarm causes can be identified by a combination of turning on / off of three switches and lighting of two LEDs.

Japanese Unexamined Patent Publication No. 63-56479

Since the above printer does not have an LCD (Liquid Crystal Display), a 7seg LED, or a display in which point light sources are arranged in a plane, if the number of error states increases, the above alarm detail display method may cause an error. The number of LEDs required for display and the lighting patterns of LEDs will increase. This causes a problem that it becomes difficult for the user to identify the state of the device. Further, the alarm detail display method of the printer has no suggestion for specifying the desired combination of the switch and the LED until the combination is specified. Therefore, since the combination of switch on / off and the LED lighting pattern are checked in order, there is a problem that it takes time for the user to identify the error state.

An object of the present invention is a state of a device capable of giving a suggestion as to which key should be pressed to specify the state of the device while suppressing an increase in a display unit and a display pattern necessary for displaying the state of the device. It is to provide a display device.

The state display device of the device of one aspect of the present invention includes a plurality of keys corresponding to each of the plurality of states in the device, and a desired key corresponding to a state generated among the plurality of states among the plurality of keys. A first determination means for determining that a key different from the desired key has been pressed, and at least one of the plurality of keys, which is less than the plurality of states and the first determination means is any of the plurality of keys. When it is determined that the key has been pressed, a display unit capable of emitting light based on the pressed key, and when the first determination means determines that the desired key has been pressed, the display unit has a first emission pattern. A light emitting control means for causing the display unit to emit light in a second light emitting pattern giving a suggestion of finding the desired key when the first determining means determines that a key different from the desired key is pressed. It is characterized by being prepared.

In this case, in the state display device of the device, when the first determination means determines that the desired key is pressed, the display unit emits light in the first emission pattern. Since the plurality of states in the device correspond to each of the plurality of keys, the user can identify one of the plurality of states by observing the desired key corresponding to the plurality of states and the first light emission pattern. Can be done. Further, in the state display device of the device, since a plurality of states correspond to each of the plurality of keys, it can be realized by at least one display unit. Therefore, the user can easily identify the state of the device. When a key different from the desired key is pressed, the state display device of the device gives the user a suggestion regarding the identification of the desired key by emitting light in the second light emitting pattern. Therefore, when the user tries to find a desired key corresponding to a plurality of states of the device, the user can identify the desired key with a smaller number of times than pressing all of the plurality of keys in order. Therefore, the user can easily identify the desired key.

When the first determination means determines that a key different from the desired key has been pressed, the state display device of the device determines whether or not a key within a predetermined range from the desired key has been pressed. The light emitting control means further comprises means, and the light emitting control means causes the display unit to emit light in the second light emitting pattern only when the second determining means determines that a key within the predetermined range is pressed from the desired key. May be good. In this case, in the state display device of the device, when the second determination means determines that a key within a predetermined range is pressed from the desired key, the display unit emits light in the second emission pattern. Therefore, the user can specify that the pressed key is within a predetermined range from the desired key when the display unit emits light in the second light emission pattern.

When the first determination means determines that a key different from the desired key has been pressed, the state display device of the device determines whether or not a key next to the desired key has been pressed. The light emitting control means may further include means, and when the third determining means determines that the key adjacent to the desired key is pressed, the display unit may emit light in a third light emitting pattern. In this case, in the state display device of the device, when the third determination means determines that the key next to the desired key is pressed, the display unit emits light in the third emission pattern. Therefore, the user can specify that the desired key is one next to the pressed key when the display unit emits light in the third light emission pattern.

When the first determination means determines that a key different from the desired key has been pressed, the state display device of the device determines whether or not a key two adjacent to the desired key has been pressed. The light emitting control means further comprises means, and when the fourth determining means determines that the key two adjacent to the desired key is pressed, the display unit displays the fourth light emitting pattern different from the third light emitting pattern. The light may be emitted in a light emission pattern. In this case, in the state display device of the device, when the fourth determination means determines that the key two adjacent to the desired key is pressed, the display unit emits light in a fourth emission pattern different from the third emission pattern. When the status display device of the device emits light in the fourth light emission pattern, the user can specify that there is a desired key two keys next to the pressed key. Further, since the light emission pattern emits light in a fourth light emission pattern different from the third light emission pattern, the user can surely identify that the key two adjacent to the pressed key is the desired key.

In the state display device of the device, the plurality of keys can be classified into a plurality of areas corresponding to the positions of the plurality of keys, and in the state display device of the device, the first determination means is the desired key. Further provides a fifth determination means for determining whether or not a key classified into the same area as the area corresponding to the desired key among the plurality of areas is pressed when it is determined that a different key is pressed. When the fifth determination means determines that a key classified in the same region as the region corresponding to the desired key is pressed, the light emission control means causes the display unit to emit light in the fifth light emission pattern. You may. In this case, in the state display device of the device, when the fifth determination means determines that a key classified in the same area as the area corresponding to the desired key is pressed, the display unit emits light in the fifth light emission pattern. .. When the display unit emits light in the fifth light emission pattern, the user can identify that the desired key is a key classified in the same area as the pressed key. Therefore, the user can easily identify the position of the desired key.

In the state display device of the device, the plurality of keys are arranged in a predetermined area, and when the state display device of the device determines that a key different from the desired key has been pressed by the first determination means, The sixth determination means for determining whether or not the desired key is on one side of the predetermined region with respect to the pressed key is further provided, and the light emission control means is such that the sixth determination means is the desired. When it is determined that the key is on the one side of the predetermined area with respect to the pressed key, the display unit may emit light in the sixth light emitting pattern. In this case, in the state display device of the device, when the sixth determination means determines that the desired key is on one side of the predetermined area with respect to the pressed key, the display unit emits light in the sixth light emission pattern. The user can specify that the desired key is on one side of a predetermined area with respect to the pressed key when the display unit emits light in the sixth light emitting pattern.

In the state display device of the device, the display unit may be an LED provided in the device. In this case, since the display unit is an LED provided in the device, the state display device of the device can display the state of the device using the LED already provided in the device. Therefore, it is not necessary to separately install a new LED in the device.

In the state display device of the device, the LED may emit light in a plurality of colors. In this case, since the display unit emits light in a plurality of colors, the state of the device can be specified by the lighting pattern due to the difference in color.

The state display device of the device further includes a seventh determination means for determining that the device is in a predetermined state in which any of the plurality of states has occurred, and the light emission control means has the seventh determination. When it is determined that the means is in the predetermined state, the display unit may emit light in the seventh light emitting pattern. In this case, in the state display device of the device, when the seventh determination means determines that a predetermined state has occurred in the device, the display unit emits light in the seventh light emission pattern. The user can identify that the device is in a predetermined state when the display unit emits light in the seventh light emission pattern.

The state display device of the device may display an error of the printing device. In this case, the device status display device displays an error in the printing device. When a user of a printing device tries to find a desired key, he / she can identify the desired key with a smaller number of times than pressing all the keys in order.

It is a perspective view of the printing apparatus 1. It is a block diagram which shows the electrical structure of the printing apparatus 1. This is an error table showing the attributes, error names, and ID numbers of the printing device 1. It is a figure which shows the light emission pattern of LED 6A in the error mode of printing apparatus 1. It is a flowchart of error identification process 1. It is a flowchart of the first light emission pattern blinking number determination process. It is a flowchart of error identification process 2. It is a flowchart of error identification process 3.

<Overview of printing device 1>
Hereinafter, the printing apparatus 1 according to the embodiment of the present invention will be described with reference to the drawings. The reference drawings are used to illustrate the technical features that can be adopted by the present invention. The configuration of the apparatus shown, the flowcharts of various processes, and the like are not limited to these, but are merely explanatory examples. In the following description, the lower right side, the upper left side, the upper right side, the lower left side, the upper side, and the lower side of FIG. 1 are defined as the right side, the left side, the rear side, the front side, the upper side, and the lower side of the printing apparatus 1, respectively.

As shown in FIG. 1, the printing apparatus 1 includes a housing 2, a cover 3, a panel 4, keys 5A, 5B, 5C, 5D, 5E, 5F, LEDs 6A, 6B, 6C, an outlet 7, a tray 8, and a connector ( It includes a cutter 30 (see FIG. 2), a fan motor 32 (see FIG. 2), a head 34 (see FIG. 2), a conveyor motor 36 (see FIG. 2), a medium detection sensor 38 (see FIG. 2), and the like. .. The housing 2 has a box shape in which the upper portion is open, and has a substantially rectangular shape in front view and plan view. The cover 3 is rotatably supported at the rear of the housing 2. The cover 3 swings up and down on the front end side with a rotation axis extending in the left-right direction as a fulcrum to open and close the housing 2. At the time of printing, the cover 3 covers the upper part of the housing 2. The panel 4 is provided on the front side of the cover 3. The keys 5A, 5B, 5C, 5D, 5E, and 5F are provided on the panel 4 and are arranged in order from the left side to the right side of the panel 4. The LEDs 6A, 6B, 6C are provided on the panel 4 and are provided behind the keys 5A, 5D, and 5E, respectively. The keys 5A, 5B, 5C, 5D, 5E, and 5F accept the input of the operation by the user. The discharge port 7 is provided on the front side and the lower side of the keys 5A, 5B, 5C, 5D, 5E, and 5F, and is long in the left-right direction. The discharge port 7 discharges the printed medium after printing. The tray 8 supports the printed medium after printing discharged from the discharge port 7. A power cord (not shown) is connected to the connector, and the connector is provided at the lower part of the back surface of the housing 2. A USB cable (Universal serial Bus cable) for connecting to an external terminal 29 (see FIG. 2) or the like is further connected to the connector (not shown). The cutter 30 cuts the print medium. The fan motor 32 discharges the air inside the printing device 1 to the outside. The head 34 is used for printing on a printing medium (see FIG. 2). The transfer motor 36 feeds the print medium. The medium detection sensor 38 detects the presence or absence of a print medium.

The external terminal 29 is, for example, a general-purpose personal computer (PC), a mobile terminal, a tablet terminal, or the like. The CPU (not shown) of the external terminal 29 executes a program (not shown) of the installed driver and creates print data from the image data. The printing device 1 performs a printing process based on the created print data. A detailed description of the printing process will be omitted.

<Electrical configuration of printing device 1>
The electrical configuration of the printing apparatus 1 will be described with reference to FIG. The printing device 1 includes a control board 212. The control board 212 controls the printing device 1, and controls the CPU 21, ROM 22, RAM 23, flash memory 24, input / output interface 25, input circuit 26, LED drive circuit 27, USB interface 28, cutter drive circuit 31, and fan drive. A circuit 33, a head drive circuit 35, a transport drive circuit 37, a wireless LAN module 39, and the like are provided. The CPU 21 controls the printing device 1. The ROM 22, the RAM 23, and the flash memory 24 are connected to the CPU 21 via a bus. Further, the CPU 21 includes an input circuit 26, an LED drive circuit 27, a USB interface 28, a cutter drive circuit 31, a fan drive circuit 33, a head drive circuit 35, and a transport drive circuit 37 via an input / output interface 25. The wireless LAN module 39 is connected. The ROM 22 stores the programs of the first light emission pattern blinking number determination process and the error identification processes 1, 2, and 3 executed by the CPU 21. The ROM 22 also stores an error table 50, which will be described later. The RAM 23 stores various temporary data. The flash memory 24 stores print data received from the external terminal 29.

The input circuit 26 is connected to the keys 5A, 5B, 5C, 5D, 5E, and 5F, and is connected to the CPU 21 via the input / output interface 25. The input circuit 26 receives inputs from the keys 5A, 5B, 5C, 5D, 5E, and 5F. The input circuit 26 transmits the key input information received by the input circuit 26 to the CPU 21 via the input / output interface 25. The LED drive circuit 27 is connected to the LEDs 6A, 6B, and 6C, and is connected to the CPU 21 via the input / output interface 25. The LED drive circuit 27 controls the on / off of the LEDs 6A, 6B, 6C by energizing the LEDs 6A, 6B, 6C. The CPU 21 controls the energization of the LEDs 6A, 6B, and 6C via the LED drive circuit 27.

The USB interface 28 communicates with the external terminal 29 via the USB cable. Therefore, the printing device 1 receives print data from the external terminal 29 via the USB cable. The printing device 1 communicates with the external terminal 29 by wireless connection such as Bluetooth (registered trademark) and Wi-Fi (registered trademark) by the wireless LAN module 39 described later. The cutter drive circuit 31 is connected to the cutter 30 and is connected to the CPU 21 via the input / output interface 25. The cutter drive circuit 31 controls the operation of the cutter 30 in accordance with the instructions of the CPU 21. The fan drive circuit 33 is connected to the fan motor 32 and is connected to the CPU 21 via the input / output interface 25. The fan drive circuit 33 controls the rotation of the fan motor 32 according to the command of the CPU 21. The head drive circuit 35 is connected to the head 34 and is connected to the CPU 21 via the input / output interface 25. The head drive circuit 35 drives the head 34 in accordance with a command from the CPU 21. The transfer drive circuit 37 is connected to the transfer motor 36 and is connected to the CPU 21 via the input / output interface 25. The transfer drive circuit 37 drives the transfer motor 36 in accordance with a command from the CPU 21. The medium detection sensor 38 detects the presence or absence of a print medium. The wireless LAN module 39 is a module for communicating with the external terminal 29 by wireless LAN. The wireless LAN module 39 is a module for making a wireless connection such as Bluetooth (registered trademark) and Wi-Fi.

The keys 5A, 5B, 5C, 5D, 5E, and 5F are in a state where no abnormality (hereinafter, referred to as "error") or the like has occurred in the above configuration of the printing device 1 (hereinafter, referred to as "normal mode"). Responsible for the following roles. The key 5A is a power ON / OFF key, and the power of the printing device 1 is turned ON / OFF by pressing and holding the key 5A. The key 5B is a feed key, and is used to feed a fixed amount of the print medium by driving the transport motor 36 to align the print medium. The key 5C is a cut key, and is used to feed a fixed amount of the print medium and cut the print medium by the cutter 30. The key 5D is a Bluetooth (registered trademark) key, and is used to wirelessly connect the external terminal 29 and the wireless LAN module 39 by Bluetooth (registered trademark). The key 5E is a Wi-Fi key and is used to wirelessly connect the external terminal 29 and the wireless LAN module 39. The key 5F is a WPS key (Wi-Fi Protected Setup key), and is used to make the printing device 1 connect to a peripheral access point. The WPS key is a standard established by Wi-Fi Alliance for easily setting a wireless LAN connection. By pressing the key 5F, it is possible to automatically set the wireless LAN corresponding to WPS.

The LEDs 6A, 6B, and 6C are lit corresponding to the roles of the keys 5A, 5D, and 5E adjacent to each front side when the printing device 1 is in the normal mode. The LED 6A is a multi-color type LED, and green and red light emitting elements are incorporated in one exterior. In addition to emitting light in green and red, the LED 6A emits light in orange by simultaneously emitting light in green and red light emitting elements. The LED 6A represents a power ON / OFF state of the printing apparatus 1, a system off state, or a cover open state. When the printing device 1 is turned on, the LED 6A lights up in green. When the power of the printing device 1 is turned off, the LED 6A is turned off. When the printing device 1 is in the system off state, the LED 6A lights up in orange. The system off state means a state in which the printing device 1 is in the transition period until the power is turned off by pressing and holding the key 5A. When the cover is open, the LED 6A lights orange. LED6B represents the connection state of Bluetooth® of the printing apparatus 1. When the Bluetooth® connection is valid, the LED 6B lights blue. If the Bluetooth® connection is not valid, the LED 6B will turn off. LED6B flashes blue when reconnecting to Bluetooth®. LED6C represents a connection state of a wireless LAN or the like. When the wireless LAN connection of the printing device 1 is in the connection established state, the LED 6C lights up in green. When the wireless LAN connection of the printing device 1 is in the unconnected state or the connection attempted state, the LED 6C blinks in green. When the wireless LAN connection is invalid, the LED 6C turns off. The state in which the wireless LAN connection is established means that the printing device 1 has completed the wireless LAN connection to the external terminal 29. The wireless LAN connection is not connected or the connection attempted state means a state in which the printing device 1 tries to connect to the external terminal 29 by wireless LAN but has not completed the connection. For example, in the unconnected state, the printing device 1 recognizes the external terminal 29, but the wireless LAN connection such as waiting for password input is not connected. Further, the connection trial state is a state in which the printing device 1 recognizes the external terminal 29 and tries to connect to the wireless LAN. The wireless LAN connection invalid state means a state in which the wireless LAN connection between the printing device 1 and the external terminal 29 is invalid.

In this embodiment, the LEDs 6A, 6B, 6C may be used for other purposes than the function in the normal mode. For example, LEDs 6A, 6B, and 6C are also used in the case of selecting a reset method or a mode in which an error described later occurs (hereinafter, referred to as "error mode"). In the following description, the LED 6A functions as an LED for displaying an error occurrence. In the error mode, the LED 6A emits red light.

In the error mode assumed by the present embodiment, there is no relationship between the LEDs 6A, 6B, and 6C, and each of the LEDs 6A, 6B, and 6C independently displays an error. For example, the LED 6B and the LED 6C emit light in the same role as in the normal mode, whereas the LED 6A independently blinks in red to display an error.

<About error attributes and error names>
With reference to the error table 50 of FIG. 3, the attributes of the error assumed in the printing apparatus 1 and the error name (hereinafter, also referred to as “error type”) will be described. When an error occurs and the printing device 1 is in the error mode, the CPU 21 refers to the error table 50 stored in the ROM 22 and identifies the state of the printing device 1. The error state of the printing device 1 is divided into six attributes according to the type of error. Attributes are classified into media, data transfer, database, wireless LAN, USB host, and system.

Media-related errors include tape end errors, feed errors, medialess errors, media error errors, and the like. ID numbers 11, 12, 13, and 14 are assigned to the tape end error, the feed error, the mediumless error, and the medium error error corresponding to the error name, respectively. The tape end error means a state in which the tape provided in the printing apparatus 1 is used up. A feed error is a state in which the print medium cannot be fed due to a paper jam or the like. The medium-less error means a state in which the print medium is not attached to the printing device 1. The medium error error refers to a state in which a print medium different from the medium information transmitted from the external terminal 29 is attached to the printing device 1.

Errors related to data transfer include communication command error, memory full error, ECSP memory full error, JPEG file error, and the like. ID numbers 21, 22, 23, and 24 are assigned to the communication command error, the memory full error, the ECSP memory full error, and the JPEG file error, respectively, corresponding to the error names. A communication command error is a state in which the CPU 21 cannot find an appropriate communication command. The memory full error means a state in which the storage capacity in the RAM 23 has reached the upper limit. The ESCP memory full error is a state in which the storage capacity of the receive buffer has reached the upper limit in printing by the printer print control command ESCP. A JPEG file error means that the JPEG file cannot be read.

Database-related errors include database search errors and templateless errors. ID numbers 31 and 32 are assigned to the database search error and the templateless error corresponding to the error name, respectively. A database search error is a state in which a search for a character string related to a database has failed. The no-template error means that the print data template cannot be selected.

Errors related to wireless LAN include access point search error, access point connection error, security error, and the like. ID numbers 41, 42, and 43 are assigned to the access point search error, access point connection error, and security error, respectively, according to the error name. An access point search error is a state in which an access point cannot be searched. The access point connection error is a state in which the access point to be connected to the printing device 1 cannot be specified. The security error refers to a state in which a security error related to the wireless LAN connection of the wireless LAN module 39 has occurred.

Errors related to the USB host include a USB host power supply over error, a USB host non-compatible device connection error, and a USB host HUB connection error. ID numbers 51, 52, and 53 are assigned to the USB host power supply over error, the USB host non-compatible device connection error, and the USB host HUB connection error, respectively, corresponding to the error names. The USB host power supply over error is a state in which the supply current from the USB host flows at a rating of 0.5 A or more. A device connection error that does not support a USB host means that the USB host does not support the connected USB standard. A USB host HUB connection error refers to a state in which a HUB is connected to a USB host.

As system errors, memory error, head error, fan motor error, built-in power supply low voltage error, and wireless LAN module error are assigned. ID numbers 61, 62, 63, 64, and 65 are assigned to memory errors, head errors, fan motor errors, built-in power supply low voltage errors, and wireless LAN module errors, respectively, according to the error names. A memory error refers to a state in which information in a memory such as ROM 22 or RAM 23 cannot be read. The head error refers to a state in which an abnormality has occurred in the head 34 of the printing apparatus 1. The fan motor error refers to a state in which an abnormality has occurred in the cooling fan motor 32 of the printing apparatus 1. Built-in power supply low voltage error means that the built-in power supply voltage is lower than the specified value. The wireless LAN module error refers to a state in which communication cannot be performed due to some abnormality in the wireless LAN module 39.

The relationship between the keys 5A, 5B, 5C, 5D, 5E, and 5F and each attribute when the printing device 1 is in the error mode will be described. In this embodiment, in the error mode of the printing apparatus 1, the key 5A corresponds to an error related to the medium. Key 5B corresponds to an error related to data transfer. Key 5C corresponds to an error related to the database. The key 5D corresponds to the error related to the wireless LAN. Key 5E corresponds to an error regarding the USB host. Key 5F corresponds to an error related to the system.

The light emission pattern of the LED 6A in the error mode will be described with reference to FIG. In FIG. 4, the white portion indicates that the LED is turned off, and the black portion indicates that the LED is turned on in red. The horizontal axis indicates the time axis. The LED 6A has a first light emission pattern, a second light emission pattern, a third light emission pattern, a fourth light emission pattern, and a fifth light emission pattern based on the error occurrence state of the printing device 1 in the error mode, the attribute of the error that has occurred, the type of error, and the like. Light can be emitted by a light emission pattern, a sixth light emission pattern, a sixth light emission pattern A, a sixth light emission pattern B, a seventh light emission pattern, and the like. The LED 6A can also emit light by combining the above light emission patterns. The first light emission pattern repeats a set of blinking as many times as the number corresponding to the last digit of the ID number after an interval of a predetermined time. The interval means a period during which the LED 6A is turned off. Here, the first light emission pattern shown in FIG. 4 corresponds to, for example, the case of an error without a medium, and shows the light emission pattern when the last digit of the corresponding ID number (13) is 3. Therefore, in the first light emission pattern shown in FIG. 4, after an interval of a predetermined time (0.9 sec as an example), lighting (0.3 sec as an example) and extinguishing (0.3 sec as an example) are repeated three times (as an example). 1.5 sec) Repeat the set. In the present embodiment, the number of blinks of the first light emission pattern after the predetermined time interval is maximum because the numerical value of the wireless LAN module error (attribute: system) is 5 with respect to the last digit of the ID number. 5 times. Therefore, the first emission pattern has a plurality of blinking patterns (not shown).

The second light emission pattern is a light emission pattern that emits light in the seventh light emission pattern described later after repeating lighting (0.1 sec as an example) and extinguishing (0.1 sec as an example) four times in a fine cycle. The third light emission pattern is turned on (0.1 sec as an example) and turned off (0.1 sec as an example) four times in a fine cycle after an interval (0.5 sec as an example) which is approximately half of the interval of the first light emission pattern. It is a light emission pattern that emits light in the seventh light emission pattern after being repeated (0.8 sec as an example). The fourth light emission pattern is turned on (0.1 sec as an example) and turned off (0.1 sec as an example) four times in a fine cycle after an interval of the same time as the interval of the third light emission pattern (0.5 sec as an example). It is a light emission pattern that emits light in the seventh light emission pattern after the repeated set is performed twice (2.4 sec as an example). The fifth light emission pattern is a light emission pattern that emits light in the seventh light emission pattern after repeating lighting (0.1 sec as an example) and extinguishing (0.1 sec as an example) five times in a fine cycle. The sixth light emission pattern is a light emission pattern that emits light in the seventh light emission pattern after repeating lighting (0.1 sec as an example) and extinguishing (0.1 sec as an example) four times in a fine cycle. The sixth light emission pattern A lights up for about half the lighting time of the seventh light emission pattern (0.3 sec as an example), and turns on and off (0.1 sec as an example) and turns off (0.1 sec as an example) in a fine cycle. It is a light emission pattern that emits light in the seventh light emission pattern after being repeated four times (0.8 sec as an example) and after an interval (0.5 sec as an example). The sixth light emission pattern B repeats lighting (0.1 sec as an example) and extinguishing (0.1 sec as an example) four times in a fine cycle, and is turned on for a period of about half of the lighting time of the seventh light emission pattern (as an example). 0.3 sec), it is a light emission pattern that emits light in the seventh light emission pattern via an interval (0.5 sec as an example). In the seventh light emission pattern, light emission (0.3 sec as an example) and extinguishing (0.3 sec as an example) are alternately repeated. When light is emitted by the combination of the above light emission patterns, the same light emission pattern as the seventh light emission pattern of each light emission pattern may not be present, or may be repeated for a predetermined time. For example, when the third light emission pattern and the sixth light emission pattern A are combined, the timing of switching from the third light emission pattern to the sixth light emission pattern A is such that after blinking four times in a fine cycle, light emission in the seventh light emission pattern for a predetermined time is performed. It switches to the sixth light emission pattern A via.

<First Embodiment>
Next, the error identification process 1 of the printing apparatus 1 will be described with reference to FIG. When the key 5A of the printing device 1 is pressed and held and the power is turned on, the CPU 21 reads the program of the error identification process 1 shown in FIG. 5 from the ROM 22 and executes it. In the error identification process 1, the printing device 1 specifies whether or not the pressed key is within a predetermined range from the desired key. The predetermined range is a range from the desired key corresponding to the error generated in the printing device 1 to the key in the preset range. Further, pressing the key 5A means a short press that does not turn off the power, which is different from a long press of the key 5A when the power is turned on / off. The CPU 21 detects whether an error has occurred at regular intervals (S11). If it is determined that no error has occurred (S11: NO), the CPU 21 repeats S11. When it is determined that an error has occurred (S11: YES), the CPU 21 turns on the error flag and shifts to the error mode (S13). In this case, the CPU 21 stores the error flag "1" in the RAM 23 as the error flag is on. The error flag "0" is stored in the RAM 23 as an off state when the power of the printing device 1 is turned on. Next, the CPU 21 causes the LED 6A to emit light in a seventh light emitting pattern indicating that some error has occurred (S15). As a result, the CPU 21 notifies the user that some error has occurred in the printing device 1. Next, the CPU 21 advances the process to S16.

The flow of the first light emission pattern blinking number determination process will be described with reference to FIG. The first light emitting pattern blinking number determination process is a process of determining the number of blinking times of the first light emitting pattern after a predetermined time interval. The CPU 21 identifies the error that has occurred (S501). The CPU 21 identifies an error that has occurred in each configuration of the printing device 1 via the input / output interface 25. For example, in the case of a medium-less error, the printing device 1 detects a signal in which the printing medium is not mounted by the medium detection sensor 38, and sends the signal to the CPU 21. The CPU 21 identifies the type of error generated by the signal from the medium detection sensor 38. For example, as the medium detection sensor 38, a transmissive photo sensor is used.

Next, the CPU 21 refers to the error table 50 and identifies the ID number associated with the identified error (S503). The CPU 21 determines whether or not the last digit of the ID number is 1 (S505). When the last digit of the ID number is 1 (S505: YES), the CPU 21 determines that the number of blinks of the first light emission pattern after the predetermined time interval is 1 (S507). The CPU 21 advances the process to S17. If the last digit of the ID number is not 1 (S505: NO), the CPU 21 advances the process to S509. When it is determined that the last digit of the ID number is 2 (S509: YES), the CPU 21 determines that the number of blinks of the first light emission pattern after the predetermined time interval is 2 (S511). The CPU 21 advances the process to S17. If it is determined that the last digit of the ID number is not 2 (S509: NO), the CPU 21 advances the process to S513.

When the last digit of the ID number is 3 (S513: YES), the CPU 21 determines that the number of blinks of the first light emission pattern after the predetermined time interval is 3 (S515). The CPU 21 advances the process to S17. When it is determined that the last digit of the ID number is not 3, the CPU 21 advances the process to S517. When it is determined that the last digit of the ID number is 4 (S517: YES), the CPU 21 determines that the number of blinks of the first light emission pattern after the predetermined time interval is 4 (S519). The CPU 21 advances the process to S17. When it is determined that the last digit of the ID number is not 4, the CPU 21 determines that the number of blinks of the first light emission pattern after the predetermined time interval is 5 (S521). The CPU 21 advances the process to S17.

The user who recognizes the error notification presses any of the keys 5A, 5B, 5C, 5D, 5E, and 5F in order to identify the attribute of the error that has occurred in the printing device 1. Hereinafter, the key corresponding to the generated error is referred to as a "desired key". Next, the CPU 21 determines whether or not there has been a key input (S17). If it is determined that there is no key input (S17: NO), the CPU 21 returns the process to S15. In this case, the LED 6A continues to emit light in the seventh light emission pattern. The CPU 21 returns the process to S17 and waits for the key input. When there is a key input (S17: YES), the CPU 21 advances the process to S19.

When the desired key is pressed (S19: YES), the CPU 21 causes the LED 6A to emit light in the first light emission pattern, which is the LED light emission pattern indicating the error name (S21). As a result, each of the plurality of keys 5A, 5B, 5C, 5D, 5E, and 5F corresponds to the error attribute of the printing device 1, so that the user can specify the error attribute of the printing device 1. it can. Further, the user can identify the type of error in the relationship between the number of blinks and the last digit of the ID number by observing the number of blinks after the interval of a predetermined time in the first light emission pattern of the LED 6A. ..

The CPU 21 advances the process to S23. The CPU 21 determines whether or not the generated error has been cleared (S23). The error cancellation determination is determined by the CPU 21 detecting that the function has been restored via the input / output interface 25. For example, in the case of a medium-less error, it can be canceled by replenishing the printing device 1 with a printing medium. When the print medium is replenished, the CPU 21 can detect the state in which the print medium is set by the signal from the medium detection sensor 38. If the error is not cleared (S23: NO), the CPU 21 returns the process to S21. In this case, the CPU 21 continues the light emission of the LED 6A in the first light emission pattern. If it is determined that the error has been cleared (S23: YES), the CPU 21 advances the process to S25. The CPU 21 sets the error flag “1” stored in the RAM 23 to the error flag “0” in the off state, and shifts the printing device 1 to the normal mode (S25). Next, the CPU 21 switches the LED 6A to the LED light emission in the normal mode (S27). The CPU 21 returns the process to S11.

On the other hand, when the pressed key is not a desired key (S19: NO), the CPU 21 determines whether or not the position of the pressed key is within a predetermined range of the desired key (S29). In the determination of S129, a table (not shown) indicating the keys within a predetermined range is stored in the ROM 22 for each key, and the CPU 21 refers to the table and presses the key in the same area as the desired key. Determine if it is in. For example, a predetermined range is a range from a desired key to two keys. When the pressed key is not within the predetermined range of the desired key (S29: NO), the CPU 21 continues to emit light in the seventh light emission pattern of the LED 6A (S31). The CPU 21 returns the process to S17. When the pressed key is a key within a predetermined range of the desired key (S29: YES), the CPU 21 sets the LED 6A with a second light emitting pattern suggesting that the desired key is within a predetermined range from the pressed key. It emits light (S33). The CPU 21 returns the process to S17.

<Second embodiment>
The error identification process 2 will be described with reference to FIG. 7. When the key 5A of the printing device 1 is pressed and the power is turned on, the CPU 21 reads the program of the error identification process 1 shown in FIG. 7 from the ROM 22 and executes it. In the error identification process 2, the printing device 1 specifies whether or not the pressed key is in the same area as the desired key. The same area is the area of the pressed key when the area in which the keys 5A, 5B, 5C, 5D, 5E, and 5F are arranged is divided into the areas belonging to the keys 5A to 5C and the keys 5D to 5F. And the desired key area are the same. Further, in the following description, the same processing as the error specifying process 1 executed by the CPU 21 is designated by the same reference numerals and the description thereof will be omitted (S11 to S27).

If the pressed key is not the desired key (S19: NO), the CPU 21 advances the process to S129. The CPU 21 determines whether or not the pressed key is in the same area as the desired key (S129). In the determination of S129, the CPU 21 stores a table (not shown) indicating the keys in the same area for each key in the ROM 22, and the key pressed by referring to the table is in the same area as the desired key. Determine if it is in. When they are not in the same region (S129: NO), the CPU 21 continues the light emission of the LED 6A in the seventh light emission pattern, so that the light emission state of the LED 6A does not change (S31). The CPU 21 returns the process to S17. On the other hand, when they are in the same area (S129: YES), the CPU 21 causes the LED 6A to emit light in a fifth light emitting pattern suggesting that the pressed key and the desired key are in the same area (S133). The CPU 21 returns the process to S17.

<Third Embodiment>
The error identification process 3 will be described with reference to FIG. When the key 5A of the printing device 1 is pressed and the power is turned on, the CPU 21 reads the program of the error identification process 3 shown in FIG. 8 from the ROM 22 and executes it. In the error identification process 3, the printing apparatus 1 specifies a desired key by combining a plurality of conditions. The plurality of conditions determine whether the desired key is in the same area as the pressed key, is on the left side, is one key next to the desired key, and is two keys next to the desired key. In the following description, the same processes as those of the error identification processes 1 and 2 executed by the CPU 21 are designated by the same reference numerals and the description thereof will be omitted (S11 to S27).

When the pressed key is not the desired key (S19: NO), the CPU 21 determines whether or not the pressed key is in the same area as the desired key (S229). The same area is the same as the same area in the error identification process 2. If they are not in the same area (S229: NO), the CPU 21 advances the process to S231. Since the CPU 21 continues the light emission of the LED 6A in the seventh light emission pattern, the light emission state of the LED 6A does not change (S231). The CPU 21 returns the process to S17.

On the other hand, when it is determined that the pressed key is in the same area as the desired key (S229: YES), the CPU 21 advances the process to S233. Next, the CPU 21 determines whether the desired key is arranged on the left side with respect to the pressed key (S233). When it is determined that the desired key is on the left side with respect to the pressed key (S233: YES), the CPU 21 advances the process to S235.

Next, the CPU 21 determines whether or not the pressed key is the key next to the desired key (S235). When it is determined that the pressed key is the key immediately adjacent to the desired key (S235: YES), the CPU 21 is the third emission pattern, which is a emission pattern suggesting that the key is adjacent to the left one in the same area. The LED 6A is made to emit light by the combination of the sixth light emitting pattern A and the sixth light emitting pattern A (S237). The CPU 21 returns the process to S17. If the pressed key is not the key next to the desired key (S235: NO), the CPU 21 advances the process to S239. Next, the CPU 21 determines whether or not the desired key pressed is two adjacent to the key pressed (S239). When the desired key is two adjacent to the pressed key (S239: YES), the CPU 21 has a fourth emission pattern and a sixth emission pattern which are emission patterns suggesting that they are two adjacent to the left of the same area. The combination of A causes the LED 6A to emit light (S241). The CPU 21 returns the process to S17. When it is determined that the pressed key is not the key two adjacent to the desired key (S239: NO), the CPU 21 emits light in a fifth emission pattern suggesting that they are in the same region (S243). The CPU 21 returns the process to S17.

On the other hand, when it is determined that the pressed key is not on the left side of the desired key (S233: NO), the CPU 21 advances the process to S245. The CPU 21 determines whether or not the pressed key is the key next to the desired key (S245). When it is determined that the pressed key is one key next to the desired key (S245: YES), the CPU 21 is a light emitting pattern suggesting that the pressed key is one right next to the same area. The LED 6A is made to emit light by the combination of the third light emitting pattern and the sixth light emitting pattern B (S247). The CPU 21 returns the process to S17.

When it is determined that the pressed key is not the key next to the desired key (S245: NO), the CPU 21 advances the process to S249. The CPU 21 determines whether or not the pressed key is a key two adjacent to the desired key (S249). When the pressed key is a key two adjacent to the desired key (S249: YES), the CPU 21 has a fourth emission pattern and a sixth emission pattern which are emission patterns suggesting that they are two adjacent to the right of the same area. The LED 6A is made to emit light by the combination of the light emission pattern B (S251). The CPU 21 returns the process to S17. When the pressed key is not the key two adjacent to the desired key (S249: NO), the CPU 21 causes the LED 6A to emit light in the fifth light emitting pattern, which is a light emitting pattern suggesting that the desired key is in the same region (S253). ). The CPU 21 returns the process to S17.

<Action, effect>
In the printing device 1 of the first to third embodiments, since the six attributes in the printing device 1 correspond to each of the plurality of keys 5A, 5B, 5C, 5D, 5E, and 5F, the user can use the user. By observing the desired key corresponding to the six attributes and the first light emission pattern, the state of the printing device 1 can identify any of the six attributes. Further, since the printing device 1 has six attributes corresponding to each of the plurality of keys 5A, 5B, 5C, 5D, 5E, and 5F, it is possible to specify the attributes of the printing device 1 with at least one LED 6A. Therefore, the user can easily identify the state of the printing device 1. Further, in the error mode, the last digit of the ID number of the error that has occurred and the number of blinks after the interval of the predetermined time in the first light emission pattern match. Therefore, the user can identify the type of error that has occurred in the printing apparatus 1.

In the printing device 1 of the above embodiment, when the CPU 21 determines that an error has occurred in the printing device 1, the LED 6A emits light in the seventh light emitting pattern. The user can identify that the printing device 1 is in an error state when the LED 6A emits light in the seventh light emitting pattern. Further, since the LED 6A is provided in the printing device 1, the printing device 1 can display the state of the printing device 1 by using the LED 6A already provided. Therefore, it is not necessary to provide a new LED in the printing apparatus 1.

In the printing apparatus 1 of the first embodiment, when a key different from the desired key is pressed, the LED 6A emits light in the second light emitting pattern. Therefore, the user can identify that the pressed key is within a predetermined range from the desired key when the LED 6A emits light in the second emission pattern. Therefore, the user can easily identify the desired key.

Further, in the printing device 1 of the second embodiment, when the CPU 21 determines that the area corresponding to the desired key and the area of the pressed key are the same area, the LED 6A emits light in the fifth light emitting pattern. Therefore, when the LED 6A emits light in the fifth light emission pattern, the user can identify that the desired key is a key classified in the same region as the pressed key. Therefore, the user can easily identify the position of the desired key.

Further, in the printing device 1 of the third embodiment, when the LED 6A emits light in a combination of the third light emitting pattern and the sixth light emitting pattern A, the user can identify that the desired key is on the left side of the same area. When the LED 6A emits light in a combination of the fourth light emitting pattern and the sixth light emitting pattern A, the user can identify that the desired key is located on the left side of two in the same area. When the LED 6A emits light in the third light emission pattern and the sixth light emission pattern B, the user can identify that the desired key is on the right side of the same area. When the LED 6A emits light in the fourth light emitting pattern and the sixth light emitting pattern B, the user can identify that the desired key is located on the right side of two in the same area. When the LED 6A emits light in the fifth emission pattern, the user can identify that the pressed key and the desired key are in the same area. Therefore, the user can easily identify the position of the desired key.

<Modification example>
The present invention is not limited to the above embodiment, and various modifications can be made. In the printing apparatus 1 of the first embodiment, the predetermined range is defined as two or less keys from the desired key, but the predetermined range may be one or less, or three or more ranges may be the predetermined range. In the printing apparatus 1 of the second embodiment, the regions belonging to the keys 5A to 5C and the keys 5D to 5F are classified, but for example, the keys 5A to 5D and the keys 5E and 5F may be classified, and other regions may be classified. It may be classified according to the case of. In the printing apparatus 1 of the third embodiment, the desired key is specified from a plurality of conditions (same area, left side, one adjacent, and two adjacent). On the other hand, the plurality of conditions may be within a predetermined range, on the left side, one adjacent condition, and two adjacent conditions. Further, the printing apparatus 1 may specify a desired key by arbitrarily selecting three from a plurality of conditions. Further, the printing apparatus 1 may arbitrarily select two from a plurality of conditions to specify the desired key.

In the printing device 1, it may be determined only whether or not the pressed key is next to the desired key. In this case, the LED 6A emits light in the third light emission pattern. Therefore, when the LED 6A emits light in the third light emission pattern, the user can specify that the desired key is one next to the pressed key.

In the printing device 1, the CPU 21 may determine only whether a key two adjacent to the desired key is pressed. In this case, when the CPU 21 determines that the key two adjacent to the desired key is pressed, the LED 6A emits light in a fourth light emitting pattern different from the third light emitting pattern. When the printing device 1 emits light in the fourth light emitting pattern, the user can specify that there is a desired key two adjacent to the pressed key. Further, since the light emission pattern emits light in a fourth light emission pattern different from the third light emission pattern, the user can surely identify that the key two adjacent to the pressed key is the desired key.

In the printing device 1, when the CPU 21 determines that the desired key is on the right side of the predetermined area with respect to the key pressed, the LED 6A may emit light in the sixth light emitting pattern. The predetermined area means an area in which the key is arranged. Therefore, when the LED 6A emits light in the sixth light emitting pattern, the user can specify that the desired key is on the right side of the predetermined area with respect to the pressed key. The predetermined area is not limited to the case where the keys 5A to 5F are arranged in a row as in the above embodiment. For example, in the printing device 1, the keys of 2 rows and 8 columns are arranged vertically and horizontally, respectively. May be good. In this case, the light emitting pattern of the LED 6A suggesting which position of the desired key is up, down, left or right from the pressed key may be provided, or the light emitting pattern of the LED 6A suggesting that the desired key is in the oblique direction may be provided. ..

In the printing device 1, the attributes of the printing device 1 and the type of error are specified by the LED 6A, but may be specified by either the LED 6B or the LED 6C. Further, the attributes of the printing device 1 and the type of error are specified by the red light emission pattern of the LED 6A, but the error state is specified by the green, orange, and red light emission patterns of the LED 6A. You may. In this case, the attributes of the printing device 1 and the error state can be specified by illuminating the LED 6A with a lighting pattern of a color corresponding to the type of error.

In the above embodiment, the display of the error related to the printing device 1 has been described, but the present invention is not limited to this, and the technique disclosed in the above embodiment may be used for a device other than the printing device 1. When the user of the device using the method of the above embodiment tries to find the desired key, the desired key can be specified with a smaller number of times than pressing all the keys in order.

The printing apparatus 1 may arbitrarily combine the specific processing of the desired key disclosed in the above embodiment. When specifying a desired key under a plurality of conditions, it is particularly effective in a printing apparatus having a large number of keys. In the above embodiment, LED6A is used for displaying an error regarding the medium, but LED6B or LED6C may be used. The keys 5A, 5B, 5C, 5D, 5E, and 5F correspond to each of the six attributes, but they may correspond differently. Further, the keys 5A, 5B, 5C, 5D, 5E, and 5F may correspond to the type of error, respectively. The number of the plurality of keys was 6, but it may be increased or decreased depending on the mode of the device. Further, in the above embodiment, the state of the printing apparatus 1 is divided into six attributes, but it may be divided into more or less attributes. The state 1 of the printing device is not necessarily limited to the attribute of the error state. For example, it may be used to indicate the remaining battery level. In the error mode, the LED 6A emits light in a plurality of light emission patterns (see FIG. 4), but may emit light in other light emission patterns as long as it is easy for the user to see. The LED 6A emits light in three colors of green, orange, and red, but a combination of other colors may be used. The LED 6A is an LED including a light emitting element of two colors, but the type of the light emitting element may be three or more colors or a single color. Although the number of LEDs was three, the number of LEDs may be increased or decreased depending on the mode of the device. Although an LED was used for the error display, other light emitting elements may be used. Although the error identification processes 1, 2 and 3 are performed by the CPU 21, they may be realized by using other elements such as FPGA and ASIC.

<Others>
The keys 5A, 5B, 5C, 5D, and 5E are examples of the "plurality of keys" of the present invention. The CPU 21 that performs the process of S19 is an example of the "first determination means" of the present invention. LED6A is an example of the "display unit" of the present invention. The CPU 21 is an example of the "light emission control means" of the present invention. The CPU 21 that performs the process of S29 is an example of the "second determination means" of the present invention. The CPU 21 that performs the processing of S235 is an example of the "third determination means" of the present invention. The CPU 21 that performs the processes of S239 and S249 is an example of the "fourth determination means" of the present invention. The CPU 21 that performs the processes of S129 and S229 is an example of the "fifth determination means" of the present invention. The CPU 21 that performs a process of determining that the desired key is on the right side of the predetermined area is an example of the "sixth determination means" of the present invention. The right side is an example of the "one side" of the present invention. The CPU 21 that performs the process of S15 is an example of the "seventh determination means" of the present invention. The error state of the printing apparatus 1 is an example of the "predetermined state" of the present invention.

1 Printing device 5A, 5B, 5C, 5D, 5E, 6E Key 6A, 6B, 6C LED
21 CPU

Claims (10)

Multiple keys corresponding to each of the multiple states in the device,
Among the plurality of keys, a first determination means for determining that a desired key corresponding to a state in which the plurality of states have occurred or a key different from the desired key has been pressed.
A display capable of emitting light based on the pressed key when the first determination means determines that any one of the plurality of keys is pressed, which is less than the plurality of states and is provided with at least one. Department and
When the first determination means determines that the desired key has been pressed, the display unit emits light in the first emission pattern, and the first determination means determines that a key different from the desired key has been pressed. A state display device for the device, comprising: a light emission control means for causing the display unit to emit light in a second light emission pattern that gives a suggestion for finding the desired key. The status display device of the device is
When the first determination means determines that a key different from the desired key is pressed, a second determination means for determining whether or not a key within a predetermined range from the desired key is pressed is further provided.
The light emission control means
The apparatus according to claim 1, wherein the display unit emits light in the second light emission pattern only when the second determination means determines that a key within the predetermined range is pressed from the desired key. Status display device. The status display device of the device is
When the first determination means determines that a key different from the desired key has been pressed, a third determination means for determining whether or not a key next to the desired key has been pressed is further provided.
The light emission control means
The state display of the apparatus according to claim 2, wherein when the third determination means determines that the key adjacent to the desired key is pressed, the display unit emits light in a third emission pattern. apparatus. The status display device of the device is
When the first determination means determines that a key different from the desired key has been pressed, a fourth determination means for determining whether or not a key two adjacent to the desired key has been pressed is further provided.
The light emission control means
When the fourth determination means determines that the two keys adjacent to the desired key are pressed, the claim is characterized in that the display unit emits light in a fourth emission pattern different from the third emission pattern. The state display device of the device according to item 3. The plurality of keys can be classified into a plurality of areas corresponding to the positions of the plurality of keys.
The status display device of the device is
When the first determination means determines that a key different from the desired key has been pressed, whether or not a key classified into the same region as the region corresponding to the desired key among the plurality of regions has been pressed. With a fifth means of judgment
The light emission control means
The claim is characterized in that, when the fifth determination means determines that a key classified in the same region as the region corresponding to the desired key is pressed, the display unit emits light in the fifth emission pattern. The state display device of the device according to any one of 1 to 4. The plurality of keys are arranged in a predetermined area, and the plurality of keys are arranged in a predetermined area.
The status display device of the device is
When the first determination means determines that a key different from the desired key has been pressed, a sixth determination is made as to whether or not the desired key is on one side of the predetermined area with respect to the pressed key. With more means of judgment
The light emission control means
When the sixth determination means determines that the desired key is on one side of the predetermined region with respect to the pressed key, the display unit emits light in the sixth emission pattern. The state display device of the device according to any one of claims 1 to 5. The state display device of the device according to any one of claims 1 to 6, wherein the display unit is an LED provided in the device. The state display device of the device according to claim 7, wherein the LED emits light in a plurality of colors. The status display device of the device is
The device further includes a seventh determination means for determining that any of the plurality of states is a predetermined state in which any of the states has occurred.
The light emission control means
The state display device of the device according to any one of claims 1 to 8, wherein when the seventh determination means determines that the predetermined state is met, the display unit emits light in a seventh light emission pattern. The state display device of the device according to any one of claims 1 to 9, wherein the state display device of the device displays an error of the printing device.

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