JP5957734B2 - control panel - Google Patents

Description

  The present invention relates to an operation panel.

  Japanese Patent Application Laid-Open No. 2004-133867 allows both the host device and the device device to shift from the normal mode to the power saving mode or return from the power saving mode to the normal mode without sacrificing user convenience, and consumes the device device. Techniques aimed at reducing power are disclosed. In the operation device of Patent Document 1, a main controller and an operation panel are connected for communication by a USB interface including a power supply line. The operating device includes a power supply monitoring unit that monitors the power supply voltage of the power supply line, and an OR circuit, a switching circuit, and a switching circuit that switch between the normal mode and the power saving mode based on a monitoring result by the power supply monitoring unit. The OR circuit, the switching circuit, and the switching circuit stop supplying the power supply voltage to the control unit, the USB controller, and the operation display unit when switching from the normal mode to the power saving mode.

JP 2011-182020 A

  An operation panel for inputting / outputting information between a user and a host device includes a display unit such as an LCD and an input unit such as a touch panel. It is desirable that the operation panel further includes a sound source that transmits information via hearing. One of the sound sources is a buzzer, and the piezoelectric buzzer is suitable as a sound source for an operation panel because it consumes less power and does not generate electromagnetic noise or sparks. If the controller (IC) has a voice synthesis function, it can be used as a speaker. On the other hand, in order to obtain a sufficient sound pressure as a warning sound or the like, a voltage of about 12V is usually required.

  In an operation panel connected to a host device including a main controller via a USB (Universal Serial Bus) interface, the voltage of power (bus power) supplied from the USB interface is limited to 5V. Therefore, it is difficult to use a piezoelectric buzzer as a sound source in a bus-powered (bus power drive) type operation panel to which power is supplied through a USB interface. It is possible to compensate for the decrease in sound pressure due to limited bus power voltage (low voltage) with a booster coil, but it may become a source of noise and reduce the merit of the piezoelectric buzzer. . Moreover, it cannot be said that it is economical. In order to drive the sound source, it is possible to prepare a power source separate from the USB interface, but a bus power driven operation panel cannot be realized.

  One aspect of the present invention is a communication interface for exchanging data between a display unit with a backlight, an input unit that accepts user input, a sound source that outputs sound, and a host device. Including a communication interface, a DC-DC converter unit for stepping up the voltage of the power supply line to supply power to the backlight, and controlling the output voltage of the DC-DC converter unit based on the brightness setting value, A control unit including a brightness adjusting function for adjusting the output voltage, and a voltage dividing circuit for dividing the output voltage of the DC-DC converter unit and supplying the divided voltage to the sound source. The control unit sets the resistance value of the voltage dividing circuit to the brightness setting. It is an operation panel including a volume adjustment function that is controlled in accordance with the value and the volume setting value.

  An operation panel having a display unit with a backlight includes a DC-DC converter unit with a step-up (boost) function as a constant current power source for a backlight using a white LED or the like. This DC-DC converter unit steps up and outputs an input voltage of 5V in a range of about 20 to 35V. However, in the DC-DC converter unit, the output voltage is controlled based on the luminance setting value by the control unit in order to adjust the luminance of the display unit, and the output voltage is not necessarily constant.

  In the operation panel of the present invention, a voltage dividing circuit that divides the output voltage of the DC-DC converter unit and supplies it to the sound source is provided, and the resistance value of the voltage dividing circuit is set to the brightness setting value in the control unit including the brightness adjusting function. In addition, a volume control function is provided to control according to the volume setting value. By dividing the output voltage of the DC-DC converter unit with a step-up function and supplying it to the sound source, the sound source can be driven with a voltage higher than the voltage of the power line of the communication interface, that is, the voltage of the bus power. Generation of noise can be suppressed. Further, the volume control function sets the resistance value of the voltage dividing circuit based on not only the volume setting value but also the luminance setting value. Therefore, even when the output voltage of the DC-DC converter unit changes for brightness adjustment, the sound source can be driven with a voltage suitable for the volume setting value.

  One form of the voltage dividing circuit includes a first switch that selects at least one of the plurality of first resistors and sets a resistance value on the high voltage side of the output end, and at least one of the plurality of second resistors. And a second switch for selecting and setting a resistance value on the ground side of the output terminal. The volume control function is configured to select at least one of a plurality of predetermined first resistors and at least one of a plurality of second resistors for the luminance setting value and the volume setting value, and the first switch and It is desirable to include a function for controlling the second switch. The relationship between the luminance setting value and the sound volume setting value and the first resistor and the second resistor selected for the luminance setting value and the sound volume setting value can be prepared in advance using a lookup table or the like and stored in a memory included in the control unit.

  In this operation panel, the communication interface is an interface conforming to a predetermined standard such as USB, and even when the voltage of the power (bus power) supplied thereby is limited, it is equal to or higher than the bus power voltage. Can be supplied to the sound source. For this reason, a sound source that requires a relatively high voltage such as a piezoelectric buzzer can be employed. Therefore, it is possible to provide a device in which an operation panel including a sound source that requires a voltage higher than the bus power voltage and the host device are connected only by a communication interface.

Another aspect is a method for controlling the operation panel. The operation panel is a communication interface that exchanges data among a display unit with a backlight, an input unit that accepts user input, a sound source that outputs sound, and a host device, and includes a power supply line And a DC-DC converter unit that steps up the voltage of the power supply line and supplies power to the backlight, and a voltage dividing circuit that divides the output voltage of the DC-DC converter unit and supplies it to the sound source. The control method includes the following steps.
1. Control the output voltage of the DC-DC converter unit based on the brightness setting value to adjust the brightness of the backlight.
2. Control the resistance value of the voltage divider circuit according to the brightness setting value and volume setting value.

  The voltage dividing circuit selects at least one of a plurality of first resistors and selects at least one of a first switch that sets a resistance value on the high voltage side of the output end and a plurality of second resistors. And a second switch for setting a resistance value on the ground side of the output terminal. Controlling the resistance value of the voltage dividing circuit selects at least one of a plurality of first resistors and at least one of a plurality of second resistors set in advance for the luminance setting value and the volume setting value. It is desirable to include controlling the first switch and the second switch as described above.

The block diagram of the apparatus containing the operation panel connected by USB (Universal Serial Bus) interface. 2A is a look-up table showing the switch state of the voltage dividing circuit, FIG. 2B is an ideal resistance ratio (voltage ratio) of the voltage dividing circuit, and FIG. 2C is an actual state of the voltage dividing circuit. Resistance ratio. The flowchart which shows the brightness | luminance control of the backlight of an operation panel, and the volume control of a buzzer.

  FIG. 1 shows an exemplary configuration of an apparatus including an operation panel. This apparatus is an MFP (multifunction printer) 1 and includes a host apparatus 10 and an operation panel 20. The host device 10 includes an MFP mechanical unit 11 including various types of input / output mechanisms such as a printer, a scanner, and a fax machine, a main controller 12 that controls the MFP mechanical unit 11, and temporary storage of data input and output in the MFP mechanical unit 11. It includes a memory 13 that also serves as an area, a LAN interface 14 that connects the host device 10 and external devices, and a USB connector 15 that connects the host device 10 and the operation panel 20. The host device 10 communicates with an external device via a computer network 9 connected to the LAN interface 14, and outputs data input by the MFP mechanism unit 11 to the external device or receives data received from the external device. Output using the MFP mechanism unit 11. The host device 10 communicates with an operation panel 20 serving as a user interface of the host device 10 via a USB cable 5 connected to a USB connector (USB interface) 15. The main controller 12 includes a USB control function 12a, receives an instruction (information, data) from a user using the operation panel 20, and provides information (data) of the host device 10 to the user using the operation panel 20.

  The operation panel 20 includes a control unit (CPU) 30, a flash memory 21 that is downloaded to the CPU 30 and stores a program (program product) and setting values for implementing a predetermined function in the CPU 30, display data, and the like SDRAM 22 serving as a storage area, a crystal resonator 23 serving as a clock source for the CPU 30, and a USB connector (USB interface) 25 to which a USB cable 5 for communication with the host device 10 is connected. The operation panel 20 is further connected to the power line 25b of the USB connector 25, and a voltage (bus power) of a predetermined voltage (5V in this example) supplied from the USB connector 25 is a voltage suitable for the voltage of the CPU power source. DC-DC converter (first power supply unit) 26 with a step-down function that supplies a step-down function to the voltage and a DC-DC converter unit (first power supply unit) with a step-up function that supplies a boosted bus power to a voltage suitable for the backlight. 2 power supply units) 27. The USB cable 5 connected to the USB connector 25 includes a communication line 5a for exchanging data and a power line 5b for supplying power (bus power) of a predetermined voltage.

  The operation panel 20 further includes a display unit 63 with backlight, a touch panel (input unit) 65 disposed on the display unit 63, and a plurality of keys (operation buttons) for operating the MFP mechanical unit 11 of the host device 10. ) On which the switch board 29 is disposed. The display unit 63 includes a backlight 61 including a plurality of white LEDs and an LCD 62. The power of the backlight 61 is supplied from the second power supply unit 27 that is a constant current power supply. The second power supply unit 27 boosts and outputs the voltage (5 V) of the USB power supply line (bus power) 25b. The output voltage BLH of the second power supply unit 27 is controlled by the luminance adjustment signal Sy supplied from the CPU 30, and varies in the range of 12V to 24V in this example. The range of the output voltage of the second power supply unit 27 is not limited to this.

  The operation panel 20 further includes a piezoelectric buzzer 67 serving as a sound source and a buzzer driving circuit 50 that supplies electric power to the piezoelectric buzzer 67. The buzzer driving circuit 50 divides the output voltage BLH of the second power supply unit 27 and supplies (applies) to the piezoelectric buzzer 67, and the piezoelectric buzzer 67 by turning on and off the current flowing through the voltage dividing circuit 55. And a drive switch 56 that outputs sound by turning on and off. The voltage dividing circuit 55 includes a first resistance unit (maximum buzzer applied voltage adjusting unit) 51 that sets a resistance value on the high voltage side of the output terminal 57 to which the high voltage side of the piezoelectric buzzer 67 is connected, and a ground side of the output terminal 57. And a second resistance unit (volume adjusting unit) 52 for setting the resistance value.

  The first resistance unit 51 selects a plurality of first resistance elements 51 a to 51 c having different resistance values and at least one of the first resistance elements 51 a to 51 c to select a resistance value on the high voltage side of the output terminal 57. And switches 53a to 53c for setting. In this example, the resistance values of the first resistance elements 51a to 51c are 5.6 kΩ, 3.74 kΩ, and 1.8 kΩ, respectively, and transistor switches are employed as the switches 53a to 53c. The first resistance element 51a and the switch 53a are connected in series. When the switch 53a is turned on, the first resistance element 51a is selected as the high-voltage side resistance element, and the other selected first resistance elements It is connected in parallel with 51b or 51c. The same applies to the first resistance element 51b and the switch 53b, and the first resistance element 51c and the switch 53c. Therefore, the selected first resistance elements 51a to 51c are connected in parallel to the high voltage side of the output terminal 57 of the voltage dividing circuit 55, and the combined resistance value of the first resistance elements 51a to 51c is output. This is the resistance value on the high voltage side of the end 57.

  The configuration of the second resistance unit 52 is also the same. In other words, the second resistance unit 52 selects a plurality of second resistance elements 52a to 52c having different resistance values and at least one of the second resistance elements 52a to 52c so that the output terminal 57 is connected to the ground side. And switches 54a to 54c for setting resistance values. In this example, the resistance values of the second resistance elements 52a to 52c are 5.6 kΩ, 3.74 kΩ, and 1.8 kΩ, respectively, and transistor switches are employed as the switches 54 a to 54 c. The second resistance element 52a and the switch 54a are connected in series. When the switch 54a is turned on, the second resistance element 52a is selected as the resistance element on the ground side, and the other selected second resistance element 52b or 52c is connected in parallel. The same applies to the second resistance element 52b and the switch 54b, and the second resistance element 52c and the switch 54c. Accordingly, the selected second resistance elements 52a to 52c are connected in parallel to the ground side of the output terminal 57 of the voltage dividing circuit 55, and the combined resistance value of the second resistance elements 52a to 52c is output. This is the resistance value on the ground side of the end 57.

  The voltage dividing circuit 55 further includes a switching circuit 58 that controls the switches 53a to 53c of the first resistance unit 51 and the switches 54a to 54c of the second resistance unit 52 by a control signal Sb1 supplied from the CPU 30. The drive switch (transistor switch) 56 is connected in series to the ground side of the voltage dividing circuit 55, and turns on and off the current flowing through the voltage dividing circuit 55 by the control signal Sb2 supplied from the CPU 30.

  The CPU 30 that controls the operation panel 20 is an LSI or an ASIC including a built-in RAM, a general-purpose input / output interface (GPIO), a pulse width modulation signal output interface (PWM), and various functions are realized by loading a program. The The CPU 30 includes a reset function 31. The first power supply unit 26 includes a power-on reset function, and outputs a reset signal Sr when the bus power 25b changes from 0V to a specified value (for example, 5V). The CPU 30 is reset by a reset signal Sr. Therefore, the main controller 12 of the host device 10 can reset the operation panel 20 from the power saving mode or the off state to the on state by turning on / off the power supply to the USB connector 15 connected to the operation panel 20.

  The CPU 30 includes a host communication function 32. The host communication function 32 includes a USB control function (USB controller) 32 a and exchanges various data with the host apparatus 10 via the USB cable 5 connected to the USB connector 25. The exchanged data may be temporarily stored in the SDRAM 22 via a memory control function (not shown).

  The CPU 30 further includes a switch control function 39. The switch control function 39 controls the switch board 29, detects a key or button operated on the switch board 29, and generates data based thereon. The generated data is displayed on the display unit 63 or supplied to the host device 10 via the host communication function 32.

  The CPU 30 further controls the touch panel 65 and receives a data input via the touch panel 65. The LCD control function 37 supplies the image signal Si to the LCD 62 of the display unit 63 and outputs information as an image. And a backlight control function (brightness adjustment function) 36 for supplying a brightness control signal Sy to the second power supply unit (DC-DC converter) 27 to control the brightness of the backlight 61 of the display unit 63. The backlight control function 36 supplies a luminance control signal (PWM signal) Sy having a duty based on the luminance setting value Fy to the control input CTRL of the second power supply unit 27. The second power supply unit 27 includes a function of boosting the voltage at the output terminal (VOUT) so that the voltage appearing at the FB terminal matches the internal reference voltage, and controls the pulse width of the signal input to the control input CTRL. Thus, the internal reference voltage can be controlled.

  Therefore, the second power supply unit 27 outputs a multi-stage voltage BLH based on the luminance control signal Sy supplied from the backlight control function 36. The second power supply unit 27 of this example steps up the input voltage of 5V input to the input terminal VIN by the luminance control signal Sy, and performs seven steps (24, 22, 20, 18, 16, 14, 12V). ) Is output from the output terminal (VOUT). For this reason, the backlight control function 36 can set seven levels of brightness (7, 6, 5, 4, 3, 2, 1) by the brightness setting value Fy. The brightness setting value Fy can be set from the touch panel 65 or the switch substrate 29.

  The CPU 30 further includes a buzzer control function 35 that controls the piezoelectric buzzer 67 to output sound information such as a beep sound. The buzzer control function 35 outputs the resistance value of the voltage dividing circuit 55 of the buzzer control unit (drive circuit) 50 according to the luminance setting value Fy and the volume setting value Fa, and the piezoelectric buzzer 67. And a pattern control function 35b for controlling the sound pattern. The volume adjustment function 35a is based on the look-up table LT, and at least one of the predetermined first resistance elements 51a to 51c and the second resistance elements 52a to 52c with respect to the luminance setting value Fy and the volume setting value Fa. Is supplied to the switching circuit 58 of the voltage dividing circuit 55. The pattern control function 35b refers to the acoustic pattern setting table AT and outputs a control signal (PWM signal) Sb2 of a pattern corresponding to another function of the CPU 30 or information (data) requested to output sound from the host device 10. This is supplied to the drive switch 56.

  FIG. 2A shows an example of the lookup table LT. This look-up table LT has a first resistance of the voltage dividing circuit 55 based on seven levels of luminance setting values (backlight luminance) Fy and three levels of volume setting values (buzzer volume, high, medium, low) Fa. ON / OFF of the switches 53a to 53c (A to C) of the unit (maximum buzzer applied voltage adjustment unit) 51, and ON / OFF of the switches 54a to 54c (A to C) of the second resistance unit (volume adjustment unit) 52 Indicates that it is uniquely set. Therefore, the sound volume adjustment function 35a outputs a sound having a desired sound volume even when the brightness setting of the backlight 61 is changed and the output voltage BLH of the second power supply unit 27 is changed by referring to the look-up table LT. Thus, the voltage applied to the piezoelectric buzzer 67 can be adjusted by controlling the voltage dividing circuit 55.

  FIG. 2B shows a voltage dividing circuit corresponding to the three-stage volume setting value Fa when the output voltage BLH of the second power supply unit 27 is changed in the range of 12 to 24 V by the seven-stage luminance setting value Fy. The resistance value on the high voltage side (the resistance value of the first resistance unit 51) for obtaining the voltage (High (10V), Middle (8V), Low (6V)) at the output terminal 57 of 55, and the resistance value on the ground side The theoretical ratio with (the resistance value of the second resistance unit 52) is shown. The ratio of the resistance values is equal to the voltage ratio to be divided.

  FIG. 2C shows the luminance setting values Fy and the respective values when the switches 53a to 53c and the switches 54a to 54c of the voltage dividing circuit 55 are controlled according to the setting of the lookup table LT shown in FIG. The resistance value on the high voltage side (resistance value of the first resistance unit 51) of the output terminal 57 of the voltage dividing circuit 55 and the resistance value on the ground side (resistance value of the second resistance unit 52) at the volume setting value Fa. The ratio is shown. Although a slight difference is recognized with respect to the ideal resistance value ratio shown in FIG. 2B, the difference is sufficiently small. Therefore, it can be seen that sufficient accuracy can be obtained for adjusting the volume of the sound signal.

  FIG. 3 is a flowchart showing an outline of the brightness control of the backlight 61 of the operation panel 20 and the volume control of the buzzer 67. When the CPU 30 is reset in step 81, in step 82, the backlight control function 36 determines the brightness based on the initial value of the brightness setting value Fy or the previously set brightness setting value Fy stored in the flash memory 21. The luminance of the backlight 61 is adjusted by supplying the control signal Sy to the second power supply unit 27 and controlling the output voltage BLH. Further, in step 83, the volume adjustment function 35a determines the lookup table LT based on the brightness setting value Fy and the initial value of the volume setting value Fa, or the previously set volume setting value Fa stored in the flash memory 21. , The signal Sb1 for controlling the switches 53a to 53c and the switches 54a to 54c of the voltage dividing circuit 55 is output, and the resistance value of the voltage dividing circuit 55 is set.

  When the luminance setting value Fy is changed in step 84 and the luminance of the backlight 61 is changed, in step 85, the backlight control function 36 sends the luminance control signal Sy to the second power supply based on the new luminance setting value Fy. The luminance of the backlight 61 is adjusted by supplying the unit 27 and controlling the output voltage BLH. Further, in step 86, the volume adjustment function 35a refers to the lookup table LT based on the new brightness setting value Fy and the previous volume setting value Fa, and switches the switches 53a to 53c and the switches 54a to 54c of the voltage dividing circuit 55. The control signal Sb1 is output, and the resistance value of the voltage dividing circuit 55 is set.

  When the volume setting value Fa changes in step 87 and the volume is changed, in step 88, the volume adjustment function 35a refers to the lookup table LT based on the previous luminance setting value Fy and the new volume setting value Fa. Thus, the signal Sb1 for controlling the switches 53a to 53c and the switches 54a to 54c of the voltage dividing circuit 55 is output, and the resistance value of the voltage dividing circuit 55 is set.

  When sound output is requested in step 89, in step 90, the pattern control function 35b refers to the acoustic pattern setting table AT, supplies a predetermined pattern signal Sb2 to the drive switch 56, and determines a predetermined volume and pattern. To drive the piezoelectric buzzer 67 and output sound.

  As described above, the operation panel 20 having the display unit 60 with a backlight has a DC-DC converter unit with a boosting function (second power supply unit) as a constant current power supply for the backlight 61 using a white LED or the like. ) 27 step-up output voltage BLH is used as power for driving the buzzer 67. Thus, even when the bus power voltage is as low as about 5V and the piezoelectric buzzer 67 cannot be driven sufficiently with the bus power, the buzzer 67 can be driven with a voltage of 10V or more. Therefore, it is possible to provide the operation panel 20 that is connected to the host apparatus 10 only by the USB interface (USB cable 5) and can drive the buzzer 67 with a voltage higher than the bus power voltage supplied by the USB interface. . For this reason, the operation panel 20 is connected to the host apparatus 10 only through the USB interface (USB cable 5), and has an operation with a piezoelectric buzzer 67 as a sound source that consumes very little power and does not generate electromagnetic noise or sparks. A panel 20 can be provided.

  Further, the operation panel 20 is provided with a voltage dividing circuit 55 that divides the output voltage BLH of the DC-DC converter unit 27 and supplies the divided voltage to the sound source, and a volume control function is provided to the CPU (control unit) 30 that adjusts the brightness of the backlight 61. 35a is mounted, and the resistance value of the voltage dividing circuit 55 is controlled in accordance with the luminance setting value Fy and the sound volume setting value Fa. Therefore, even when the output voltage BLH of the DC-DC converter unit 27 changes for adjusting the luminance of the backlight 61, the resistance value of the voltage dividing circuit 55 is appropriately controlled, and the buzzer is set at a voltage that matches the sound volume setting value Fa. 67 can be driven. Further, by using the voltage dividing circuit 55 instead of the step-down circuit in order to adjust the output voltage BLH of the DC-DC converter unit 27 for the buzzer voltage, generation of electromagnetic noise can be suppressed.

  In the above description, the operation panel 20 connected by USB is described as an example of a communication interface in which the voltage of the bus power is limited. However, the communication interface is not limited to USB but is an interface based on other standards such as IEEE1394. There may be. The operation panel according to the present invention can supply a voltage equal to or higher than the bus power voltage to the sound source even when the voltage of the power (bus power) supplied via the communication interface is limited. For this reason, it is possible to employ a sound source that requires a relatively high voltage such as a piezoelectric buzzer on an operation panel connected to the host device only by a communication interface.

  In the above description, the MFP is described as an example of the apparatus 1 including the operation panel 20, but an apparatus to which the operation panel 20 can be applied is not limited to the MFP. The operation panel is used not only in office equipment such as an MFP but also in household equipment such as a refrigerator and industrial equipment such as a robot, and these apparatuses are also included in the present invention.

1 MFP
10 Host device 20 Operation panel

Claims (5)

A display unit with backlight,
An input unit that accepts user input;
A sound source that outputs sound,
A communication interface for exchanging data with a host device, including a power supply line;
A DC-DC converter unit for stepping up the voltage of the power supply line and supplying power to the backlight;
A control unit including a brightness adjustment function for adjusting the brightness of the backlight by controlling the output voltage of the DC-DC converter unit based on a brightness setting value;
A voltage dividing circuit for dividing an output voltage of the DC-DC converter unit and supplying the divided voltage to the sound source;
The operation unit includes a volume adjustment function for controlling a resistance value of the voltage dividing circuit according to the luminance setting value and the volume setting value. The voltage dividing circuit according to claim 1, wherein the voltage dividing circuit selects at least one of a plurality of first resistors and sets a resistance value on the high voltage side of the output end;
A second switch that selects at least one of a plurality of second resistors and sets a resistance value on the ground side of the output end;
The volume adjustment function is configured to select at least one of the plurality of first resistors and at least one of the plurality of second resistors that are set in advance for the luminance setting value and the volume setting value An operation panel including a function of controlling the first switch and the second switch.   3. The operation panel according to claim 1, wherein the sound source includes a piezoelectric buzzer.   4. The operation panel according to claim 1, wherein the communication interface is a USB. An operation panel according to any one of claims 1 to 4,
A device having the operation panel and a host device connected only by the communication interface.

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