JP2007327768A - Spontaneous emission display panel and apparatus, and battery-powered equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problems that a system has had to be restarted only for learning a battery residual capacity and that a prescribe time period has had to be required from the actuation of the system to the verification of the battery residual capacity. <P>SOLUTION: In the spontaneous emission display panel, a first emission region (a) connected to a battery power supply via a main power supply switch for receiving the supply of driving power from the battery power supply in the case that the main power supply switch is closed and a second emission region (b) which is directly supplied with driving power from the battery power supply at all times and of which emission mode changes with changes in the battery residual capacity are arranged in the same panel. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

The invention described in this specification relates to a technique that allows a battery remaining amount to be always confirmed.
The invention proposed by the inventors has aspects as a self-luminous display panel, a self-luminous display device, and a battery-driven device.

Currently, a wide variety of battery-powered devices are used.
These battery-powered devices are equipped with a remaining amount display function. The reason is to avoid in advance the situation where the battery-powered device suddenly becomes unusable.

For this reason, there are many technologies related to the battery remaining amount display function.
For example, Patent Document 1 proposes a technique for expressing the remaining battery level through the character's movement speed, body shape, gesture, and the like.
Japanese Patent Laid-Open No. 2003-9404

However, in the case of existing technologies including Patent Document 1, a mechanism for displaying the remaining battery level on a screen through a resident program is employed.
Therefore, as long as the system is not activated, the user cannot immediately check the remaining battery level.

In addition, when the user wants to know the remaining battery level when the system is not activated, the user needs to restart the system by closing the main power switch. However, the user had to wait until the battery level could be displayed.
As described above, in the existing technology, there is a problem that the remaining battery level cannot be confirmed immediately even if it is desired to check the remaining battery level.

Therefore, the inventors propose a mechanism that can always check the remaining battery level without closing the main power switch.
Specifically, on the same panel, (a) a first light emitting region that is connected to a battery power source via a main power switch and receives driving power from the battery power source when the main power switch is closed; b) A self-luminous display panel is proposed that is equipped with a second light-emitting area in which the driving power is always supplied directly from the battery power source and the light-emission mode changes as the remaining battery level changes.

  If the self-luminous display panel proposed by the inventors is used, the remaining battery level can be confirmed through the second light emitting region regardless of the operation state of the main power switch.

Hereinafter, the battery remaining amount display technique according to the invention will be described.
In addition, the well-known or well-known technique of the said technical field is applied to the part which is not specifically illustrated or described in this specification.
Moreover, the form example demonstrated below is one form example of invention, Comprising: It is not limited to these.

(A) Form Example (A-1) External Configuration FIG. 1 shows an external configuration example of the display device 1 that operates by receiving drive power from a battery power supply. FIG. 1 shows an external configuration example of a display device 1 in which an information display unit 5 and a battery remaining amount display unit 7 are arranged on one surface of a housing 3.

The information display unit 5 is a display area that receives supply of driving power from the battery power supply via the main power switch. That is, the information display unit 5 is a display area in which driving power is supplied from the battery power source only when the main power switch is closed.
The information display unit 5 is a display area that can display an arbitrary image or video, and displays various types of user interface information.

  The battery remaining amount display unit 7 is a display area in which driving power is always supplied directly from the battery power source. That is, it is a dedicated display area that can always display information on the remaining battery level not only while the main power switch is closed but also when the main power switch is open.

  In the case of this example, the battery remaining amount display unit 7 is composed of three indicators as shown in FIG. Here, the fact that all three indicators are lit means full charge. Further, the indicator is controlled to be turned off one by one as the remaining battery level decreases, and all three indicators are turned off when the remaining battery level is exhausted.

(A-2) Panel Configuration and Power Supply Path FIG. 3 shows a planar configuration and power supply path of the display panel 11. As shown in FIG. 3, the information display unit 5 and the battery remaining amount display unit 7 are formed on the same display panel 11. In the case of this example, both the information display unit 5 and the battery remaining amount display unit 7 are configured by display pixels using organic electroluminescence elements (hereinafter referred to as “organic EL elements”) as light emitting elements.

  As shown in FIG. 3, the driving power of the battery power source 13 is supplied to the information display unit 5 and each part of the system via the main power switch 15. That is, each part of the system mounted on the display device 1 can be used only when the main power switch 15 is closed. In addition, when each part of the system becomes usable, the information display unit 5 can display images and videos.

  On the other hand, the driving power of the battery power supply 13 is directly supplied to the battery remaining amount display unit 7. Thus, the supply of drive power to the battery remaining amount display unit 7 is irrelevant to the operation of the main power switch 15.

(A-3) Circuit Configuration Related to Battery Remaining Display FIG. 4 shows a circuit configuration related to battery remaining display by the battery remaining amount display unit 7. The output voltage of the battery power supply 13 is given to the voltage converter 21 and the display mode controller 23 (lighting controller 231).

The voltage converter 21 is a circuit device that converts the output voltage V0 of the battery power supply 13 into a drive voltage V1 necessary for light emission of the organic EL element 71.
At present, a lithium ion secondary battery is generally used for the battery power source 13 in many cases. This type of secondary battery employs a single battery cell unit, a configuration in which two to three battery cells are connected in series, or a configuration in which these are connected in parallel.

  Therefore, the output voltage V0 of the battery power supply 13 is almost about 3 to 12V. On the other hand, it is known that the drive voltage V1 of the organic EL element is about several V to 10V. The voltage conversion unit 21 is installed for the purpose of eliminating this voltage difference.

  As shown in FIG. 5, the output voltage V0 of the battery power source 13 has a characteristic that changes according to the remaining battery level. The voltage changing unit 21 is used for the purpose of obtaining a constant driving voltage V1 from the output voltage V0 that varies in this way.

The voltage converter 21 uses a boost type circuit when the output voltage V0 of the battery power supply 13 is lower than the drive voltage V1 of the organic EL element, and the output voltage V0 of the battery power supply 13 is the drive voltage of the organic EL element. When it is higher than V1, a step-down type circuit is used.
The voltage converter 21 may be a switching regulator circuit or a series regulator circuit.

  The output voltage V0 of the voltage converter 21 is supplied to the display mode controller 23 as the drive voltage V1 of the organic EL element 71. The display mode control unit 23 is a circuit device that controls three indicators constituting the remaining battery level display unit 7 in accordance with the remaining battery level.

  That is, the remaining battery level is displayed in four stages. For this display control, the display mode control unit 23 includes three lighting control units 231.

  Each lighting control unit 231 corresponds to the three indicators constituting the battery remaining amount display unit 7 and selectively supplies the drive power source V1 or the ground potential (GND) to the organic EL element 71 located in each indicator.

In other words, the organic EL element 71 is switched on and off.
FIG. 6 shows an internal configuration example of the lighting control unit 231. The lighting control unit 231 includes an operational amplifier that operates as the comparator 31 and a voltage dividing circuit that operates as the reference voltage generator 33.

  The reference voltage generator 33 is a circuit that divides the drive voltage V1 by resistors R1 and R2 and generates a reference voltage specific to each lighting control unit 231. The drive voltage V1 is given as a constant voltage regardless of the fluctuation of the output voltage V0 of the battery power supply 13, so that the reference voltage generated by the reference voltage generator 33 is always a constant value. By setting an appropriate reference voltage, the turn-off timing for each indicator can be shifted as shown in FIG.

  The comparator 31 compares the reference voltage with the output voltage V0, and executes an operation of switching and controlling the output voltage according to the magnitude relationship. For example, when the output voltage V0 is larger than the reference voltage, the comparator 31 outputs the drive voltage V1, and when the output voltage V0 is smaller than the reference voltage, the comparator 31 outputs the ground potential (GND).

  Of course, the organic EL element 71 is turned on when the drive voltage V1 is output, and the organic EL element 71 is turned off when the ground potential (GND) is output.

(A-4) Effect of Embodiment As described above, the battery remaining amount display unit 7 prepared separately from the information display unit 5 can be displayed by adopting a mechanism for supplying power by a system different from the main power switch. Even when the system of the apparatus 1 is not activated (when the main power switch is open), the remaining battery level display unit 7 can be controlled to be turned on in a display mode corresponding to the remaining battery level.

  This frees the user from having to close the main power switch to check the remaining battery level. In addition, it is possible to eliminate the waiting time as in the case where the remaining battery amount displayed on the information display unit 5 is confirmed after the system is activated.

  When the light emitting pixel is an organic EL element, the current flowing through one pixel is on the order of nanoamperes (nA). For this reason, even if the battery remaining amount display portion 7 is always lit for displaying the remaining amount, it is hardly considered that the original use time of the display device is affected.

(B) Other Embodiments (B-1) Improvement of Display Accuracy of Battery Remaining In the above description of the embodiments, the case where the output voltage V0 of the battery power supply 13 is directly applied to the display mode control unit 23 has been described.
That is, the case where the lighting control unit 231 directly compares the output voltage V0 of the battery power supply 13 with the reference voltage has been described.

  However, as shown in FIG. 5, it is known that the output voltage V0 of the battery power supply 13 gradually decreases as the remaining battery level decreases, but rapidly decreases when the remaining battery level decreases to some extent. It has been.

  For this reason, as in the circuit configuration (FIG. 4) described above, the method of directly inputting the output voltage V0 of the battery power supply 13 to the comparator 31 may cause the remaining battery level to be erroneously detected.

  Therefore, the circuit configuration shown in FIG. 7 is proposed. That is, a remaining amount calculation unit 41 for detecting the remaining battery level with higher accuracy and a remaining amount information analog conversion unit 43 that converts the remaining battery level detected by the calculation into an analog voltage are arranged, and the remaining battery level A method is adopted in which a voltage value that changes in proportion to is supplied to the comparison unit 31 of the lighting control unit 231.

In this way, by providing the comparison unit 31 with a voltage value that accurately reflects the remaining battery level instead of the output voltage V0, the determination accuracy in the comparison unit 31 can be increased.
The remaining amount calculation unit 41 has a number of well-known processing circuits and will not be described. The remaining amount information analog conversion unit 43 uses, for example, a digital / analog conversion circuit.

(B-2) Suspension of battery remaining amount display In the description of the above-described embodiment, the case where the battery remaining amount display unit 7 is always controlled to be turned on has been described. As described above, the current consumed by the battery remaining amount display unit 7 is very small.
However, some users may desire a mechanism that can intentionally turn off the battery remaining amount display unit 7.

FIG. 8 shows an example of a circuit configuration equipped with an operation switch 51 that can switch between turning on and off the battery remaining amount display unit 7.
In the case of FIG. 8, the operation switch 51 is disposed on a dedicated power supply line for the battery remaining amount display unit 7.

  The supply of the drive voltage by the operation switch 51 affects only the voltage conversion unit 21, the display mode control unit 23, and the battery remaining amount display unit 7. Therefore, operating the operation switch 51 does not affect the system side. Therefore, the battery remaining amount display and non-display of the battery remaining amount display unit 7 can be switched independently of the main power switch.

(B-3) Stabilization of Determination Accuracy In the case of the above-described embodiment, the case where the lighting control unit 231 having the circuit configuration illustrated in FIG. 6 is used has been described.
However, in this circuit configuration, there is a possibility that the remaining battery level is erroneously determined due to the influence of slight noise.

Therefore, when more stable determination accuracy is required, the positive feedback type comparison circuit configuration shown in FIG. 9 is adopted.
That is, a circuit configuration in which a positive feedback resistor R5 is connected between the positive input terminal and the output terminal is adopted.

In this case, assuming that the reference voltage is VE, a hysteresis voltage VH (determination margin for noise) given by the following equation can be provided.
VH = (V1-VE) × R4 / (R4 + R5)
VE = V0 × R1 / (R1 + R2)

(B-4) Display Panel In the case of the embodiment described above, the case where the information display unit 5 and the battery remaining amount display unit 7 are spatially separated and arranged on the display panel 11 as shown in FIG. 3 has been described. In the case of this configuration example, the existing circuit configuration can be used as it is for the panel configuration and drive circuit of the information display unit 5.

  However, the structure of the display panel 11 is not limited to the arrangement of the light emitting regions shown in FIG. For example, as shown in FIG. 10, the battery remaining amount display portion 7 can be formed integrally with the information display portion 5. In this case, it becomes impossible to display an image or a video on a portion of the display area of the information display unit 5 that overlaps the remaining battery level display unit 7. However, depending on the application, as shown in FIG. 10, the battery remaining amount display section 7 can be arranged in the screen of the information display area 5.

(B-5) Arrangement Position of Battery Remaining Display Unit In the case of the above-described embodiment, the case where the battery remaining amount display unit 7 and the information display unit 5 observed by the user are arranged on the same plane has been described. That is, a configuration has been described in which a window is provided in the housing 3 at a position facing the light emitting surface of the display panel 11 and the light emitting region can be confirmed as it is from the window.

  However, as shown in FIG. 11, the battery remaining amount display unit 7 can be arranged on a housing surface different from the information display unit 5. Incidentally, FIG. 11 is an example in which the battery remaining amount display unit 7 is arranged at the side surface position when the installation surface of the information display unit 5 is the front side. Such an arrangement is possible by installing a light guide member 61 that guides the light output from the battery remaining amount display area to the battery remaining amount display unit 7 as shown in FIG.

For the light guide member 61, for example, an optical fiber is used. By using the light guide member 61, it is possible to guide the light pattern output according to the remaining battery level to an arbitrary position.
In this way, the degree of freedom of the installation position of the battery remaining amount display unit 7 is increased, so that the design of the display device can be improved.
Further, it is possible to install the battery remaining amount display unit 7 at an appropriate position according to the device, such as installing the battery remaining amount display unit 7 at a position where the user can easily confirm.

(B-6) Display of remaining battery level In the case of the above-described embodiment, as shown in FIG. 2, rectangular indicators are arranged in a line, and the remaining battery level is determined by the length (number) of the indicators to be lit. The case of displaying was explained.

  However, the battery remaining amount display method is not limited to this. For example, as shown in FIG. 13, the shape of the indicator may be round. For example, as shown in FIG. 14, a display method in which a battery-shaped outer frame and three indicators are combined may be employed. Further, for example, as shown in FIG. 15, the emission color may be varied according to the remaining battery level.

In the case of FIG. 15, the fully charged state (first state of charge amount) is represented by “white” color, and the next most charged state (second state of charge amount) is represented by “purple” color. Next, a state in which the amount of charge is the second largest (a state in which the amount of charge is the third largest) is represented by “red”.
This display example can be realized by adopting the same color pixel structure as that of the information display unit 5 in the light emitting area of the battery remaining amount display unit 7.

That is, each pixel of the light emitting area constituting the battery remaining amount display unit 7 is formed by light emitting surfaces corresponding to the three primary colors “red”, “green”, and “blue”, and the combination of the light emitting surfaces to be lit is variable. To control the emission color.
Of course, any emission color can be obtained by controlling the emission luminance. In the case of FIG. 15, “white” color is realized by lighting all the light emitting surfaces.

  Further, only the light emitting surface corresponding to the “red” and “blue” colors is turned on, and the light emitting surface corresponding to the “green” color is turned off to realize “purple” color. Further, only the light emitting surface corresponding to the “red” color is turned on, and the light emitting surface corresponding to the “green” color and the “blue” color is turned off to realize the “red” color.

  Of course, other display forms are possible. For example, the remaining battery level can be displayed in more stages or in fewer stages. Moreover, it is also possible to combine the above display forms.

(B-7) Battery Driven Device In the above-described embodiment, the display device has been described as an example of the battery drive device. However, the battery remaining amount display function described above can be installed in various battery-driven devices.

(A) Broadcast wave receiver FIG. 16 is a functional configuration example when the display panel 11 having the above-described structure is applied to a portable broadcast wave receiver. The broadcast wave receiving apparatus 101 includes a display panel 11, a battery power supply 13, a system control unit 103, an operation unit 105, a storage medium 107, and a tuner 109 as main constituent devices.

  Note that the system control unit 103 is configured by, for example, a microprocessor. The system control unit 103 controls the operation of the entire system. The operation unit 105 is a user interface including a main power switch. In addition to mechanical controls, a graphic user interface is also included.

The storage medium 107 is used as a storage area for firmware and application programs in addition to data corresponding to images and videos displayed on the display panel 11. The tuner 109 is a wireless device that selectively receives a broadcast wave of a specific channel selected by the user from incoming broadcast waves.
This configuration of the broadcast wave receiving apparatus can be used when applied to, for example, a television program receiver or a radio program receiver.

(B) Audio Device FIG. 17 is a functional configuration example when the display panel 11 having the above-described structure is applied to an audio device as a playback device.
The audio apparatus 201 as a playback device includes a display panel 11, a battery power supply 13, a system control unit 203, an operation unit 205, a storage medium 207, an audio processing unit 209, and a speaker 211 as main constituent devices.

  Also in this case, the system control unit 203 is constituted by, for example, a microprocessor. The system control unit 203 controls the operation of the entire system. The operation unit 205 is a user interface including a main power switch. In addition to mechanical controls, a graphic user interface is also included.

  The storage medium 207 is a storage area for firmware and application programs in addition to audio data. The audio processing unit 209 is a processing device that processes audio data. The decompression process of the compression-encoded audio data is also executed. The speaker 211 is a device that outputs the reproduced sound.

  When the audio device 201 is used as a recorder, a microphone is connected instead of the speaker 211. In this case, the audio processing unit 209 realizes a function of compressing and encoding audio data.

(C) Communication Device FIG. 18 is a functional configuration example when the display panel 11 having the above-described structure is applied to a portable communication device. The communication apparatus 301 includes the display panel 11, the battery power supply 13, the system control unit 303, the operation unit 305, the storage medium 307, and the wireless communication unit 309 as main constituent devices.

  Note that the system control unit 303 is configured by, for example, a microprocessor. A system control unit 303 controls the operation of the entire system. The operation unit 305 is a user interface including a main power switch. In addition to mechanical controls, a graphic user interface is also included.

The storage medium 103 is used as a storage area for firmware and application programs in addition to data files corresponding to images and videos displayed on the display panel 11. The wireless communication unit 309 is a wireless device that transmits / receives data to / from other devices.
This configuration of the communication device can be used, for example, when applied to a mobile phone.

(D) Imaging Device FIG. 19 is a functional configuration example when the display panel 11 having the above-described structure is applied to a portable imaging device. The imaging apparatus 401 includes the display panel 11, the battery power supply 13, the system control unit 403, the operation unit 405, the storage medium 407, and the imaging unit 409 as main constituent devices.

  Note that the system control unit 403 is configured by a microprocessor, for example. The system control unit 403 controls the operation of the entire system. The operation unit 405 is a user interface including a main power switch. In addition to mechanical controls, a graphic user interface is also included.

The storage medium 403 is used as a storage area for firmware and application programs in addition to data files corresponding to images and videos displayed on the display panel 11. The imaging unit 409 is configured by, for example, a CMOS sensor and a signal processing unit that processes an output signal thereof.
This configuration of the imaging apparatus can be used when applied to, for example, a digital camera, a video camera, or the like.

(E) Information Processing Device FIG. 20 is a functional configuration example when the display panel 11 having the above-described structure is applied to a portable information processing device. The information processing apparatus 501 includes the display panel 11, the battery power supply 13, the system control unit 503, the operation unit 505, and the storage medium 507 as main constituent devices.

  Note that the system control unit 503 is configured by, for example, a microprocessor. A system control unit 503 controls the operation of the entire system. The operation unit 505 is a user interface including a main power switch. In addition to mechanical controls, a graphic user interface is also included.

The storage medium 503 is used as a storage area for firmware and application programs in addition to data files corresponding to images and videos displayed on the display panel 11.
This configuration of the information processing apparatus can be used when applied to, for example, a game machine, an electronic book, an electronic dictionary, a computer, and the like.

(B-8) Self-luminous element In the case of the above-mentioned form example, it demonstrated that the self-luminous element which comprises the information display part 5 and the battery residual amount display part 7 was an organic EL element.
However, any current-driven self-emitting element can be applied to, for example, an inorganic EL element.

(B-9) Others The above-described embodiments can be modified in various ways within the scope of the gist of the invention. Various modifications and applications created or combined based on the description of the present specification are also conceivable.

It is a figure which shows the example of an external appearance structure. It is a figure which shows the example of a display of a battery residual amount display part. It is a figure explaining the panel structure and electric power feeding path | route of a display panel. It is a figure which shows the circuit structural example relevant to a battery remaining charge display. It is a figure which shows the output voltage characteristic of a battery power supply. It is a figure which shows the internal structural example of a lighting control part. It is a figure which shows the other panel structural example. It is a figure which shows the other panel structural example. It is a figure which shows the other internal structural example of a lighting control part. It is a figure which shows the other structural example of a display panel. It is a figure which shows the other external appearance structural example. It is a figure explaining the example of arrangement | positioning of a light guide member. It is a figure which shows the other example of a display of a battery remaining charge display part. It is a figure which shows the other example of a display of a battery remaining charge display part. It is a figure which shows the other example of a display of a battery remaining charge display part. It is a figure which shows the function structural example of a battery drive apparatus. It is a figure which shows the function structural example of a battery drive apparatus. It is a figure which shows the function structural example of a battery drive apparatus. It is a figure which shows the function structural example of a battery drive apparatus. It is a figure which shows the function structural example of a battery drive apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 5 Information display part 7 Battery remaining amount display part 11 Display panel 21 Voltage conversion part 23 Display mode control part 231 Lighting control part 41 Remaining amount calculation part 43 Remaining quantity information analog conversion part 51 Operation switch 61 Light guide member

Claims (9)

On the same panel,
A first light emitting region connected to a battery power source via a main power switch and receiving drive power from the battery power source when the main power switch is closed;
A self-luminous display panel, comprising: a second light emitting region in which driving power is always supplied directly from the battery power source, and a light emission mode changes with a change in remaining battery level. The self-luminous display panel according to claim 1,
The self-luminous display panel, wherein the first and second light-emitting regions are composed of organic electroluminescence elements. The self-luminous display panel according to claim 1 comprises:
A self-luminous display panel, comprising: a display mode control unit that controls a display mode so that the number of indicators displayed in the second light emitting region is reduced as the remaining battery level decreases. The self-luminous display panel according to claim 1 comprises:
A self-luminous display panel, comprising: a display mode control unit that variably controls a light emission color of the second light emission region as the battery remaining amount decreases. The self-luminous display panel according to claim 1 comprises:
A self-luminous display panel, comprising: a light guide member that guides light emitted from the second light emitting region to a window portion formed on a surface of the housing. A main power switch;
When the main power switch is connected to the battery power source via the main power switch and the main power switch is closed, the first light emitting region that receives the driving power from the battery power source and the driving power is always supplied directly from the battery power source. A self-luminous display panel formed on the same panel with a second light-emitting area whose light-emission mode changes according to the transition of the remaining battery capacity;
A self-luminous display device comprising: a light emission mode control unit that controls a light emission mode in the second light emitting region as the battery remaining amount decreases. The self-luminous display device according to claim 6,
A light guide member that propagates the light beam output from the second light emitting region to a window for checking the remaining amount of the battery formed in a region portion excluding the position facing the second light emitting region. Self-luminous display device. The self-luminous display device according to claim 6,
A self-luminous display device comprising: an operation switch that can independently switch on and off the second light emitting region. A battery power source attachment;
A main power switch;
When the main power switch is connected to the battery power source via the main power switch and the main power switch is closed, the first light emitting region that receives the driving power from the battery power source and the driving power is always supplied directly from the battery power source. A self-luminous display panel formed on the same panel with a second light-emitting area whose light-emission mode changes as the remaining battery level changes,
A battery-powered device comprising: a light emission mode control unit that controls a light emission mode in the second light emission region as the battery remaining amount decreases.

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