JP4632722B2 - Driven element control circuit, portable terminal - Google Patents

Description

  The present invention relates to a driven element control circuit that drives and controls a driven element such as an LED (Light Emitting Diode), and a portable terminal equipped with the driven element control circuit.

  Conventionally, various electronic devices have, for example, a light emitting element for illuminating operation keys, a light emitting element for a backlight of a liquid crystal display (LCD), and a notification for giving some notification to the user. In many cases, a plurality of LEDs are mounted as a light-emitting element for use.

  In recent years, LED control ICs capable of driving a plurality of LEDs with one IC (integrated circuit) have been put into practical use. However, there is always a variation in the so-called forward voltage (VF) of a plurality of LEDs having different emission colors such as R (red), G (green), B (blue), and white. For example, when driving the plurality of LEDs using power from the battery, each LED may or may not emit light or may emit light as the voltage decreases due to battery consumption. However, there may be a difference in brightness.

  For this reason, in Japanese Patent Application Laid-Open No. 2004-6533 (Patent Document 1), when a plurality of LEDs having different emission colors are driven and controlled by one LED control IC, the forward direction of each LED is described. When the voltage (VF) is read to determine the highest forward voltage (VF) among the forward voltages (VF) of the plurality of LEDs, the battery voltage decreases to a preset voltage. By operating the DC converter to boost the battery voltage and supplying the LEDs with the minimum voltage and current necessary to make each LED emit light, the lowest voltage that always satisfies the drive conditions is always output. A technology that can realize an LED control IC that can perform light emission efficiency and has low power loss is disclosed.

Japanese Patent Laying-Open No. 2004-6533 (FIG. 1)

  By the way, the LED control IC for driving a plurality of LEDs includes FETs (Feild Effect Transistors) for turning on / off the LEDs at terminals to which the LEDs are connected.

  For this reason, for example, when power is supplied from a battery and one LED control IC drives the plurality of LEDs, for example, when the battery is consumed and becomes a low voltage, each LED control IC The voltage between the drain and source of the FET for turning on / off each of the LEDs connected to the terminals decreases, and for example, as shown in FIG. 9, among the terminals LED1-1 to LED1-4 for adjacent LEDs. When the output difference is as large as maximum → zero → maximum (or zero → maximum → zero), there is a problem that noise occurs at a terminal having a large output difference. In particular, the occurrence of noise as described above becomes prominent when the state of the LED changes significantly, such as switching the LED from on to off or from off to on. In the example of FIG. 9, the outputs of the terminals LED1-2 and LED1-4 are maximized, while the output of the terminals LED1-3 arranged between the terminals LED1-2 and LED1-4 is set to zero. This shows a state where the output of the terminal LED1-3 has not fallen to zero due to noise from the output of the terminals LED1-2 and LED1-4.

  The present invention has been made in view of such a problem. For example, when power is supplied from a battery to a plurality of driven elements such as LEDs, the battery is consumed and the voltage is lowered. Mounted a driven element control circuit and its driven element control circuit, which can suppress the generation of noise even if there is a large difference in output for driving adjacent driven elements. An object is to provide a portable terminal.

The driven element control circuit of the present invention boosts the power supply voltage to a predetermined voltage when the power supply voltage becomes lower than the specified voltage, and supplies the power supply voltage boosted to the predetermined voltage to the plurality of driven elements. A plurality of terminals each connected to a plurality of driven elements, a drive control value setting unit for setting a drive control value for each driven element connected via each terminal, and a plurality of Intermediate value generation that generates a substantially intermediate value between the drive control value when driving the driven element connected to the adjacent terminal and the drive control value when not driving the driven element between adjacent terminals of each terminal and parts, by a control unit to generate an intermediate value in the intermediate value generating unit when the power supply voltage becomes lower than a specified voltage, to solve the problems described above.

The driven element control circuit of the present invention boosts the power supply voltage to a predetermined voltage when the power supply voltage becomes lower than the specified voltage, and supplies the power supply voltage boosted to the predetermined voltage to the anodes of the plurality of light emitting diodes. A plurality of LED drive current setting circuits each including a converter, a plurality of terminals respectively connected to the cathodes of the plurality of light emitting diodes, and FET elements respectively connected to the cathodes of the respective light emitting diodes through the terminals; An on / off control circuit for controlling on / off of the light emitting diode connected via the terminal, and a drive control value when the light emitting diode emits light and a drive control value when the light emitting diode does not emit light are approximately intermediate values. the for producing 1, a second resistor element, char the intermediate value while being respectively connected to the gate of the FET device of the LED drive current setting circuit And plurality of capacitors to a plurality of imaginary circuit comprising a third resistor element provided adjacent respectively to the respective LED drive current setting circuit as a dummy of the LED drive current setting circuit, becomes the power supply voltage lower than the specified voltage The drive control value is supplied to the gate of the FET element, and each imaginary circuit is connected between adjacent terminals of the plurality of terminals, and the intermediate value charged in the capacitor is supplied to the gate of the FET element. By having a switch element that sequentially switches the supplied state , the above-described problems are solved.

The portable terminal of the present invention includes a battery, a plurality of driven elements driven by a power supply voltage from the battery, an execution unit for executing a predetermined function, and a power supply voltage from the battery lower than a specified voltage. A boosting unit that boosts the power supply voltage to a predetermined voltage and supplies the power supply voltage boosted to the predetermined voltage to the plurality of driven elements; a plurality of terminals that are respectively connected to the plurality of driven elements; A drive control value setting unit for setting a drive control value for each driven element connected via each terminal, and a driven element connected to the adjacent terminal between adjacent terminals of the plurality of terminals an intermediate value generating unit that generates a substantially intermediate value of the drive control value when the drive control values and not driving a driven element when to be, when the supply voltage is below the prescribed voltage, and controls the intermediate value generating unit To generate an intermediate value By having a control unit, to solve the problems described above.

That is, according to the present invention, when the power supply voltage becomes lower than the specified voltage, an output between adjacent terminals is generated by generating a pseudo intermediate value between adjacent terminals connected to each driven element. Even if there is a large difference, the influence on these terminals is only due to the intermediate value.

In the present invention, for example, when power is supplied from a battery and one LED control IC drives the plurality of LEDs, the output is used to drive a driven element connected to an adjacent terminal. By generating an intermediate value in a pseudo manner, for example, the battery is consumed and the voltage becomes low, and even if there is a large difference in output for driving adjacent driven elements, noise to these driven elements Can be suppressed.

  Hereinafter, an embodiment of a driven element control circuit and a mobile terminal according to the present invention will be described with reference to the drawings. In the present embodiment, as the driven element control circuit of the present invention, an LED control IC that controls the drive currents of a plurality of LEDs that are driven elements is taken as an example, and a mobile phone terminal as an example of the mobile terminal of the present invention Cite. In the embodiment of the present invention, an example in which the LED control IC drives and controls 16 LEDs (16-channel LEDs) is given. Of course, the content described here is merely an example, and it goes without saying that the present invention is not limited to this example.

[Internal configuration of mobile phone terminal]
Hereinafter, a schematic internal configuration of the mobile phone terminal according to the embodiment of the present invention described above will be described with reference to FIG.

  The antenna 12 is, for example, a built-in antenna, and transmits and receives signal radio waves for calls and packet communications. The communication circuit 13 performs frequency conversion, modulation, demodulation, and the like of the transmission / reception signal.

  For example, call voice data received by the communication circuit 13 is sent to the control unit 11 via a data line. The control unit 11 includes a CPU (Central Processing Unit), decodes call voice data, and sends the decoded voice data to the speaker 19 via a data line.

  The speaker 19 corresponds to a receiving speaker or a ringer speaker, and includes a digital / analog converter and an amplifier. The speaker 19 digitally / analog-converts and amplifies voice / linger sound data and outputs the converted data. Thereby, a call voice and a ringer sound are obtained.

  The microphone 20 is a microphone for transmission, and includes an analog / digital converter and an amplifier. The call voice signal input through the microphone 20 is amplified to a predetermined level by an amplifier, converted to digital voice data by an analog / digital converter, and sent to the control unit 11 through a data line. After being encoded, it is sent to the communication circuit 13.

  The display control unit 16 controls the display of the main display unit 15 that is a main liquid crystal display and the sub display unit 17 that is a sub liquid crystal display provided in the mobile phone terminal of the present embodiment.

  The operation unit 18 includes a numeric keypad and a jog dial provided on a casing (not shown) of the mobile phone terminal, an operation signal generation unit that generates an operation signal corresponding to the operation.

  The memory 14 includes a ROM (Read Only Memory) and a RAM (Random Access Memory). The ROM has various control programs for the control unit 11 to control each unit, various initial setting values, font data, dictionary data, program codes for applications for creating and editing e-mails, and various images. In addition, application code for performing various processes, program codes for various applications installed in the mobile phone terminal, identification information (ID) of the mobile phone terminal, and the like are stored. This ROM includes a rewritable ROM such as an EEPROM (Electrically Erasable Programmable Read-Only Memory), e-mail data, a phone book and e-mail address set by the user, downloaded photo data and ringtone data, It is also possible to store character data, prediction conversion candidate word registration data, prediction conversion learning data, and various user setting values. The RAM stores data as needed as a work area when the control unit 11 performs various data processing.

  The LED drive unit 21 includes the LED control IC according to the embodiment of the present invention, and a plurality of LEDs 22 such as an LED for illuminating a key on the operation unit 18, a backlight LED for the main liquid crystal display and the sub liquid crystal display, and an incoming LED Is controlled.

  The control unit 11 performs various arithmetic processes such as control of each component of the mobile phone terminal via the control line, in addition to the above-described encoding and decoding of the call voice data.

  The camera unit 23 includes an optical lens, an image sensor, and the like, and takes a still image or a moving image under the control of the control unit 11.

  The battery 25 is a detachable secondary battery, for example, and the power management IC 24 supplies power from the battery 25 to each unit.

  In addition, although not shown in FIG. 1, the mobile phone terminal of this embodiment is connected to a recording / playback unit for recording and playing music and images, a browser function, an external cable connector, and an external remote controller. It also includes a connector, a GPS (Global Positioning System) communication unit that is a positioning device for detecting the current position of the mobile phone terminal, and its antenna.

[Configuration of LED control IC]
Hereinafter, the internal configuration of the LED control IC of the embodiment of the present invention will be described with reference to FIG. In the LED control IC, descriptions of terminals and configurations that are not particularly related to the contents of the present embodiment are omitted.

  In the LED control IC of the present embodiment, a plurality of (16) LEDs 22 having substantially the same or different driving voltages, that is, forward voltages VF necessary for light emission, are connected in parallel. As an example, the terminal LED1 The cathodes of four backlight LEDs of the main liquid crystal display are connected to -1 to LED1-4, and the cathodes of R, G, B3 color LEDs for incoming call notification are connected to the terminals LED2-1 to LED2-3. The terminals LED3-1 to LED3-3 are cathodes of three backlight LEDs of the sub liquid crystal display, and the terminals LED4-1 to LED4-3 and LED5-1 are four LEDs for camera photographing auxiliary light. (So-called picture light) cathodes are connected to the terminals LED5-2 and LED5-3, respectively. It has been. The terminal DCDC_OUT of the LED control IC is connected to the anode of each LED, and a power supply voltage is supplied from the battery 25 to the terminal VCC via the power management IC 24. The LED control IC then selects the optimum voltage (for example, the lowest voltage) when driving each LED with the set current of the LED having the maximum forward voltage VF (Max. VF) among the connected LEDs. Are supplied from the terminal DCDC_OUT to the anodes of the LEDs, and the terminals LED1-1 to LED1-4, LED2-1 to LED2-3, LED3-1 to LED3-3, LED4-1 to LED4-3, and LED5. The LED connected to the cathodes of −1 to 5-3 has a function of driving to emit light at an arbitrary luminance (drive current).

  Also, the terminals SEN, SCLK, and SDAT of the LED control IC are connected to the CPU of the control unit 11. From the CPU, a serial enable signal is supplied to the terminal SEN, a serial clock signal is supplied to the terminal SCLK, and serial data is supplied to the terminal SDAT. Are supplied respectively. In the present embodiment, the serial data is digital data representing a current value for driving each LED. These serial enable signal, serial clock, and serial data are sent to the serial I / F register circuit 30.

  The serial I / F register circuit 30 reads the register in accordance with the serial data sent from the CPU of the control unit 11 and outputs parallel data representing the current value of each LED. The parallel data representing the current value is sent to 16 current control circuits 34a to 34p provided corresponding to the respective LEDs.

  The current control circuits 34a to 34p set data representing the brightness value for each corresponding LED from the data representing the current value, and the brightness setting value data for each LED is associated with each LED. Current sampling circuits 35a to 35p provided, and 16 imaginary circuits 36a to 36a provided as dummy circuits for LED brightness control current setting circuits described later provided in the current sampling circuits 35a to 35p, respectively. To 36p. The detailed configurations and operations of the LED drive control current setting circuit that is a real circuit and the imaginary circuits 36a to 36p that are dummy circuits will be described later.

  The constant current circuit 38 sets a fixed drive current value when the power supply voltage of the battery 25 is equal to or higher than a specified voltage, and supplies a signal representing the fixed set drive current value to the current sampling circuits 35a to 35p.

  On the other hand, when the power supply voltage of the battery 25 falls below the specified voltage, the DC-DC converter circuit 39, as will be described later, supplies the power to the predetermined voltage corresponding to the highest forward voltage among the currently driven LEDs. The voltage is boosted, and the voltage is supplied from the terminal DCDC_OUT to the anode of each LED. The DC-DC converter circuit 39 also outputs a signal for determining the sampling period in the subsequent current sampling circuits 35a to 35p.

  The thermal shutdown circuit 37 stops (shuts down) the operations of the DC-DC converter circuit 39 and the current sampling circuits 35a to 35p when the temperature of the LED control IC exceeds a specified temperature.

  The BGR circuit 33 is a circuit that operates as a reference voltage generation and bias current source, and supplies a reference voltage for comparison with the power supply voltage of the battery 25 to the constant current circuit 38.

  The LED on / off control circuit 31, which will be described in detail later, includes an operational amplifier, a switch, a resistor, and the like, and corresponds to a value obtained by digital / analog conversion of data representing the current value from the serial I / F register circuit 30. Thus, a control signal for performing LED on / off control is generated. This LED on / off control signal is output to the switching circuit 32.

Switching circuit 32, a LED on / off control signal, and outputs the sequentially switched to the 16 current sampling circuit 3 5 a~3 5 p and 16 imaginary circuits 36A to 36P. That is, the switching circuit 32 is switched with respect to the 16 total of 32 circuit 16 and the imaginary circuit 36a~36p current sampling circuit 3 5 a~3 5 p, a LED on / off control signal in order Output To do.

  The current sampling circuits 35a to 35p have 16 corresponding terminals LED1-1 to LED1-4, LED2-1 to LED2-3, LED3-1 to LED3-3, LED4-1 to LED4-3, LED5-, respectively. 1 to LED5-3, connected to the cathode of the LED through these terminals, and the LED brightness control current setting circuit provided therein supplies from the corresponding current control circuits 34a to 34p. The LED brightness control current setting value is set according to the LED brightness setting value data.

  The current sampling circuits 35a to 35p have corresponding terminals LED1-1 to LED1-4, LED2-1 to LED2-3, LED3-1 to LED3-3, LED4-1 to LED4-3, and LED5-1 to LED5-1. The difference voltage between the forward voltage output to each LED via the LED 5-3 and the voltage supplied from the DC-DC converter circuit 39 when the DC-DC converter circuit 39 is operating is a predetermined cycle. And sampling voltage values are fed back to the DC-DC converter circuit 39.

  The DC-DC converter circuit 39 at this time compares each sampling voltage value supplied from the current sampling circuits 35a to 35p with the reference voltage value, and the difference between the smallest sampling voltage value and the reference voltage, in other words, the highest value. A signal indicating the forward voltage VF is generated. The DC-DC converter circuit 39 boosts the power supply voltage of the battery 25 to a value corresponding to the highest forward voltage VF, and the boosted voltage is supplied from the terminal DCDC_OUT to the anode of each LED. Supply.

[Step-up / down operation by DC-DC converter]
Hereinafter, the operation when the DC-DC converter circuit 39 turns on / off the power supply voltage in accordance with the highest forward voltage VF described above will be described with reference to FIG.

  3, the graph (A) in the drawing shows the correlation between the power supply voltage of the battery 25 (battery voltage VBAT), the boosted voltage of the DC-DC converter circuit 39 (output voltage of the terminal DCDC_OUT), and the remaining amount of the battery 25. The graph of (B) in the figure shows the terminals LED1-1 to LED1-4, LED2-1 to LED2-3, LED3-1 to LED3-3, LED4-1 to LED4-3, LED5- The correlation between the terminal voltage of any one of the operating LEDs 1 to 5 and the remaining amount of the battery 25 is shown.

  As shown in FIGS. 3A and 3B, when the battery 25 is charged, the difference (DCDC_OUT-VCC) between the output voltage (DCDC_OUT) of the DC-DC converter circuit 39 and the battery voltage (VCC) of the battery 25 is charged. ) Is lower than the specified voltage value (DC_THR [2.0]) (DCDC_OUT−VCC <DC_THR [2.0]), the DC-DC converter circuit 39 is turned on and the DC-DC converter circuit 39 is turned on. Thus, the voltage is boosted by a predetermined set value DC_THR [2.0]. Further, when the battery 25 is discharged, the battery voltage (VCC) of the battery 25 becomes lower than a voltage value obtained by adding a certain constant value (0.3 V in this example) to the above-mentioned highest forward voltage (Max.VF). (Max.VF LED terminal voltage <0.3) is detected, the DC-DC converter circuit 39 is turned on, and the DC-DC converter circuit 39 boosts the signal by a predetermined set value DC_HYS [2.0]. Is made. In other cases, boosting is not performed and the power supply voltage of the battery 25 is used as it is.

[Operating conditions of each circuit block of LED control IC]
Next, with reference to the functional block diagram of FIG. 4, the operating conditions when the boosting is turned on by the DC-DC converter circuit 39 in each circuit section in the LED control IC described above and the operation according to the operating conditions. explain.

  As the DC-DC converter circuit setting condition 51, when “1” of the DC-DC converter enable signal DCDD_EN is supplied from the CPU to the serial I / F register circuit 30, the serial I / F register circuit 30 performs a boost operation. When the setting signal “1” to be turned on is output and the DC-DC converter enable signal DCDD_EN “0” is supplied, the serial I / F register circuit 30 is a setting signal for turning off the boosting operation. “0” is output.

Further, when the LED drive circuit setting condition 52 is supplied with data indicating that any one of the LEDs is lit from the serial I / F register circuit 30 to the current control circuits 34a to 34p, the current control circuit 34a. To 34p, when the current sampling circuits 35a to 35p output "1" which is a setting signal for turning on the above-described sampling operation, while data indicating that all the LEDs are turned off is supplied. From the current control circuits 34a to 34p, "0" that is a setting signal for turning off the sampling operation in the current sampling circuits 35a to 35p is output.

  The ON / OFF setting signal for the boost operation and the ON / OFF setting signal for the sampling operation are ORed 53, and the calculation result is sent to the BGR circuit 33 as a signal for instructing the on / off operation of the BGR circuit 33. And also sent to the thermal shutdown circuit 37. The thermal shutdown circuit 37 outputs a temperature OK signal (“1”) or a temperature NG signal (“0”).

  The temperature OK / NG signal from the thermal shutdown circuit 37 and the signal of the operation result of the OR operation 53 are ANDed 55, and the operation result is sent to the DC-DC converter oscillator 57 not shown in FIG. Further, the oscillation signal from the DC-DC converter oscillator 57 is sent to an oscillation start-up counter 58 that is not shown in FIG. When the count number of the oscillation start-up counter 58 reaches a predetermined count number, the oscillation start-up counter 58 outputs “1”, which is a signal that allows the current sampling circuit 35 (35a to 35p) to start sampling. The On the other hand, while the predetermined count is not reached, the oscillation start-up counter 58 outputs “0”, which is a signal that does not permit the start of sampling.

  Further, the temperature OK / NG signal from the thermal shutdown circuit 37, the sampling start enable / disable signal from the oscillation start-up counter 58, and the sampling operation on / off setting signal are subjected to a logical AND operation 56. It is sent to the current sampling circuit 35 (35a to 35p). When the operation result in the AND operation 56 is “1”, the current sampling circuit 35 performs the above-described sampling operation and sets the LED drive current.

  Further, the temperature OK / NG signal from the thermal shutdown circuit 37, the ON / OFF setting signal of the boost operation, and the signal of the operation result of the AND operation 56 are subjected to the AND operation 54, and the operation result is converted into the DC-DC converter circuit 39. Will be sent to. When the operation result of the AND operation 56 is “1”, the boosting operation of the DC-DC converter circuit 39 is started.

Referring to FIG. 5, and each LED brightness control current setting circuit is provided 76a~76p in the current sampling circuit 35A～35p, and detailed configuration of the imaginary circuit 3 6A～36p its dummy circuit, their The detailed configurations of the LED on / off control circuit 31 and the switching circuit 32, which are the previous configuration, will be described.

  In FIG. 5, the LED on / off control circuit 31 is closed when any one of the terminals 70 to which a signal representing the current value from the serial I / F register circuit 30 is supplied and the LED is turned on. A switch 71 that is opened when all LEDs are turned off, and resistors R1 and R2 for generating an intermediate value (intermediate potential) between the terminal 70 and the ground (these resistance values are substantially the same). The intermediate value is supplied to the non-inverting input terminal, and the operational amplifier 72 is connected to the terminal 70 via the switch 71 to the inverting input terminal. In the figure, CP is a parasitic capacitance.

  The switching circuit 32 includes switch circuits 74a to 74p corresponding to the current sampling circuits 35a to 35p and switch circuits 75a to 75p respectively corresponding to the imaginary circuits 36a to 36p. The switch circuits 74a to 74p and the switch circuits 75a to 75p are each composed of a pair of switches that are opened and closed in conjunction with each other. One of the two sets of switches in the switch circuits 74a to 74p includes the gate of the P channel FET in the LED brightness control current setting circuit 76 in the corresponding current sampling circuit 35a to 35p and the output of the operational amplifier 72, respectively. The other is connected between the source of the FET and the inverting input terminal of the operational amplifier 72. One of the two sets of switches in the switch circuits 75a to 75p is connected between one end of the resistor in the corresponding imaginary circuit 36a to 36p and the output terminal of the operational amplifier 72. The other is connected between the other end of the resistors in the imaginary circuits 36 a to 36 p and the inverting input terminal of the operational amplifier 72.

  The LED brightness control current setting circuits 76a to 76p in the current sampling circuits 35a to 35p (FIG. 5 shows only the LED brightness control current setting circuit 76a in the current sampling circuit 35a in detail) has a gate having a predetermined capacity. The capacitor CA is connected, the source is connected to the variable resistor VR, and the drain is connected to the cathodes of the corresponding LEDs 78a to 78p via the corresponding LED terminals LED1-1 to LED5-3 of the LED control IC. Yes.

  The imaginary circuits 36 a to 36 p each include only a resistor, and the resistor is connected to a set of switches corresponding to the switching circuit 32.

  In the configuration as shown in FIG. 5, in the switching circuit 32, the switch circuits 74a to 74p connected to the LED luminance control current setting circuits 76a to 76p and the switch circuits 75a to 75p connected to the imaginary circuits 36a to 36p. Are closed / open in turn.

  With such a configuration and the operation of the switching circuit 32, the LED on / off control circuit 31 is artificially connected to a total of 32 circuits of the LED brightness control current setting circuits 76a to 76p and the imaginary circuits 36a to 36p. Will look like this. In particular, the capacitor CA of the LED brightness control current setting circuits 76a to 76p is in a state in which the intermediate value is always charged. Therefore, when the imaginary circuits 36a to 36p are connected by closing the switch circuits 75a to 75p, they are adjacent to each other. A pseudo intermediate value can be seen between the terminals.

  Therefore, according to the present embodiment, the respective terminals LED1-1 to LED1-4, LED2-1 to LED2-3, LED3-1, LED3-1, LED3-3, and LED4-, which are LED connection terminals of the LED control IC. 1 to LED4-3, LED5-1 to LED5-3, especially when the output difference among adjacent terminals increases as maximum → zero → maximum (or zero → maximum → zero). As shown in FIG. 6, an intermediate value can be seen between the actual terminals even when the state of the LED changes greatly, such as switching from ON to OFF or switching from OFF to ON. Therefore, noise as described with reference to FIG. 9 does not occur at the LED terminal. In the example of FIG. 6, the outputs of the terminals LED1-2 and LED1-4 are maximized, while the output of the terminals LED1-3 arranged between the terminals LED1-2 and LED1-4 is set to zero. When it should be, only the intermediate value by the imaginary circuits 36b and 36c can be seen from the terminal LED1-3, no noise is generated in the terminal LED1-3, and the output of the terminal LED1-3 can be lowered to zero. It becomes possible.

[Second Specific Example of LED Driving Current Setting Circuit and Imaginary Circuit]
The above-described example of FIG. 5 shows a configuration in which the capacitor CA is always charged with an intermediate value. As a second specific example of the embodiment of the present invention, as shown in FIG. By providing a logic circuit 90 for outputting an intermediate value when the difference in output value between adjacent LED terminals is the largest between the switching circuits 32, the capacitor CA does not always have to be charged with an intermediate value. A configuration that improves the power consumption to reduce the power consumption is also conceivable. In FIG. 7, the same components as those in FIG. 5 are denoted by the same reference numerals, and description thereof is omitted.

  The logic circuit 90 in the example of FIG. 7 can be realized by a configuration as shown in FIG. 8, for example.

  In FIG. 8, a terminal 102 is connected to the inverting input terminal of the operational amplifier 72, and a terminal 104 is the LED brightness among the two sets of switches of the switch circuits 74a to 74p and 75a to 75p of the switching circuit 32. It is connected to the switch on the source side of the FET of the control current setting circuit.

  The terminal 101 is connected to the output terminal of the operational amplifier 72, and the terminal 103 is connected to the switch on the gate side of the FET of the LED brightness control current setting circuit among the two sets of switches of each switch circuit. The

  The logic circuit 90 includes D-type flip-flops 111, 112, and 113 that handle the output of the operational amplifier 72 as binary signals of “H” and “L”, and an exclusive OR gate 114. The input terminal D of the D-type flip-flop 111 and the input terminal D of the D-type flip-flop 113 are both connected to the terminal 101, and the output terminal Q of the D-type flip-flop 111 is connected to the input terminal D of the D-type flip-flop 112. It is connected. The output terminal Q of the D-type flip-flop 112 is connected to one input terminal of the exclusive OR gate 114, and the output terminal Q of the D-type flip-flop 113 is the other input terminal of the exclusive OR gate 114. Connected with. Further, a predetermined clock signal is supplied to the clock terminal CK of the D-type flip-flops 111, 112, 113 via the terminal 105.

  That is, in the logic circuit 90 shown in FIG. 8, when the difference in the output value between adjacent LED terminals is the largest, the output of the operational amplifier 72 is output by the D-type flip-flops (111, 112) having a two-stage configuration. An intermediate value of the output of the operational amplifier 72 is generated and output by performing an exclusive OR operation (114) between the latched signal and the signal obtained by latching the output of the operational amplifier 72 by the D-type flip-flop 113 in one stage. To do.

[Summary]
As described above, according to the LED control IC and the mobile phone terminal of the present embodiment, the imaginary circuit as a dummy circuit is provided between the LED brightness control current setting circuits 76a to 76p actually connected to the LED terminal. By providing 36a to 36p, when the battery 25 is consumed and the power supply voltage is boosted by the DC-DC converter 39, an intermediate value is set between the adjacent terminals for LEDs of the LED control IC. Therefore, even if there is a large difference in output between adjacent terminals for LEDs, it is possible to suppress the generation of noise.

  The above description of the embodiment is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made according to the design or the like as long as the technical idea according to the present invention is not deviated.

  For example, the mobile terminal of the present invention can be applied not only to mobile phone terminals but also to all electronic devices such as PDA devices (PDA: Personal Digital Assistants) that drive and control a plurality of LEDs driven by a battery with a single LED control IC. It is.

  Further, the present invention is not limited to the one that drives the LED, and can be applied to all objects that drive various elements driven by a battery with one control IC.

It is a block block diagram which shows the schematic internal structure of the mobile telephone terminal of embodiment of this invention. It is a block circuit diagram which shows the schematic internal structure of LED control IC of this invention embodiment. It is a figure used for description of operation | movement when a DC-DC converter circuit performs step-up ON / OFF of a power supply voltage according to the highest forward voltage. It is a functional block diagram used for operation explanation according to the operation condition according to the operation condition when each booster is turned on by the DC-DC converter circuit in each circuit unit in the LED control IC. It is a circuit diagram used for description of the configuration and operation of a first specific example of an LED drive current setting circuit and an imaginary circuit, and an LED on / off control circuit and a switching circuit. It is a figure used for description of the effect of LED control IC of this embodiment. FIG. 5 is a circuit diagram used for explaining the configuration and operation of a second specific example of an LED drive current setting circuit, an imaginary circuit, an LED on / off control circuit, a switching circuit, and a logic circuit; It is a circuit diagram used for description of a specific internal configuration of a logic circuit of a second specific example. It is a figure used for description of the problem of the conventional LED control IC.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 Control part, 12 Antenna, 13 Communication circuit, 14 Memory, 15 Main display part, 16 Display control part, 17 Sub display part, 18 Operation part, 19 Speaker, 20 Microphone, 21 LED drive part, 22 LED, 23 Camera part , 24 power management IC, 25 battery, 30 serial I / F register circuit, 31 LED on / off control circuit, 32 switching circuit, 33 BGR circuit, 34a-34p current control circuit, 35a-35p current sampling circuit, 36a-36p Imaginary circuit, 37 Thermal shutdown circuit, 38 Constant current circuit, 39 DC-DC converter circuit, 51 DC-DC converter circuit setting condition, 52 LED drive circuit setting condition, 53 OR operation, 54, 55, 56 Product operation, 57 DC-DC converter oscillator, 58 transmission start-up counter, 70 serial I / F register output input terminal, 71 switch, 72 operational amplifier, 74a-74p, 75a-75p switch circuit, 76a-76p LED drive current setting circuit 78a-78p LED, 80a FET, 90 logic circuit, 111, 112, 113 D-type flip-flop, 114 exclusive OR gate

Claims (6)

A boosting unit that boosts the power supply voltage to a predetermined voltage when the power supply voltage becomes lower than a specified voltage, and supplies the power supply voltage boosted to the predetermined voltage to a plurality of driven elements;
A plurality of terminals respectively connected to the plurality of driven elements;
A drive control value setting unit that is connected to each driven element via each terminal and sets a drive control value for each driven element connected via each terminal;
A substantially intermediate value between the drive control value when driving the driven element connected to the adjacent terminal and the drive control value when not driving the driven element is generated between adjacent terminals of the plurality of terminals. an intermediate value generating unit for,
When the power supply voltage becomes lower than the specified voltage, the driven element control circuit that have a control unit to generate the intermediate value in the intermediate value generating unit. The driven element control circuit according to claim 1 , wherein the intermediate value generation unit generates the intermediate value when an output difference between the adjacent terminals is equal to or greater than a predetermined value. The driven element is a light emitting diode,
The boosting unit supplies the boosted power supply voltage to the anode of the light emitting diode,
The drive control value setting unit sets the brightness control value of the light emitting diode as the drive control value,
2. The driven element control circuit according to claim 1, wherein each of the terminals is connected to a cathode of a corresponding light emitting diode. A converter that boosts the power supply voltage to a predetermined voltage when the power supply voltage becomes lower than a specified voltage, and supplies the power supply voltage boosted to the predetermined voltage to the anodes of the plurality of light emitting diodes;
A plurality of terminals respectively connected to cathodes of the plurality of light emitting diodes;
A plurality of LED drive current setting circuits including FET elements respectively connected to the cathodes of the respective light-emitting diodes via the terminals;
An on / off control circuit for controlling on / off of the light emitting diode connected via each terminal ;
First and second resistance elements for generating a substantially intermediate value between a drive control value when the light emitting diode emits light and a drive control value when the light emitting diode does not emit light ,
A plurality of capacitors each connected to the gate of the FET element of each LED drive current setting circuit and charging the intermediate value;
A plurality of imaginary circuits comprising third resistance elements provided adjacent to each LED drive current setting circuit as a dummy of each LED drive current setting circuit;
When the power supply voltage becomes lower than a specified voltage, the drive control value is supplied to the gate of the FET element, and each imaginary circuit is connected between adjacent terminals of the plurality of terminals and the capacitor A switching element for sequentially switching the state in which the intermediate value charged to the FET element is supplied to the gate of the FET element ;
The driven element control circuit having. 5. The driven element control circuit according to claim 4, further comprising a logic circuit for charging the intermediate value to the capacitor only when an output difference between adjacent terminals becomes equal to or greater than a predetermined value. Battery,
A plurality of driven elements driven by a power supply voltage from the battery;
An execution unit for executing a predetermined function;
When the power supply voltage from the battery becomes lower than a specified voltage, and the power supply voltage is boosted to a predetermined voltage, the boosting unit supplies the plurality of driven elements the power voltage boosted to the predetermined voltage,
A plurality of terminals respectively connected to the plurality of driven elements;
A drive control value setting unit that is connected to each driven element via each terminal and sets a drive control value for each driven element connected via each terminal;
A substantially intermediate value between the drive control value when driving the driven element connected to the adjacent terminal and the drive control value when not driving the driven element is generated between adjacent terminals of the plurality of terminals. an intermediate value generating unit for,
And a control unit that causes the intermediate value generation unit to generate the intermediate value when the power supply voltage becomes lower than a specified voltage.

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