KR100620685B1 - Apparatus for converting GPIO signal and Mobile communication terminal using the apparatus - Google Patents

Abstract

The present invention relates to a mobile communication terminal, and more particularly, to a technology for converting and outputting a PDM signal used in the terminal to a plurality of digital signals.

The present invention can solve the problem caused by the shortage of the GPIO terminal for outputting the control signal of the external component added by converting the PDM signal output from the PDM terminal provided in the MSM chip of the mobile communication terminal to a plurality of GPIO signals That has the advantage.

According to an aspect of the present invention, a mobile communication terminal includes an RC filter for converting a PDM signal having different duty cycles output from a PDM terminal of an MSM into a DC voltage having a continuous voltage, and according to the level of the converted DC voltage. Multiple GPIO Digital Scenes

Characterized in that it comprises a signal converter for converting and outputting the call. According to an advantageous aspect of the present invention, the signal converter according to the present invention is characterized in that it can be expanded only by adding a simple circuit component and a digital logic circuit.

Mobile terminal, MSM, PDM, GPIO, DUTY CYCLE

Description

Apparatus for converting GPIO signal and Mobile communication terminal using the apparatus}

1 is a block diagram schematically illustrating a mobile communication terminal according to an exemplary embodiment of the present invention.

2A is a block diagram schematically illustrating a signal converter according to an exemplary embodiment of the present invention.

FIG. 2B is a truth table showing the output value of the signal converter shown in FIG. 2A.

3A is a block diagram schematically illustrating an extended signal converter according to another embodiment of the present invention.

3B is a truth table showing the output value of the signal converter shown in FIG. 3A.

4A is a circuit diagram illustrating a signal conversion circuit according to another embodiment of the present invention.

FIG. 4B is a graph showing output voltages output from two load resistors of the signal conversion circuit shown in FIG. 4A.

<Description of the symbols for the main parts of the drawings>

100. MSM chip 110. Communication control unit

120. System Controls 210. Keypad

220. Indicator 230. LED

240. Wireless communication unit 250. Voice input and output circuit

260. Audio playback unit 270. Audio output unit

280. Electric vibrator 290. External parts

300.RC filter 400.Signal converter

400-1. First signal converter 400-2. Second signal converter

410. First comparator 420. Second comparator

430. Third comparison unit 440. First switching unit

450. Fourth comparator 460. Fifth comparator

470. Sixth comparator 480. The seventh comparator

490. Second switching unit 500. Signal conversion circuit

510. Control power terminal 520. Drive power terminal

530. First voltage divider 540. First output unit

550. Second voltage divider 560. Second output portion

The present invention relates to a mobile communication terminal, and more particularly, to a technology for converting and outputting a PDM output voltage used in the terminal to a plurality of digital control signals.

As the number of mobile communication terminals has increased in recent years and various functions have been added at the request of consumers, as personal mobile communication terminals have become multimedia devices, the structure of the terminal is complicated and the MSM chip provided in the terminal has many external components to be controlled. It is losing.

Currently, MSM chips in mobile communication terminals use digital logic signals to effectively control components such as vibration motors, LCDs, and LEDs. The MSM is equipped with input / output terminals called GPIOs (General Purpose Input Outputs) for inputting and outputting such control signals, and the number of GPIOs provided by the MSM chip is limited, which places many restrictions on the implementation of various functions in the new terminal planning stage.

In general, a pulse duration modulation (PDM) output unit is implemented in the MSM chip to control external components at a continuous voltage level. The PDM signal can control external components by controlling the ratio of the time to stay high and low by adjusting the ratio of high and low in one duty cycle. A typical PDM output is made by an RC filter consisting of a resistor and a capacitor. However, the PDM output from the MSM chip of the terminal is rarely utilized, and the number of GPIO terminals is insufficient for implementing various functions. This acts as a deterrent to efficient utilization of the MSM chip and the implementation of various functions of the terminal.

SUMMARY OF THE INVENTION The present invention is derived from such a background, and an object thereof is to provide a mobile communication terminal capable of converting PDM signals output from a terminal into a plurality of GPIO outputs.

Furthermore, the present invention is to provide a mobile communication terminal that can use a plurality of GPIO outputs with the addition of simple components.

Furthermore, an object of the present invention is to propose a system architecture that enables unified and systematic control between components in a terminal.

A mobile communication terminal according to an aspect of the present invention for achieving the above object is to divide the PDM output voltage output from the MSM of the terminal into a plurality of stages so that each outputs a different STATE. The PDM signal output from the MSM chip is converted into a continuous voltage level, that is, a DC voltage level, using an RC filter. The converted DC voltage is output to the input terminal of the signal conversion unit according to the present invention. The signal converter outputs a plurality of GPIO signals, that is, digital logic values composed of '0' and '1' according to the level of the input DC voltage. Therefore, it is possible to convert two digital logic values by outputting the voltage of one PDM signal. The digital logic value thus converted is output to each external component provided in the terminal.

According to this aspect of the present invention, the control signal output to the components of the new function to be implemented in the terminal is implemented, so that it is possible to maintain the same degree as the existing MSM without having to replace or improve the MSM chip of the main body. For example, there is an advantage that can be applied to a variety of models, such as GSM, CDMA, cellular, and even a variety of models.

Furthermore, according to a characteristic aspect of the present invention, the signal converter and the RC filter of the mobile communication terminal according to the present invention may be packaged into one IC chip, and may be extended by connecting a plurality of IC chips in parallel.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

1 is a block diagram schematically illustrating a mobile communication terminal according to an exemplary embodiment of the present invention. As shown, a mobile communication terminal according to an embodiment of the present invention includes an MSM chip 100, which is a configuration common to a conventional mobile communication terminal, and external components connected to GPIO terminals of the MSM chip 100. It is configured by. The external parts include a keypad 210 for receiving a user's operation command, a display unit 220 displaying an image signal read out according to a menu and operation state, and a control signal of a phone controller, a plurality of LEDs 230, and an antenna. A wireless communication unit 240 for extracting voice and data signals from a wireless signal transmitted / received through the voice signal, and a voice input / output circuit 250 for inputting / outputting a voice call signal from the wireless communication unit 240 through a microphone and a speaker; , A sound source playback chip such as a YAMAHA chip for ringtone playback, or a DSP chip for MP3 playback, and a voice playback unit 260 for reproducing and outputting from various sound sources such as ringtone, effect sound or music file playback, and a voice playback unit A voice output unit 270 for selectively outputting various reproduction sounds such as a ring tone or an effect sound in the terminal reproduced and output from the terminal 260 under the control of the MSM 100; It includes external components, such as the vibrator 280.

The keypad 210 and the display unit 220 which is a liquid crystal display device may have a conventional well-known configuration. In addition, the wireless communication unit 240 is configured to include an antenna and RF circuit for communication with the base station. In the present specification, the wireless communication unit 240 is interpreted to cover not only various versions of CDMA but also existing methods such as cellular, GSM, and W-CDMA, as well as mobile communication methods to be introduced in the future. The voice input / output circuit 250 is a well-known configuration which processes conversion of digital voice data into an analog voice signal or vice versa, and includes an additional circuit such as a voice amplifier circuit or a filter.

The baseband circuit of the wireless communication unit 240 and most of the circuits of the MSM 100 are commercially provided as a single integrated circuit. This integrated circuit, commonly referred to as MSM chip 100, includes dedicated hardware to process communications therein, a digital signal processor and a general purpose microprocessor. Logically, these include a communication control unit 110 for controlling voice and data communication, a system control unit 120 for controlling the entire system according to an operation signal or an operation state input from the keypad 210, and a plurality of external components. The control command, expressed as a bit value, is transmitted through a terminal called GPIO. The system controller 120 supports a convenient application environment, such as a virtual machine, and can process the control of various components according to a characteristic aspect of the present invention by a program.

The system controller 120 may interface with external ICs through the GPIO terminal to control them. When an operation command is input from the user through the operation unit or an event such as a call reception occurs, the system control unit 120 transmits the necessary control command to external components connected through the GPIO terminal.

The conventional MSM chip 100 includes a GPIO terminal for transmitting digital logic signals to a plurality of external components and a PDM terminal for controlling the external components at a continuous voltage level. According to a characteristic aspect of the present invention, the mobile communication terminal according to an embodiment of the present invention is an RC filter 300 for converting the PDM signal output from the PDM terminal of the MSM chip 100 into a continuous DC voltage signal, The apparatus may further include a signal converter 400 for converting and outputting a plurality of digital logic values according to the height of the DC voltage converted by the RC filter 300. The digital logic signal converted and output by the signal converter 400 is used as a control signal of the external components 290-1 and 290-2 additionally added to the mobile communication terminal.

2A is a block diagram schematically illustrating a signal converter according to an exemplary embodiment of the present invention. As shown, the signal converter 400 according to an embodiment of the present invention is 1 of the DC voltage value converted by using the voltage value converted by the RC filter 300 to a DC voltage having a continuous voltage level A first comparison unit for determining whether the / 2 value is a voltage higher than a predetermined reference voltage value and outputting TRUE if the value is large, and outputting FALSE if the input voltage value is low, and the RC filter 300. A second comparator for outputting a TRUE value when the DC voltage value converted by is higher than 1/4 of the input voltage value, and outputting FALSE when the input voltage value is a low value; From the third comparator, the second comparator and the third comparator to output a TRUE value when the DC voltage value is higher than 3/4 of the input voltage value, and output a FALSE value when the input voltage value is low. Any one of the input signal is output from the first comparison unit It further includes a switching unit for selectively outputting according to the output value.

The system controller 120 outputs a control signal of an external component in the form of a clock pulse according to a time ratio of a low and a high voltage of the voltage, that is, a duty cycle. When the PDM signal is output from the system control unit 120, the RC filter 300 converts the DC signal having a constant voltage level to the PDM signal and outputs the DC voltage. The RC filter 300 is composed of a resistor and a capacitor, and converts a signal such as a PDM signal, for example, a clock pulse, into a DC voltage by using a charge / discharge of the capacitor. The DC voltage converted and output by the RC filter 300 is output to the signal converter 400, and the signal converter 400 includes three comparators, and each comparator has a reference voltage value V _ref . Therefore, the input voltage is compared with the reference voltage (V _ref ) to output '1' (TRUE) or '0' (FALSE). The DC voltage converted and output by the RC filter 300 is converted into a digital signal of one bit through the first comparator and output.

The first comparator has a voltage value corresponding to 1/2 of the maximum voltage that can be output to the PDM output terminal of the MSM chip 100 as the reference voltage value V _ref . For example, when the maximum voltage V _max converted and output from the RC filter 300 is 8V, the first comparator has a value of 4V as the reference voltage V _ref . Therefore, when the value of 1/2 of the input voltage is greater than the reference voltage value (V _ref ) 4V, the value '1' (TRUE) is output, and when the value is smaller, the value '0' (FALSE) is output to the output terminal.

The second comparator has a voltage value corresponding to 1/4 of the maximum voltage that can be output to the PDM output terminal of the MSM chip 100 as the reference voltage value V _ref . For example, if the maximum voltage V _max converted and output from the RC filter 300 is 8V, the second comparator has a value of 2V as the reference voltage V _ref . Therefore, when the 1/4 value of the input voltage is greater than the reference voltage value (V _ref ) 2V, the value '1' (TRUE) is output and when the value is small, the value '0' (FALSE) is output to the output terminal.

The third comparator has a voltage value corresponding to three quarters of the maximum voltage that can be output to the PDM output terminal of the MSM chip 100 as the reference voltage value V _ref . For example, if the maximum voltage V _max converted and output from the RC filter 300 is 8V, the third comparator has a value of 6V as the reference voltage V _ref . Therefore, when the value of 3/4 of the input voltage is greater than the reference voltage value (V _ref ) 6V, the value '1' (TRUE) is output, and when the value is small, '0' (FALSE) is output to the output terminal.

The switching unit is, for example, an electronic switching circuit such as a 2x1 multiplexer which selectively outputs one of two input signals, and is output from the second comparing unit or the third comparing unit according to the digital signal output from the first comparing unit. Selectively outputs one of the one-bit digital signals. When the one-bit digital signal output from the first comparator is '0', for example, when the 4 V input voltage is applied to the signal converter 400, the first comparator is output to the output terminal. Output 1 '. Since the reference voltage V _ref of the second comparator is 2V, '1' is output to the output terminal of the second comparator, and the reference voltage V _ref of the third comparator is 6V, so '0' is switched to the output terminal of the third comparator. Output as negative. The switching unit outputs a '0' value input from the third comparing unit to the output terminal according to the digital signal output from the first comparing unit.

Therefore, since '1' output from the first comparator and '0' output from the switching unit are output, a control signal can be transmitted to two external components using one PDM signal. FIG. 2B is a truth table showing the output value of the signal converter 400 shown in FIG. 2A. As described above, a single PDM signal may be used to convert a GPIO signal having a 2-bit output and four states.

3A is a block diagram schematically illustrating an extended signal converter according to another embodiment of the present invention. As shown, the signal converter 400 of the mobile communication terminal according to the present invention may convert one PDM signal into three digital logic signals and output the same. The signal converter 400 according to another embodiment of the present invention outputs a 2-bit digital signal having four states according to a voltage value converted by the RC filter 300 into a DC voltage having a continuous voltage level. And a first signal converter 400-1, and according to a characteristic aspect of the present invention, 1/8, 3/8, 5 / of the maximum voltage V _max converted from the RC filter 300 and output. Fourth, fifth, sixth, seventh comparators 450, 460, 470, and 480 having reference voltage values corresponding to eight, seventh, eighth, seventh, eighth, and seventh comparators; And a second signal conversion unit 400-2 including a second switching unit 490 for selectively outputting a '1' (TRUE) or a '0' (FALSE) value respectively output from 480. Can be.

Since the operations of the fourth, fifth, sixth and seventh comparators 450, 460, 470, and 480 are output through the same operations as the first, second, and third comparators 410, 420, and 430, the digital signals are output. The detailed description is omitted. For example, the second switching unit 490 may be implemented as a 4X1 multiplexer. The second switching unit 490 may receive a 2-bit digital signal output by the first signal conversion unit 400-1 and may be configured as a fourth, fifth, sixth, seventh embodiment. The digital signals output from the comparators 450, 460, 470, and 480 are selectively output. Referring to the operation of the second switching unit 490 by way of example, when the two-bit digital signal output by the first signal converter 400-1 is '0', '0' fourth comparison unit 450, output of the fifth comparator 460 for '0' and '1', output for the sixth comparator 470 for '1' and '0', '1', '1' ', The output of the seventh comparator 480 is selected and output. Therefore, by adding a circuit consisting of a simple comparator and a switching device to the two output terminals of the signal converter 400 described with reference to FIG. 2A, a 3-bit digital signal can be output through one PDM signal.

FIG. 3B is a truth table showing the output value of the signal converter shown in FIG. 3A. As described above, a single PDM signal may be used to convert a 3-bit digital signal into a GPIO signal having eight states.

4A is a circuit diagram illustrating a signal conversion circuit according to another embodiment of the present invention. As shown, the signal conversion circuit 500 according to the present invention is separately applied to the control power supply terminal 510 supplied with a voltage that is converted into a DC voltage by the RC filter 300 and outputted to drive the circuit. The driving power terminal 520, the first voltage divider 530 that distributes the input voltage supplied from the control power terminal at a predetermined ratio, and the driving power terminal 520 according to the voltage distributed from the first voltage divider 530. The first output unit 540 for selectively outputting the driving voltage applied through) and the input power supplied from the control power terminal 510 at a predetermined ratio, but the voltage value output according to the switching operation of the transistor The second voltage divider 550 to control the second and the second output unit 560 for selectively outputting the driving voltage applied through the driving power terminal 520 according to the voltage distributed from the second voltage divider 550 Include.

The control power supply terminal 510 is supplied with a voltage that is converted into a DC voltage by the RC filter 300 and the PDM signal output from the output MSM chip 100 is converted into a DC voltage by the RC filter 300 and output. . The first voltage divider 530 uses a first resistor R1 and a second resistor R1 as a DC voltage input to supply a driving voltage, that is, a point for driving the first transistor Q1 ON / OFF. And the voltage applied to the second resistor R1 is output to the first transistor Q1.

For example, when the input voltage VS input from the control power supply terminal 510 is 1.4 V, and the value of the first resistor R1 and the second resistor R2 has the same value as 1 ㏀, two resistors ( The voltages applied to R1 and R2 are equal to 0.7V, and the first voltage divider 530 outputs a voltage of 0.7V applied to the second resistor R2 to the first output unit 540. The first output unit 540 receives a voltage output from the first voltage divider 530 and drives ON / OFF to selectively switch a voltage applied from a driving power supply terminal, and a first transistor. And a first load resistor RL1 for outputting a voltage input from the driving terminal according to the driving of Q1. For example, assuming that the operating voltage of the general transistor, that is, the starting voltage is 0.7V, when the voltage applied to the base of the first transistor Q1 through the first power divider 530 is 0.7V, the first transistor Q1 is driven ON to cause the driving voltage applied from the driving power supply terminal connected to the collector to be applied to the emitter. Therefore, no voltage is applied to the first load resistor RL1 from the driving power supply terminal 520.

On the contrary, when the voltage applied to the base of the first transistor Q1 is less than 0.7 V, the first transistor Q1 is not driven, and therefore, all of the driving voltages output from the driving power supply terminal 520 are connected to the collector. It is applied to the resistor RL1. Therefore, when the input voltage output from the voltage control power supply terminal 510 is less than 0V to 1.4V, the first output unit 540 uses the driving voltage input from the driving power supply terminal 520 as the first load resistor. When the output voltage is 1.4 V or more, the first transistor Q1 is operated so that no driving voltage is applied to the first load resistor RL1.

The second output unit 560 also includes a second voltage divider 550 that can determine a point for turning on / off the second transistor Q2 implemented in the output unit. The fourth resistor R4 operates the first resistor R1 of the first voltage divider 530, and the fourth and fifth resistors R4 and R5 and the second transistor Q2 are connected to the second resistor R1. R2), and the sixth and seventh resistors R6 and R7 turn ON / OFF the second transistor Q2. When the second transistor Q2 is OFF, only the fifth resistor R5 serves as the second resistor R2. When the second transistor Q2 is ON, the fifth and eighth resistors R5 and R8 are used. These are connected in parallel to play the role of the second resistor (R2) and as a result the point is changed according to the state of the voltage divider circuit consisting of the combination with the fourth resistor (R4). Basically, if the second transistor Q2 is not turned on / off, the third transistor Q3 controls the power applied to the second load resistor RL2 only once as in the case of the first transistor Q1, but the second transistor Since Q2 is turned on / off by the sixth and seventh resistors R6 and R7, the third transistor Q3 passes through three ON / OFFs, thereby obtaining outputs having four different states.

FIG. 4B is a graph showing output voltages output from two load resistors of the signal conversion circuit shown in FIG. 4A. As described above, one PDM signal may be converted into a DC voltage through an RC filter and output, and an output having four states may be generated using the output DC voltage. Therefore, two bits of digital signals can be generated by encoding the four states.

As described in detail above, the mobile communication terminal according to the present invention converts the PDM signals output from the PDM output terminal of the MSM chip in the terminal into a plurality of GPIO control signals and outputs the number of GPIO terminals supported by the MSM chip of the mobile communication terminal. It has the effect of adding additional functions without limitation.

In addition, the signal conversion unit is packaged in a single IC chip, which has the effect of easy expansion.                     

In addition, since the control of external components that perform complex and various functions can be uniformly performed, system design, function addition, and design change can be easily performed.

The present invention has been described above with reference to preferred embodiments, but is not limited thereto, and is interpreted by the appended claims, which are intended to cover many modifications that will be apparent to those skilled in the art without departing from the scope of the present invention. Should be done.

Claims (5)

delete In the mobile communication terminal, An MSM chip having a plurality of General Purpose Input Output (GPIO) and Pulse Duration Modulation (PDM) terminals; An RC filter converting the PDM signal output from the PDM terminal into a continuous DC voltage value; It is determined whether the 1/2 value of the DC voltage value converted by the RC filter is at a level higher than a predetermined reference voltage value, and TRUE is output when the value is large, and FALSE is output when the input voltage value is low. With the first comparison part to say, A second comparison unit outputting a TRUE value when the DC voltage value converted by the RC filter is higher than 1/4 of an input voltage value, and outputting FALSE when the input voltage value is low;  A third comparison unit outputting a TRUE value when the DC voltage value converted by the RC filter is higher than 3/4 of an input voltage value, and outputting a FALSE value when the input voltage value is low; A signal conversion unit including a switching unit for selectively outputting any one of signals input from the second comparison unit and the third comparison unit according to an output value output from the first comparison unit; Mobile communication terminal comprising a. The mobile communication terminal of claim 2, wherein the RC filter and the signal converter are configured as a single integrated circuit. An RC filter which receives the PDM signal and converts the DC signal into a DC voltage having a continuous voltage; A signal conversion circuit comprising a signal conversion circuit for converting the DC voltage converted by the RC filter into a plurality of GPIO signals and outputting the signal conversion circuit, the signal conversion circuit comprising: A control power supply terminal receiving the DC voltage converted by the RC filter; A driving power supply terminal for supplying driving power to the signal conversion circuit; A first voltage divider for dividing and outputting the DC voltage output from the control power terminal at a predetermined ratio; A first output unit selectively outputting a voltage applied from the control power terminal according to a voltage value distributed and output by the first voltage divider; A second voltage divider for dividing and outputting the DC voltage output from the control power terminal at a predetermined ratio; A second output unit selectively outputting a voltage applied from the control power supply terminal according to a voltage value distributed and output by the second voltage divider; Signal conversion apparatus comprising a. The apparatus of claim 4, wherein the first voltage divider is: A first resistor having one end connected to the control power terminal; An end connected to the other end of the first resistor, the second end of the second resistor being grounded; The first output unit: A third resistor having one end connected to the driving power terminal; A first transistor having a collector connected to the other end of the third resistor, a base connected to a node to which the first resistor and a second resistor are connected, and an emitter connected to ground; A first load resistor having one end connected to a node to which the collector and the third resistor of the first transistor are connected, the other end of which is grounded; The second voltage divider is: A fourth resistor having one end connected to the control power terminal; A fifth resistor having one end connected to the other end of the fourth resistor and having the other end grounded; A sixth resistor having one end connected to a node connected to the fourth resistor and a control power supply terminal; A seventh resistor having one end connected to the other end of the sixth resistor and having the other end grounded; An eighth resistor having one end connected to a node to which the fourth and fifth resistors are connected; A collector connected to the other end of the eighth resistor, a base connected to a node to which the sixth and seventh resistors are connected, and a second transistor to which the emitter is grounded; The second output unit: A ninth resistor having one end connected to a node connected to the driving power terminal and a third resistor; A third transistor having a collector connected to the other end of the ninth resistor, a base connected to a node to which fourth, fifth, and eight resistors are connected, and an emitter grounded; A second load resistor having one end connected to a node connected to the collector of the ninth resistor and the third transistor, the other end of which is grounded; Signal conversion device characterized in that.

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