KR20140022327A - Method for preventing abnormal operation in an electronic device - Google Patents

Abstract

The present invention relates to a device for preventing an electronic device from malfunctioning due to an abnormal control signal generated when a battery is mounted and a method thereof. The method for preventing an electronic device from malfunctioning when a battery is mounted using a stabilization module includes: a step of blocking a control signal from a first module generated within a certain period of time after the battery is mounted not to be delivered to a second module; and a step of delivering a control signal from the first module generated after a certain period of time only to the second module. [Reference numerals] (100) Power supply unit; (102) First module; (104) Stabilization module; (106) Second module

Description

Electronic device and method for preventing malfunction when battery is installed {METHOD FOR PREVENTING ABNORMAL OPERATION IN AN ELECTRONIC DEVICE}

The present invention relates to an apparatus and a method for preventing an electronic device from malfunctioning by an abnormal control signal generated when a battery is mounted.

Recently, electronic devices such as portable terminals are indispensable for modern people, regardless of age or gender, and service providers and manufacturers of electronic devices are competitively developing products (or services) to differentiate themselves from other companies. .

For example, the electronic device has developed into a multimedia device capable of a phone book, a game, a short message, an e-mail, a wake-up call, an MP3, a schedule management function, a multimedia message, and a wireless Internet service, and provides various services.

In general, the electronic device operates by receiving power from a power supply means called a battery.

However, abnormalities caused by batteries are often occurring in the electronic device.

As one of the abnormalities, when a battery is mounted in the electronic device, an abnormal control signal may be generated before a normal booting process is completed and a specific function may be executed.

In detail, when the battery is mounted in the electronic device, a booting process is performed with power supplied from the battery, and the electronic device operates under the control of the processor after the booting process is completed.

However, when a battery is mounted in the electronic device, an abnormal control signal occurs intermittently in the processor.

For example, the processor and the plurality of modules (camera module, media playback module, etc.) of the electronic device generate a control signal after completing the booting process.

However, after the battery is installed in the electronic device, power of the battery may be applied to each module before the booting process is completed, and an unintended control signal may be transmitted to another module through an interface. This control signal may be the abnormal control signal described above.

An example of an abnormal control signal may be a situation in which a flash of a camera is emitted when a battery is mounted in the electronic device. This provides the flash module with an abnormal control signal for supplying power from the battery to the processor and causing the processor to emit flash.

Accordingly, in order to solve the above problems, an apparatus and method for preventing a malfunction from occurring due to an abnormal control signal generated when a battery is mounted in an electronic device are required.

The present invention was derived to solve the above problems, and an object of the present invention is to provide an apparatus and method for preventing a malfunction from occurring due to an abnormal control signal generated when a battery is mounted in an electronic device.

Another object of the present invention is to provide an apparatus and method for blocking a control signal transmitted to a module when a battery is mounted in an electronic device.

Another object of the present invention is to provide a stabilization module configured to block output of a control signal for a predetermined time by configuring a resistor, a capacitor, and an AND gate (or NAND) in order to prevent malfunction of the electronic device.

According to a first aspect of the present invention for achieving the above objects, a method for preventing a malfunction occurring when the battery is mounted in the stabilization module of the electronic device includes a control signal of the first module generated within a predetermined time after the battery is mounted; Blocking transmission to the module, and transmitting only to the control signal of the first module generated after a certain time to the second module.

Preferably, the process of blocking transmission of the control signal of the first module generated within a predetermined time after the battery is transmitted to the second module includes inputting the first signal to the transmitter for a predetermined time, wherein the first signal Denotes a signal for blocking abnormal control signals from being transmitted to the second module.

Preferably, the process of blocking transmission of the control signal of the first module generated within a predetermined time after the battery is transmitted to the second module is performed by inputting the first signal to the transmitter for a predetermined time and then sending the second signal to the transmitter. Including the input process, wherein the second signal is characterized in that a signal for ensuring that the control signal is transmitted to the second module.

Preferably, the step of inputting the first signal to the transmitter during the predetermined time period is a process of inputting the first signal to the transmitter while the resistor and the capacitor are charged by supplying power to a delay composed of a resistor and a capacitor. .

Preferably, the step of transmitting only the control signal of the first module generated after the predetermined time to the second module transmits the control signal input to the transmitter to the second module in a situation in which the second signal is input from the delay unit. Characterized in that the transmission process.

Preferably, the step of blocking the transmission of the control signal of the first module generated within a predetermined time after the battery is transmitted to the second module is characterized in that it comprises the step of shutting off the power supply to the transmitter for a predetermined time.

According to a second aspect of the present invention for achieving the above objects, the stabilization module for preventing malfunction when the battery is mounted is that the control signal of the first module generated within a predetermined time after the battery is transmitted to the second module It characterized in that it comprises a transmitter for blocking and transmitting only to the control signal of the first module generated after a certain time to the second module.

Preferably, the stabilization module includes a delay for inputting the first signal to the transmitter for a predetermined time, wherein the first signal means a signal that blocks abnormal control signals from being transmitted to the second module. .

Preferably, the delayer inputs a first signal to the transmitter for a predetermined time, and then inputs a second signal to the transmitter, wherein the second signal is a signal for ensuring that a control signal is transmitted to the second module. It means to mean.

Preferably, the retarder supplies power to a retarder consisting of a resistor and a capacitor to input the first signal to the transmitter while the resistor and the capacitor are being charged.

Preferably, the transmitter transmits a control signal input to the transmitter to the second module when a second signal is input from the delay unit.

Preferably, the stabilization module further comprises a power supply circuit for shutting off power supply to the transmitter for a predetermined time.

According to a third aspect of the present invention for achieving the above objects, a device for preventing malfunction when the battery is mounted is composed of a resistor and a capacitor to output a different signal according to the charge amount of the capacitor, AND gate It characterized in that it comprises a transmitter for controlling the output of the control signal using the signal output from the delay and the control signal received from the module.

Preferably, the capacitor of the retarder is characterized in that the output of the low signal to the transmitter for a predetermined time after the battery is installed to block the output of the control signal.

Preferably, the transmitter is configured using at least one of a field effect transistor, a transistor, and a switching element.

As described above, the present invention prevents the control signal generated after the battery is stabilized (before the predetermined time has elapsed) from being transmitted to the module for a predetermined time, thereby preventing abnormal control signals generated when the battery is mounted on the electronic device. The malfunction can be prevented from occurring.

1 is a block diagram illustrating a configuration of an electronic device for processing an abnormal control signal generated when a battery is mounted according to the present invention;
2 shows a functional block of a stabilization module according to the invention,
3 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is installed according to an exemplary embodiment of the present disclosure.
4 is a view illustrating an operation process of a stabilization module according to an embodiment of the present invention;
FIG. 5 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is installed, according to another exemplary embodiment of the present disclosure; FIG.
6 illustrates a method for designing a stabilization module according to the present invention;
FIG. 7 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is installed, according to another exemplary embodiment of the present disclosure; FIG.
8 is a flowchart illustrating an operation process of a stabilization module according to the present invention;
9 is a view showing an operation of the stabilization module according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In the following description, an apparatus for preventing a control signal from being transmitted to another module for a predetermined time after a battery is installed in order to prevent a malfunction caused by an abnormal control signal generated when a battery is mounted in an electronic device according to the present invention; The method will be described.

In addition, the electronic device may be a portable electronic device and may be a portable terminal, a mobile phone, a media player, a tablet computer, a handheld computer a handheld computer, or a PDA (Personal Digital Assistant). It may also be any portable electronic device, including devices combining two or more of these devices.

In addition, the module is a module for controlling the operation of the electronic device, and may be a hardware configuration of a processor, a camera unit, an input unit, and a display unit. In addition, the module may be a program for operation of the hardware configuration.

1 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is mounted according to the present invention.

Referring to FIG. 1, the electronic device may include a power supply unit 100, a first module 102, a stabilization module 104, and a second module 106.

First, the first module 102 and the second module 106 refer to a module for controlling the operation of the electronic device. That is, the first module 102 may be an application processor (AP), and the second module 106 operates according to a control signal of the first module 102 (eg, a camera module). , Flash module, input unit, display unit, etc.).

When the battery is mounted, the power supply unit 100 supplies power to the module of the electronic device to process a boot process for normal operation. In this case, the power supply unit 100 may have a structure in which the battery may be mounted or detached. Of course, the power supply unit 100 may supply power to a module of the electronic device using an external power source in addition to a battery.

In general, a processor (first module) supplied with power from the power supply unit 100 performs a booting process using a boot program stored in a storage area, and then receives a control signal of a processor using a control signal. Operate the (second module).

However, before the booting process of the electronic device is completed, power is supplied to each module by a battery installed in the power supply unit 100, and the module supplied with power generates an abnormal control signal and abnormally causes another module to abnormally occur. The situation arises.

For example, when power is supplied to the processor by installing the battery, the processor of the electronic device generates an abnormal operation of generating a control signal for emitting the camera flash before the boot process is completed and delivering the control signal to the corresponding module.

Accordingly, the module receiving the control signal generated by the abnormal operation does not determine the abnormal control signal and causes the flash to emit light according to the received control signal.

In order to solve the above problems, the electronic device according to the present invention includes a stabilization module 104 between each module to prevent abnormal control signals from being transmitted to other modules.

For the detailed description, the first module 102 is defined as a processor and the second module 106 is defined as a flash module.

First, when power is suddenly supplied by the battery mounting, an abnormal control signal for controlling the operation of the second module 106 in the first module 104 may occur. Of course, the abnormal control signal is described as an example of a control signal for emitting a flash, but may be a control signal for controlling the operation of at least one of the functions operable by the second module 106. .

The abnormal control signal of the first module 102 generated as described above is not directly transmitted to the second module 106 but is transmitted to the stabilization module 102 according to the present invention.

The stabilization module 104 operates with power supplied from the power supply unit 100, and the control module received from the first module 102 for a predetermined time after the initial power is supplied to the second module 106. Do not pass to.

Here, since the abnormal control signal may be generated in each module before the boot process of the electronic device is completed, the stabilization module 104 performs the first module 102 for a time until the boot process is completed. May not be transmitted to the second module 106.

The stabilization module 104 performing such an operation may include a delayer for preventing abnormal control signals from being transmitted to another module and a transmitter for transmitting normal control signals to other modules.

In addition, the stabilization module 104 may be configured using logic gates, transistors, switches, field effect transistors, and the like.

For example, the stabilization module 104 may be configured using an AND gate.

The AND gate determines output using two inputs, and may be implemented to receive a control signal of the first module 102 and a power supply signal of the power supply unit 100.

When the stabilization module 104 of such a structure generates an abnormal control signal and a power supply signal at the same time, the abnormal control signal cannot be directly transmitted to the second module 106 to solve the problems of the prior art. This is because the control signal and the supply signal are generated because a high signal is input to two input terminals of an AND gate, and the AND gate outputs a high signal so that the second module can be controlled.

If a low signal is input to at least one input terminal of the AND gate for a predetermined time after the battery is mounted, the AND gate will output a low signal, and thus the second module will not be controlled.

Accordingly, according to the present invention, the stabilization module 104 may process the AND gate to output a signal having a predetermined state for a predetermined time by using a resistor and a capacitor. That is, the stabilization module 104 prevents the other module from being controlled by an abnormal control signal by outputting a low signal through the AND gate for a predetermined time after the battery is mounted.

In order to enable such an operation, the power supply unit 100 may be connected in series with a resistor and a capacitor, and may connect an AND gate input between the resistor and the capacitor.

Accordingly, when the first power is supplied, the power of the power supply unit 100 is not input to the AND gate, but is provided to the capacitor to charge the capacitor, and the AND gate is a low signal for a predetermined time while the capacitor is charged. Will be input. In addition, when the capacitor is fully charged, the AND gate will receive a high signal.

That is, as the first supplied power charges the resistor and the capacitor for a predetermined time, a low signal is inputted to the AND gate, and the AND gate receiving the low signal is supplied to the second module even if an abnormal control signal is generated. Low signal will be output. However, after a predetermined time has passed (after the resistor and the capacitor are charged), when the high signal is inputted to the AND gate to generate a control signal in the first module, the high signal is output in the second module. That is, the AND gate blocks the transmission of the control signal during the time when the input of the low signal is guaranteed and serves as a buffer for transmitting the control signal during the time when the input of the high signal is guaranteed.

In summary, the transmitter of the stabilization module 104 described above may be an AND gate, and the delay may be a resistor and a capacitor.

In addition, the stabilization module 104 is to prevent the control signal from being provided to another module for a predetermined time after the initial power is supplied. In one embodiment of the present invention, an AND gate is used. Circuits having these characteristics may be designed using various logic gates, FETs, transistors, switches, and the like.

In FIG. 1, an AND gate (transmitter) outputs a signal of a predetermined state for a predetermined time when a battery is mounted using a signal of a delay circuit (delay) using a resistor and a capacitor to block abnormal output of a control signal. The method to make it described was demonstrated.

Of course, when the NAND gate is used instead of the AND gate in FIG. 1, when the battery is mounted, the NAND gate (transmitter) may output the signal High in a predetermined state to block abnormal output of the control signal.

In addition, the present invention implements a power supply circuit using a resistor and a capacitor to block the abnormal control signal from being output to another module by not supplying power to the AND gate or the NADN gate for a predetermined time when the battery is mounted. Gate or NADN gate is disabled). This configuration will be described with reference to FIG. 9.

2 is a diagram illustrating a functional block of a stabilization module according to the present invention.

Referring to FIG. 2, the stabilization module may include a delay and a transmitter.

First, the delay unit 201 may be a kind of timer for preventing abnormal control signals from being transmitted to other modules. In addition, the transmitter 203 refers to a device for transmitting a normal control signal to another module.

As described above, the delay unit 201 and the transmitter 203 process not to output the control signal provided from the module for a predetermined time. This is because a signal is input to the transmitter 203 such that the operation of the second module is not controlled by the delayer 201.

Such an operation may implement a circuit, and the elements constituting the circuit and the arrangement of the elements may be implemented in various ways.

For example, the stabilization module may enable a timer operation using a resistor and a capacitor, and may enable a transmitter operation using a logic gate, a transistor, a switch, a field effect transistor, or the like.

Of course, in the foregoing description, the low signal is output to another module for a predetermined time after the battery is installed by using the AND gate. However, the stabilization module may process the high signal to be transmitted to another module for a predetermined time after the battery is installed by using the NAND gate. Can be. This can be an embodiment indicating that the stabilization module can be implemented in various ways by those skilled in the art.

Such a stabilization module may be located between the input and output interfaces of the module.

3 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is installed, according to an exemplary embodiment of the present disclosure.

Referring to FIG. 3, the electronic device may include a first module, a stabilization module 104, and a second module. In addition, although not shown, the electronic device may include a power supply unit to process power to each module (first module, second module) and stabilization module 104.

First, the first module and the second module refer to modules for controlling the operation of the electronic device. That is, the first module may be an application processor (AP), and the second module may be a module (eg, a camera module, a flash module, an input unit, a display unit, etc.) operating according to a control signal of the first module. This can be

In general, the power supply means a battery that is detached or mounted. When the battery is mounted, an abnormal control signal may be generated for at least one module. Here, the abnormal control signal refers to a control signal generated by a sudden power supply, which is not intended by the electronic device.

When such a control signal is transmitted to another module through an input / output interface, a problem occurs that an unintended function of the electronic device is executed by a module receiving the control signal.

In order to solve the above problems, the stabilization module 104 according to the present invention prevents an abnormal control signal from being transferred to another module.

The stabilization module 104 may be composed of a resistor 301, a capacitor 312, and an AND gate 314 according to an exemplary embodiment of the present invention.

In this case, the resistor 310 and the capacitor 312 are connected in series with a power supply, and the input of the AND gate 314 is connected between the first module and the resistor 310 and the capacitor 312.

In addition, the output of the AND gate 314 is provided to the second module. Of course, the first module and the second module may include an input / output interface.

As shown in FIG. 3, power is supplied to the first module and the stabilization module 104 when a battery is mounted in the electronic device, and the first module is abnormally controlled by the supplied power. Is assumed to occur.

The abnormal control signal 300 of the first module is generated when the electronic device is not intended, but is provided to the stabilization module 104 through an input / output interface.

When the abnormal control signal 300 received by the stabilization module 104 is directly provided to the second module, the second module performs an operation on the control signal, but this becomes an abnormal operation not intended by the electronic device.

In order to prevent such a problem from occurring, the stabilization module 104 according to the present invention controls the power supplied when the first power is supplied, thereby preventing the abnormal control signal 300 from being provided to the second module.

That is, power supplied to the stabilization module 104 may be supplied to the capacitor 312 through the resistor 310. The resistor 310 and the capacitor 312 are charged by the supplied power, and a low signal is input to the input terminal of the AND gate 314 while the capacitor 312 and the resistor 310 are charged. Here, the low signal means a signal that blocks the front end of the second module by the control signal.

The time at which the low signal is input to the input terminal of the AND gate 314 is determined according to the capacitance of the resistor 310 and the capacitor 312, and the stabilization circuit provides an abnormal control signal to the second module during this time. Block it.

In other words, the stabilization module 104 inputs a signal (eg, a low signal) to the AND gate 314 that blocks abnormal control signals from being transmitted to the second module while the capacitor 312 is being charged. In addition, the stabilization module 104 inputs a signal (eg, a high signal) to the AND gate 314 to ensure that a control signal is transmitted to the second module after the capacitor 312 is charged. .

The AND gate 314 provides a control signal transmitted by the first module to the second module.

In this case, the AND gate 314 receives two types of signals by a capacitor and a resistor. Here, the AND gate 314 receives a signal Low that blocks an abnormal control signal from being transmitted to the second module and a signal High to ensure that the control signal is transmitted to the second module. .

That is, the AND gate 314 outputs a low signal to the second module according to a low signal input for a predetermined time during which a battery power is charged with a capacitor and a resistor after the battery is mounted, thereby generating the low signal by the abnormal control signal. 2 Modules can be prevented from being controlled.

In addition, the AND gate 314 receives a high signal input after a predetermined time after the battery is mounted (after the capacitor and the resistor are charged by the battery's power source), and the first gate 314 receives the first signal. When the control signal is input from the module, the high signal is output to control the second module.

4 is a diagram illustrating an operation process of a stabilization module according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the stabilization module may be implemented using a resistor and a capacitor as described above.

Since the resistor and the capacitor are connected in series with the power supply unit, the resistor and the capacitor are charged with the same characteristics as the reference symbol (a) when the power is supplied.

Referring to reference numeral (a), it can be seen that the charging amount of the capacitor increases as the power supply time passes, which means that a predetermined time (TL) must pass for the predetermined amount (Th) to be charged.

That is, when the time τ 0 of supplying power to the capacitor is shorter than a predetermined time TL, a signal Low is input to block an abnormal control signal from being transmitted to another module to the AND gate, thereby generating an abnormal control signal. Even if the stabilization module outputs a signal (Low) so that the other module is not controlled (400).

On the other hand, if the time τ 0 of supplying power to the capacitor is longer than a predetermined time TL, a signal High to ensure that the control signal is transmitted to the other module is input to the AND gate, so that the stabilization module is another module. In step 410, a control signal High for controlling the signal is output. Here, the control signal generated before the capacitor is charged may be an abnormal control signal generated after the initial voltage is supplied. In addition, since the electronic device may perform a normal booting process during the time when the capacitor is charged, the control signal generated after the capacitor is charged may be a normal control signal.

FIG. 5 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is installed, according to another exemplary embodiment of the present disclosure.

Referring to FIG. 5, the electronic device may include a first module, a stabilization module, and a second module. In addition, although not shown, the electronic device may include a power supply unit to process power to each module and the stabilization module.

In addition, the stabilization module may be composed of a plurality of stabilization modules, each stabilization module may include both a delay and a transmitter. This is to enable bidirectional communication between the first module and the second module.

In general, the power supply unit may be mounted or detached from a battery, and when the battery is mounted, abnormal control signals may be simultaneously generated in the first module and the second module. Here, the abnormal control signal refers to a control signal generated by a sudden power supply, which is not intended by the electronic device.

When this situation occurs, the stabilization module processes the abnormal control signal generated in the first module by using the first stabilization module 510 and generates the second control module by using the second stabilization module 520. It can handle abnormal control signals.

That is, the abnormal control signal generated in the first module is transmitted to the first stabilization module 510, but the control signal is not transmitted to the second module while the delay device of the first stabilization module is in operation. Then, when the operation of the delay is completed, the control signal provided from the first module is transmitted to the second module.

In addition, the abnormal control signal generated in the second module is transmitted to the second stabilization module 520, but the control signal is not transmitted to the first module while the delay device of the second stabilization module is in operation. Thereafter, when the operation of the delay unit is completed, the control signal provided from the second module is transferred to the first module.

Here, when the delay is composed of a resistor and a capacitor, the operation of the delay means that the capacitor is charged, and the completion of the operation of the delay means that the capacitor is charged by a certain amount.

6 is a diagram illustrating a method for designing a stabilization module according to the present invention.

Referring to FIG. 6, the stabilization module prevents the control signal from being provided to another module for a predetermined time after the initial power is supplied.

The stabilization module having this characteristic can be implemented in a circuit, and can be implemented using a logic gate such as an AND gate or a NAND gate.

In addition, the stabilization module may block transmission of control signals provided from the module for a predetermined time by using a switch.

In addition, the stabilization module may block the control signal from being provided to another module for a predetermined time after the initial power is supplied using the field effect transistor or the transistor.

Of course, such a stabilization module can be implemented using a variety of elements in addition to the above-mentioned device, there may be a variety of ways that the stabilization module to block the control signal transmission between the modules.

FIG. 7 is a block diagram illustrating a configuration of an electronic device that processes an abnormal control signal generated when a battery is installed, according to another exemplary embodiment of the present disclosure.

Referring to FIG. 7, the electronic device may include a plurality of output modules 701, 703, a stabilization module 710, and a plurality of input modules 720, 722. In addition, although not shown, the electronic device may include a power supply unit to process power to each module and the stabilization module.

In addition, the stabilization module 710 may include one delayer 712 and a plurality of transmitters 714 and 716. In the above-described drawing, the delay module and the transmitter are included in each stabilization module. However, in order to determine a normal control signal, the delay unit and the transmitter may be implemented by only one delay unit, so that the output of the delay unit may be input to each transmitter.

That is, the first transmitter 714 receives the output of the first output module 701 and the output of the delayer 712 to transmit a control signal to the first input module 720.

In addition, the n-th transmitter 716 receives the output of the n-th output module 703 and the output of the delayer 712 to transmit a control signal to the n-th input module 722.

The stabilization module 710 can reduce the cost and size than the stabilization module having a delay depending on the number of transmitters.

8 is a flowchart illustrating an operation process of a stabilization module according to the present invention.

Referring to FIG. 8, the stabilization module is to prevent the control signal from being provided to another module for a predetermined time after the initial power is supplied. It is possible to determine whether an unintended control signal has occurred in the device.

In addition, the stabilization module determines that the control signal is an abnormal control signal generated at a predetermined time after the initial power is supplied.

The stabilization module for performing the above operation first checks whether the battery mounting signal is received in step 801 and then proceeds to step 803 to check whether the control signal is received from the module.

In operation 805, the stabilization module determines whether the booting process is completed.

Here, the completion of the booting process means that a predetermined time has passed after the battery is mounted in the electronic device.

In addition, the stabilization module may include a delay consisting of a resistor and a capacitor to determine whether the booting process is completed by using the time when the capacitor is charged.

For example, the stabilization module may define a time when the booting process is not completed until the capacitor is charged with the power supplied from the battery.

In addition, the stabilization module may define a time after the capacitor is charged with the power supplied from the battery as a time when the booting process is completed.

Because the stabilization module is configured as a logic gate as described above, the control signal can be provided to another module only when a control signal and a signal High for ensuring that the control signal is transmitted to another module are input. have. For this reason, the stabilization module may determine that the control signal is a normal signal when the capacitor is charged and a high (signal for ensuring that the control signal is transmitted to another module) is input to the logic gate. This is to prevent the control signal from being abnormally generated in the module when the battery is installed to another module.

That is, the stabilization module may determine that the booting process is completed when a signal High for ensuring that the control signal is transmitted to another module is input to the logic gate.

If it is determined in step 805 that the booting process is not completed, the stabilization module proceeds to step 809 and determines that an abnormal control signal has been input, and then proceeds to step 811 to block the control signal, and then, in step 805. Rerun the process.

On the other hand, if it is determined in step 805 that the booting process is completed, the stabilization module proceeds to step 807 to confirm that a normal control signal is input and processes it to transmit to the corresponding module.

The stabilization module that has performed the above operation ends the present algorithm.

9 is a view showing an operation of the stabilization module according to another embodiment of the present invention.

Referring to FIG. 9, the stabilization module includes a power supply circuit 901 and a transmitter 903 composed of a resistor and a capacitor as shown by reference numeral (a).

The transmitter 903 refers to a device for transmitting a normal control signal to another module, and the power supply circuit 901 refers to a circuit for controlling a power supply for the operation of the transmitter.

The resistor and the capacitor of the power supply circuit 901 are connected in series with the power supply, and are charged by the power supply. At this time, the charging amount of the capacitor increases as the power supply time passes, and a predetermined time TL must pass for the predetermined amount Th to be charged.

At this time, the power supply circuit 901 cuts off the power supply to the transmitter 903 as indicated by a reference numeral b when the time τ 0 when the power is supplied is shorter than the predetermined time TL.

Accordingly, the transmitter 903 that is not supplied with power does not output the control signal even when receiving the control signal (910).

In addition, when the power supply time τ0 is longer than the predetermined time TL, the power supply circuit 901 performs power supply to the transmitter 903 as shown by reference numeral c.

Accordingly, when the power supply transmitter 903 receives a control signal, the transmitter 903 may output the control signal to process another module to be controlled (920).

Here, the control signal generated before the power supply to the transmitter 903 may be an abnormal control signal generated after the initial voltage is supplied. In addition, a control signal generated after power is supplied to the transmitter 903 may be a normal control signal.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but is capable of various modifications within the scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

Reference Signs List 100: power supply 102: first module 104: stabilization module 106: second module

Claims (15)

In the stabilization module of the electronic device, a method for preventing malfunction when mounting the battery,
Blocking transmission of the control signal of the first module generated within a predetermined time after installing the battery to the second module;
And transmitting only the control signal of the first module generated after a predetermined time to the second module.
The method of claim 1,
The process of blocking transmission of the control signal of the first module generated within a predetermined time after installing the battery to the second module,
Including a process for inputting the first signal to the transmitter for a predetermined time,
The first signal means a signal for blocking abnormal control signal from being transmitted to the second module.
3. The method of claim 2,
The process of blocking transmission of the control signal of the first module generated within a predetermined time after installing the battery to the second module,
And after inputting the first signal to the transmitter for a predetermined time, inputting the second signal to the transmitter,
The second signal means a signal for ensuring that a control signal is transmitted to the second module.
3. The method of claim 2,
The process of inputting the first signal to the transmitter for the predetermined time,
And supplying a first signal to the transmitter while the resistor and the capacitor are being charged by supplying power to a delay consisting of a resistor and a capacitor.
The method of claim 1,
The process of transmitting only the control signal of the first module generated after the predetermined time to the second module,
And transmitting a control signal input to the transmitter to the second module when a second signal is input from the delay unit.
The method of claim 1,
The process of blocking transmission of the control signal of the first module generated within a predetermined time after installing the battery to the second module,
Cutting off the power supply to the transmitter for a period of time.
In the stabilization module to prevent malfunction when the battery is installed,
It includes a transmitter to block the control signal of the first module generated within a certain time after the battery is installed 2 to the second module, and to transmit only to the control signal of the first module generated after a certain time to the second module Stabilization module.
8. The method of claim 7,
The stabilization module,
Including a delay for inputting the first signal to the transmitter for a predetermined time,
The first signal is a stabilization module means a signal that blocks the transmission of the abnormal control signal to the second module.
The method of claim 8,
Wherein the delay comprises:
After the first signal is input to the transmitter for a predetermined time, the second signal is input to the transmitter,
The second signal is a stabilization module means a signal for ensuring that a control signal is transmitted to the second module.
The method of claim 8,
Wherein the delay comprises:
A stabilization module for supplying power to a delay consisting of a resistor and a capacitor to input the first signal to the transmitter while the resistor and the capacitor is charged.
8. The method of claim 7,
The transmitter comprises:
Stabilization module for transmitting a control signal input to the transmitter to the second module in a situation that the second signal is input from the delay.
8. The method of claim 7,
The stabilization module,
Stabilization module further comprising a power supply circuit for shutting off the power supply to the transmitter for a period of time.
In the device for preventing malfunction when the battery is installed,
A retarder configured of a resistor and a capacitor to output different signals according to the amount of charge of the capacitor,
And a transmitter configured as an AND gate to control the output of the control signal by using the signal output from the delay unit and the control signal received from the module.
14. The method of claim 13,
The capacitor of the retarder,
Device that blocks control signal output by outputting low signal to transmitter for a certain time after battery installation.
14. The method of claim 13,
The transmitter comprises:
Device that can be configured using at least one of a field effect transistor, a transistor, and a switching element.

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