KR20060106275A - Mobile communication terminal including battery and method for managing battery power - Google Patents

Abstract

The mobile communication terminal according to the present invention comprises a) an external signal generator for outputting a variable sleep mode signal according to a user's operation, b) modulating various digital signals into a baseband signal, an intermediate frequency signal, and a high frequency signal according to a predetermined standard. A transmitter for transmitting to the antenna, c) a receiver for demodulating the high frequency signal received through the antenna into an intermediate frequency signal, a low frequency signal and a digital signal according to a predetermined standard, d) a battery unit for supplying power to the transmitter and the receiver, e) a battery A power measurement unit for outputting a power measurement signal corresponding to a negative voltage level, f) a memory unit for storing sleep mode section information according to a voltage level, and g) a variable sleep mode signal is set to set a variable sleep mode and then a sleep mode section Set the sleep mode section corresponding to the voltage level detected through the power measurement signal using the information, and set the sleep mode section. It includes a central control unit for shutting off the power of the transmitter and the receiver. In addition, the battery power management method of the present invention comprises the steps of a) determining whether a normal sleep mode signal or a variable sleep mode signal is input, b) setting a variable sleep mode when a variable sleep mode signal is input, c) a battery Determining a negative current voltage level, d) setting a sleep mode section using previously stored sleep mode section information according to the current voltage level, and e) shutting off power to the transmitter and the receiver during the set sleep mode section It includes a step.

Description

Mobile Communication Terminal Including Battery and Method for Managing Battery Power

1 is a block diagram of a mobile communication terminal according to the present invention.

2 is a flowchart illustrating a method for managing battery power of a mobile communication terminal according to the present invention.

3 is a slot cycle index for a battery power management method of a mobile communication terminal according to the present invention.

Explanation of symbols on the main parts of the drawings

110: external signal forming unit 120: transmitter

130: receiver 140: duplexer

150: battery unit 160: power measurement unit

170: memory unit 180: central control unit

The present invention relates to a mobile communication terminal, and more particularly, to a mobile communication terminal including a battery and a battery management method of a mobile communication terminal.

In general, a CDMA mobile communication terminal uses a pilot channel for providing access to a base station and a sector of the largest signal from a CDMA mobile communication network, and a sync channel for providing a synchronization signal. (sync channel), a paging channel for receiving a call signal and control information from the base station (taging channel), and receives a traffic channel (traffic channel) for transmitting voice or data to perform voice communication or data communication.

That is, a general mobile communication terminal detects the largest signal in a mobile communication network through a pilot channel and selects a base station using a start time difference of a PN code for distinguishing each base station from each other, and then selects a sync channel. The synchronization signal is provided to achieve synchronization with the mobile communication network.

Thereafter, the mobile communication terminal is called from a base station through a slot of a paging channel to receive control information. At this time, the base station sets a sleep mode interval according to the slot cycle index (Slot Cycle Index) of the base station. As such, when the sleep mode section is set by the base station, the mobile communication terminal checks a paging channel for one frame for each sleep mode section set by the base station. That is, the mobile communication terminal checks the paging channel only for one frame between the sleep mode section and the sleep mode section and receives control information.

For this operation, the mobile communication terminal cuts off the power supplied to the wireless circuit in the sleep mode section and supplies power to the wireless circuit for one frame. Accordingly, the mobile communication terminal can reduce the power consumption of the battery.

At this time, the radio circuit unit includes a transmitter for modulating various baseband signals into high frequency signals according to a predetermined standard, and a receiver for demodulating high frequency signals received through an antenna into baseband signals according to a predetermined standard.

However, the conventional mobile communication terminal has a limitation in increasing the battery usage time because the power supply to the wireless circuit unit is cut off according to the sleep mode section set by the base station even when the voltage level of the battery drops.

The present invention is to solve the above problems, to provide a mobile communication terminal and a battery power management method that can change the sleep mode period according to the voltage level of the battery.

In order to achieve the above object, a mobile communication terminal according to the present invention comprises: a) an external signal generator for outputting a variable sleep mode signal according to a user's operation, b) a baseband signal and an intermediate frequency signal according to a predetermined standard. And a transmitter for modulating high frequency signals and transmitting them to an antenna, c) a receiver for demodulating high frequency signals received through the antenna into intermediate frequency signals, low frequency signals and digital signals according to a predetermined standard, and d) supplying power to the transmitter and receivers. A battery unit, e) a power measurement unit for outputting a power measurement signal corresponding to the voltage level of the battery unit, f) a memory unit for storing sleep mode section information according to the voltage level, and g) a variable sleep mode receiving a variable sleep mode signal And set the sleep mode section corresponding to the voltage level detected by the power measurement signal using the sleep mode section information. And a central controller configured to cut off power of the transmitter and the receiver during the set sleep mode period.

In addition, the battery power management method of the present invention comprises the steps of a) determining whether a normal sleep mode signal or a variable sleep mode signal is input, b) setting a variable sleep mode when a variable sleep mode signal is input, c) a battery Determining a negative current voltage level, d) setting a sleep mode section using previously stored sleep mode section information according to the current voltage level, and e) shutting off power to the transmitter and the receiver during the set sleep mode section It includes a step.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a mobile communication terminal according to the present invention. As shown in FIG. 1, the mobile communication terminal according to the present invention includes an external signal generator 110, a transmitter 120, a receiver 130, a duplexer 140, a battery unit 150, and a power measurement unit 160. , A memory unit 170 and a central control unit 180.

The external signal forming unit 110 includes a keypad for generating a key signal according to a user's manipulation and outputs a general sleep mode signal or a variable sleep mode signal.

The transmitter 120 modulates various digital signals in order of a baseband signal, an intermediate frequency signal, and a high frequency signal and transmits the digital signals to the antenna.

The receiver 130 demodulates the high frequency signal received through the antenna into an intermediate frequency signal, a low frequency signal, and a digital signal according to a predetermined standard.

The duplexer 140 branches the transmitter 120 and the receiver 130 while using one antenna.

The battery unit 150 supplies power for driving the entire mobile communication terminal, and in particular, supplies power for driving the transmitter 120 and the receiver 130.

The power measurement unit 160 includes an analog to digital converter (ADC) to convert an analog signal corresponding to the voltage level of the battery unit 150 into a digital signal and output a power measurement signal.

The memory unit 170 stores data, an OS program, and various application programs for driving the mobile communication terminal. In particular, the memory unit 170 stores sleep mode section information according to a voltage level. In this case, the sleep mode section information is a slot cycle index to which the sleep mode section is assigned according to the voltage level, or the change sleep mode section, which is a reference voltage level and one fixed value.

The central controller 180 performs a call processing according to the CDMA protocol to output a digital signal to the transmitter 120 or to process the digital signal input from the receiver 130. In particular, the central controller 180 sets the normal sleep mode or the variable sleep mode according to the normal sleep mode signal or the variable sleep mode signal received from the external signal forming unit 110. At this time, if the central control unit 180 sets the normal sleep mode, the power supply to the transmitter 120 and the receiver 130 is cut off during the sleep mode period set by the base station. In addition, when the central control unit 180 sets the variable sleep mode, the current voltage level is determined by the power measurement signal input from the power measuring unit 160 to determine the sleep mode section using the sleep mode section information of the memory unit 170. Set it.

At this time, the central controller 180 sets the sleep mode section according to the current voltage level according to the slot cycle index stored in the memory unit 170 and the power supplied to the transmitter 120 and the receiver 130 in the set sleep mode section. To block.

In addition to the above method, the central controller 180 compares the current voltage level with the reference voltage level stored in the memory unit 170 and stores the sleep mode section in the memory unit 170 when the current voltage level is smaller than the reference voltage level. It sets to the change sleep mode section and cuts off the power supplied to the transmitter 120 and the receiver 130 in the set sleep mode section.

Reference numeral 190 decodes the data packet as a vocoder, outputs it to a PCM codec (not shown) as a PCM (pulse code modulation) voice data sample, converts it into an analog voice signal, and outputs it to a speaker, a microphone and a PCM codec PCM voice data samples are formed from the user's voice signal input through (not shown).

Next, a battery power management method of a mobile communication terminal according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a flowchart illustrating a method for managing battery power of a mobile communication terminal according to the present invention.

The central controller 180 determines whether the normal sleep mode signal or the variable sleep mode signal is input from the external signal forming unit 110 (S210).

When the variable sleep mode signal is input from the external signal forming unit 110, the central controller 180 sets the variable sleep mode (S220).

The central controller 180 receives the power measurement signal from the power measuring unit 160 to determine the current voltage level of the battery unit 150 (S230).

The central controller 180 extracts and sets the sleep mode section corresponding to the current voltage level from the slot cycle index which is the sleep mode section information stored in the memory unit 170 (S240). At this time, the slot cycle index used in the present invention represents a change value of the sleep mode section according to the voltage level.

The central controller 180 cuts off the power supplied to the transmitter 120 and the receiver 130 during the set sleep mode period (S250).

Thereafter, when the set sleep mode period elapses, the central controller 180 supplies power to the transmitter 120 and the receiver 130 for one frame (S260).

On the other hand, when the normal sleep mode signal is input from the external signal forming unit 110 in S210, the central control unit 180 sets the normal sleep mode (S270).

When the central control unit 180 sets the normal sleep mode, the power supply to the transmitter 120 and the receiver 130 is cut off during the sleep mode period set by the base station (S280).

Thereafter, when the sleep mode section set by the base station passes, the central controller 180 supplies power to the transmitter 120 and the receiver 130 for one frame (S290).

In addition to the above method, the central controller 180 compares the current voltage level with the reference voltage level stored in the memory unit 170 and stores the sleep mode section in the memory unit 170 when the current voltage level is smaller than the reference voltage level. It is also possible to set the change sleep mode section.

As described above, the mobile communication terminal of the present invention supports the normal sleep mode in addition to the variable sleep mode. The variable sleep mode is set so that the standby time increases when the sleep mode section is set. Mode or normal sleep mode can be selected.

3 is a slot cycle index for a battery power management method of a mobile communication terminal according to the present invention. As shown in FIG. 3, the slot cycle index and the sleep mode section change according to the voltage level. The voltage level is then the percentage of the current battery's voltage to the voltage when the battery is fully charged.

As the voltage level decreases, the slot cycle index increases in size and the sleep mode interval increases. Therefore, as the voltage level decreases, the power cut-off time for the transmitter 120 and the receiver 130 becomes longer, thereby making battery management more efficient.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive.

The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

For example, a mobile communication terminal includes a mobile phone, a personal digital assistant (PDA), a notebook, and the like connected to a mobile communication network.

As described above, the mobile communication terminal and the battery management method of the present invention can efficiently manage the power of the battery by setting the sleep mode section in accordance with the voltage level of the battery.

Claims (9)

An external signal generator for outputting a variable sleep mode signal according to a user's manipulation; A transmitter for modulating various digital signals into baseband signals, intermediate frequency signals, and high frequency signals according to a predetermined standard and transmitting them to the antenna; A receiver demodulating the high frequency signal received through the antenna into an intermediate frequency signal, a low frequency signal and a digital signal according to a predetermined standard; A battery unit which supplies power to the transmitter and the receiver; A power measurement unit outputting a power measurement signal corresponding to the voltage level of the battery unit; A memory unit which stores sleep mode section information according to the voltage level; And Set the variable sleep mode by receiving the variable sleep mode signal, and set a sleep mode section corresponding to the voltage level determined through the power measurement signal using the sleep mode section information, and set the sleep mode section with the transmitter during the set sleep mode section. A mobile communication terminal comprising a central control unit for shutting off the power of the receiver. The method of claim 1, The sleep mode section information may be a slot cycle index in which the sleep mode section changes according to a voltage level. The central control unit, And extracting and setting a sleep mode section corresponding to the voltage level from the slot cycle index. The method of claim 1, The sleep mode section information is characterized in that the reference voltage level and the change sleep mode section, The central control unit, And setting the changed sleep mode section when the current voltage level determined by the power measurement signal is smaller than the reference voltage level. The method of claim 1, The external signal forming unit may output a normal sleep mode signal. The central control unit, And setting a normal sleep mode according to the normal sleep mode signal, and interrupting power supplied to the transmitter and the receiver during a sleep mode period set by a base station. The method of claim 1, The power measuring unit, A mobile communication terminal comprising an analog to digital converter (ADC) to convert an analog signal corresponding to the voltage level of the battery unit into a digital signal and output the power measurement signal. In the power management method of a battery mounted to a mobile communication terminal including a battery unit, a transmitter and a receiver, Determining whether a normal sleep mode signal or a variable sleep mode signal is input; Setting a variable sleep mode when the variable sleep mode signal is input; Determining a current voltage level of the battery unit; Setting a sleep mode section by using previously stored sleep mode section information according to the current voltage level; And Disconnecting power supplied to the transmitter and the receiver during the set sleep mode period. The method of claim 6, The sleep mode section information may be a slot cycle index in which the sleep mode section changes according to a voltage level. And setting a sleep mode section corresponding to the voltage level from the slot cycle index in setting the sleep mode section. The method of claim 6, The sleep mode section information is characterized in that the reference voltage level and the change sleep mode section, And setting the sleep mode section to set the current sleep mode section to the changed sleep mode section when the current voltage level is less than the reference voltage level. The method of claim 6, Setting a normal sleep mode when the normal sleep mode signal is input, and shutting off power supplied to the transmitter and the receiver during a sleep mode period set by a base station; .

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