KR100652141B1 - Battery type detection circuit in mobile communication terminal - Google Patents

Abstract

The present invention measures the ID port voltage of a battery used in a mobile communication terminal using an ADC in a BBA of a mobile communication terminal so that various types of batteries can be recognized through one ID port. The sensing circuit, which converts the ID voltage output from the battery's ID port into a DC level voltage of 0.5 to 2.5V and outputs it to the ADC in the BBA, and then converts the DC level voltage into digital data in the ADC in the BBA. It outputs to MSM, and then it analyzes digital data in MSM and classifies battery type according to capacity and composition, and executes battery operation program according to this classified battery type. By using the BBA's ADC instead of the port, it detects the ID voltage output from the battery's ID port. It can be used to recognize the womb battery, wherein the mobile communication terminal has the effect of being able to reduce the number of ports required for using different types of battery.

Description

Battery type detection circuit in mobile communication terminal

The present invention provides a mobile communication using an analog-to-digital converter (hereinafter, referred to as 'ADC') in a base-band analog processor (hereinafter referred to as 'BBA') of a mobile communication terminal. Detects battery type in a mobile communication terminal that can recognize various types of batteries through a single ID port by measuring the ID port of the battery used in the terminal (hereinafter referred to as 'ID') It is about a circuit.

In general, a mobile communication terminal is being used in a mobile communication system such as a digital cellular system (DCS), a personal communication system (PCS), or an international mobile telecommunication (IMT) -2000 network system. It is a device that can transmit and receive information and voice while being stopped, and there are a portable terminal, a vehicle terminal, and a fixed portable terminal.

Such a mobile communication terminal facilitates personal convenience in real life by allowing a user to easily carry and exchange information or voice quickly and accurately.

On the other hand, the mobile communication terminal performing the above functions are all operated by the power supply voltage of the battery, wherein the battery that can be used in the mobile communication terminal according to the capacity of the small capacity, medium capacity, large capacity battery, as well as the components There are several types such as lithium ions and nickel-hydrogen batteries.

In order to recognize the battery used in the mobile communication terminal as described above, the ID port of the battery is conventionally detected. That is, the ID port of the battery in the mobile communication terminal is referred to as a mobile station modem (hereinafter referred to as 'MSM'). The type of battery was determined by detecting a low signal or a high signal by connecting to a general purpose input output (GPIO) port.

However, as described above, only the type of battery according to the capacity can be detected using the GPIO port of the MSM, and when using different types of batteries together, another software for sharing the additional ID port and the battery may be used. There was a problem that an algorithm is needed.

The present invention has been made to solve the above problems, and the object of the present invention is to measure the ID port voltage of the battery used in the mobile communication terminal by using the ADC in the BBA of the mobile communication terminal without using the GPIO port of the MSM. One ID port can recognize various types of batteries according to their capacity and components, and it is possible to use various types of batteries by consistent software algorithms for sharing various batteries in mobile terminals. It is to provide a battery type detection circuit in a communication terminal.

Battery type detection circuit in the mobile communication terminal of the present invention for achieving this purpose, converts the ID voltage output from the ID port of the battery to a voltage of DC level of 0.5 ~ 2.5V and outputs to the ADC in the BBA, and then ADC in BBA converts DC level voltage into digital data and outputs it to MSM, and then analyzes the digital data in MSM to classify the battery type according to the capacity and composition, and the battery operation program suitable for the classified battery type. Characterized in that the execution.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the battery type detection circuit in the mobile communication terminal according to the present invention.

1 is a block diagram of a battery type sensing circuit in a mobile communication terminal according to the present invention. The battery 1 generates a power supply voltage for supplying a corresponding voltage to each component block of the mobile communication terminal, and the battery. A level converter 20 for converting the ID voltage output from the ID port of (1) into a DC level voltage that can be recognized by the ADC in the BBA, and an ADC is configured so that the level converter 20 The BBA 30 converts the DC level voltage converted into digital data into digital data, and classifies the battery type according to capacity and components from the digital data output from the BBA 30 to execute a battery operation program suitable for the type. It is configured to include the MSM (40).

The level converter 20 inputs an ID voltage of the battery 10 to a non-inverting terminal (+) to perform a voltage comparison and amplification operation with an inverting terminal (−), which is a reference terminal, and the comparator OP1. Amplification resistors R1 and R2 connected to the inverting terminal − of the comparator OP1 and between the inverting terminal − and the output terminal, respectively, and a filter capacitor C1.

The level converting unit 20 configured as described above inputs the ID voltage of the battery 10 and converts the voltage into a DC level that can be recognized by the ADC in the BBA 30 of 0.5 to 2.5V.

The BBA 30 converts an analog signal of an IF signal received by a mobile communication terminal that has passed through a wireless transmission / reception terminal into a baseband digital signal or converts a baseband digital signal output from the MSM 40 into an IF signal. Converted to an analog signal, the MSM 40 interfaces with the BBA 30 and consists of a demodulator, a modulator, a decoder, and the like, a code division multiple access (CDMA) signal of a forward / reverse link. Perform the process.

The operation of the battery type detecting circuit in the mobile communication terminal according to the present invention configured as described above will be described with reference to the flowchart of FIG. 2.

First, the level converter 20 inputs an ID voltage output from the ID port of the battery 10 (S1), converts it into a DC level voltage of 0.5 to 2.5V (S2), and then converts it to a BBA 30. Output to my ADC

That is, the level converter 20 converts the voltage into a DC level that can be recognized by the ADC in the BBA 30 through a voltage comparison and amplification operation of the comparator OP1.

Subsequently, the ADC in the BBA 30 inputs a DC level voltage (S3), converts it to digital data (S4), and outputs it to the MSM 40.

Then, the MSM 40 inputs the digital data (S5), classifies the battery type according to the capacity and the component through analysis of the digital data (S6), and generates a battery operation program suitable for the classified battery types. To execute (S7).

That is, the battery detects whether the shape is small, medium, or large by capacity, and detects whether lithium ions, nickel hydrogen, graphite, coke, etc., depending on the component type, and ends depending on the type of each detected battery. Run the program by determining the voltage or by using a DC / DC converter.

As described above, the present invention can recognize and use various types of batteries through one ID port by detecting the ID voltage output from the ID port of the battery using the ADC of the BBA, not the GPIO port of the MSM. In this case, there is an effect that the mobile communication terminal can reduce the number of ports required to use various types of batteries.

1 is a block diagram of a battery type detection circuit in a mobile communication terminal according to the present invention;

2 is a signal flow diagram illustrating an operation of a battery type sensing circuit in a mobile communication terminal according to the present invention.

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

10: battery 20: level converter

30: BBA 40: MSM

OP1: Comparator R1, R2: Resistance

C1: Capacitor

Claims (2)

The battery 1 generating a power supply voltage for supplying a corresponding voltage required to each component block of the mobile communication terminal, and the DC level at which the ADC in the BBA can recognize the ID voltage output from the ID port of the battery 1. A level converter 20 for converting the voltage into a voltage of the BBA, and an BBA 30 for converting the DC level voltage converted by the level converter 20 into digital data through the ADC; Battery type detection circuit in a mobile communication terminal, characterized in that it comprises a MSM (40) for classifying the type of the battery according to the capacity and components from the digital data output from the (30) to execute a battery operation program according to the type. The comparator (OP1) of claim 1, wherein the level converter 20 inputs an ID voltage of the battery 10 to a non-inverting terminal (+) to perform a voltage comparison and amplification operation with an inverting terminal (-). And amplification resistors (R1, R2) connected to the inverting terminal (-) of the comparator (OP1) and between the inverting terminal (-) and the output terminal, and a filter capacitor (C1), respectively. Battery type detection circuit in a communication terminal.