JPH0326028A - Power supply system for portable telephone set - Google Patents

Abstract

PURPOSE:To provide an optimum characteristic on a reception section in matching with the operating state of the power supply by utilizing a built-in battery and an external power supply, thereby attaining the power supply to the front end of the reception section with a different voltage. CONSTITUTION:The voltage V0 of a battery section 40 is nearly the same voltage as a voltage V1 at an external power input terminal 42 and a voltage V2 at an external power input terminal 44 is set higher than the voltage V1. Thus, a different voltage from the external power supply mode and the built-in battery mode is supplied as the power supply for the front end 10 of the reception section 8. Thus, a voltage applied to a high frequency amplifier section 12 and a frequency mixer section 14 in the front end 10 is boosted in the external power supply mode connecting to a booster or the like and the current consumption is suppressed within a range of satisfying the performance requested to the front end 10 in the built-in battery mode. Thus, the optimum characteristic in matching with the operating state of the power supply is provided on the reception section 8.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a mobile phone, and more particularly to a power supply method of a mobile phone to a receiving section of a superheterogeneous mobile phone.

[Conventional technology]

A conventional mobile phone has an antenna 52 as shown in FIG.
, the duplexer 54 , the receiver 56 , the transmitter 58 , the receiver 60 , the power switch 62 , the power switch 6
4, a battery section 66, and an external power input terminal 68, and power was supplied to the receiving section from the battery section 66 and external power input terminal 68. And if you use the built-in battery,
From the battery section 66 to the power switching section 64 and the power switch 62
When using an external power supply, connect the external power supply to the external power input terminal 68 and supply power through the power supply switching unit 64, the power switch 62, and the stabilized power supply 70. was being supplied. Generally, the voltage V1 of the external power supply is the reference voltage V of the battery. It was designed to have a value approximately equal to (■.ξVl).

Here, regarding the stabilized power supply 70, in FIG. 2, power is supplied to all of the receiving units 56 from one stabilized power supply, but in reality, a plurality of stabilized power supplies 70 exist in the receiving unit 56. In some cases, it may act across the receiving section 56 and the transmitting section 58. There are also cases where a stabilized power source is not used, but whether a built-in battery or an external power source is used, power is supplied to all circuits of the receiving section 56 at approximately the same voltage.

As mentioned above, conventional mobile phones can be supplied with power by selecting either the built-in battery or an external power source, but mobile phones do not require an external power source because their greatest feature is that they are portable. In most cases, a built-in battery is used. However, when it is actually used, it is not necessarily limited to being carried around, but is often used in a car, an office, etc. If you frequently use your mobile phone in your car or office, instead of using the built-in battery as a power source, use an external power source such as a converter from the car battery or AC power source. It is clearly more convenient to use the battery because it does not require the trouble of replacing and charging the battery.

Particularly when using in a car, it is better to use an external power supply, as it can be used in conjunction with a booster device that increases the transmitter output, allowing it to be handled like a dedicated car phone, and at the same time charging the battery. You can also do it.

[Problem to be solved by the invention]

In the conventional power supply system of mobile phones, even when using an external power supply, each circuit block in the receiving section is supplied with V, (Vl ”i
Power is supplied at the same voltage as the built-in battery of the Vj). Therefore, whether a built-in battery or an external power source is used as a power source for the mobile phone, there is no significant difference in the electrical operation of the receiving section.

Among the performance of a mobile phone as a radio device, reception sensitivity and intermodulation characteristics are representative of those related to the reception section. Generally speaking, there is a certain front end from the high frequency amplification section and frequency mixing section as a circuit block that greatly influences reception sensitivity and intermodulation characteristics, and the electrical performance of this front end is correlated with the power supply voltage and current consumption. is strong,
For example, the first frequency mixing section is designed with a power supply voltage of 5 [V] or less and a current consumption of 3 (mA) or less, and one that is designed with a power supply voltage of 12 (V) or less and a consumption current of 10 [mA].
When compared with those designed under the following conditions, the latter is clearly superior in receiving sensitivity and intermodulation characteristics.

On the other hand, one of the items that expresses the performance of a mobile phone is the amount of current consumption during standby. In other words, if the battery energy is kept constant, the lower the current during standby, the longer the standby time can be, which is beneficial to the user. Therefore, when designing the reception section of a mobile phone,
Reducing current consumption will be an important issue.

Therefore, when designing the front end of a mobile phone, the design should be made to reduce current consumption as much as possible while still satisfying the performance required for a radio device. In addition, when using a booster device etc. connected to an external power input terminal, high performance equivalent to that of a vehicle combat type mobile aircraft is required, and the reception sensitivity and intermodulation characteristics must also meet stricter values. ．．
For this reason, as mentioned above, it is effective to supply higher voltage and more current to the receiver. However, when power is supplied using the external power mode in the conventional power supply system of a mobile phone, power is supplied to each circuit block of the receiving section at the same voltage V+ (V+'ive). For this reason, the voltage is the same whether the mobile phone is powered by an internal battery or an external power supply, so the operating conditions of the front end can be changed depending on the usage status of the power supply, and the optimum characteristics for the receiver can be achieved. The disadvantage is that it cannot have .

An object of the present invention is to eliminate such drawbacks and to provide a power supply for a mobile phone having a receiving section that has optimal characteristics suitable for each usage state, both in built-in battery mode and external power mode. The purpose is to provide a supply method. [Means for Solving the Problems] The present invention has a front end including a high frequency amplification section and a frequency mixing section in a super heterolog reception section, and this reception section is equipped with a built-in battery or an external power input terminal. In a power supply system for a mobile phone that supplies power using a V.V. >V, and the other external power input terminal inputs a predetermined voltage Vt of It is characterized by supplying power. [Example] Next, an example of the present invention will be described with reference to the drawings.

FIG. I is a circuit block diagram showing one embodiment of the present invention. The power supply system of this mobile phone includes an antenna 2, a duplexer 4, a transmitting section 6, a receiving section 8, a receiver 34, a power switch 36, a power switching section 38, and a battery section 40.
, an external power input terminal 42 , and an external power input terminal 44 .

The antenna 2 transmits and receives radio waves, and the duplexer 4 separates waves transmitted by the transmitter 6 and waves received by the receiver 8 in bidirectional communication. The transmitting section 6 transmits the audio signal as a transmission wave, and the receiving section 8 is a receiving section using a super heterolog system, and receives the received wave and converts it into an audio signal.

This receiving section 8 includes a front end 10 of the receiving section, a first local oscillating section 20, a second frequency mixing section 22, a second local oscillating section 24, an intermediate frequency amplifying section 26, a demodulating section 28,
The front end 10 of the reception section includes a low frequency amplification section 30 and a stabilized power supply 32, and includes a high frequency amplification section l2, a first frequency mixing section l4, a diode 16, and a diode l8.
It is equipped with

The front end 10 of the receiving section is a front end consisting of a high frequency amplifying section 12 and a first frequency mixing section l4,
The high frequency amplification section 12 selectively amplifies the high frequency input signal received from the antenna 2, and the first frequency mixing section 14 uses the oscillation frequency from the first local oscillation section 20 to convert the reception frequency from the high frequency amplification section 12 to a frequency lower than that. Convert and amplify. A diode 1 is connected to the front end of the high frequency amplification section 12 and the first frequency mixing section 14 from a built-in battery or an external power supply.
By supplying power at different voltages through the diode 6 or the diode 18, performance such as receiving sensitivity of the receiving section can be improved. The first local oscillation section 20 sends the oscillation frequency to the first frequency mixing section 14.

The second frequency mixer 22 has the same function as the first frequency mixer l4, and converts the received frequency from the first frequency mixer 14 to a lower frequency. The second local oscillator 24 is
The oscillation frequency is sent to the second frequency mixing section 22. The intermediate frequency amplifying section 26 amplifies the intermediate frequency frequency-converted by the first frequency mixing section 14 and the second frequency mixing section 22 and sends it to the demodulating section 28 . The demodulation unit 28 includes an intermediate frequency amplification unit 26
A signal wave is extracted from the signal, and the low frequency amplification section 30
The signal wave from the demodulator 28 is amplified.

The stabilized power supply 32 receives power from a built-in battery or an external power supply, and supplies power to all circuits of the receiving section 8 at a constant voltage. The receiver 34 converts the audio signal from the low frequency amplification section 30 into audio.

The power switch 36 is connected to the stabilized power source 32 of the transmitting section 6 and receiving section 8, and supplies power to the transmitting section 6, the stabilized power source 32, etc. by turning the switch "on".

The power supply switching section 38 is connected to the battery section 40 and the external power input terminal 42, and selects either the power source from the built-in battery from the battery section 40 or the power source from the external power source from the external power input terminal 42. , to the power switch 36. The power supply switching section 38 can switch from a mechanical switch, for example, or from the supply from the battery section 40 of the built-in battery to the external power supply by inserting a jack such as an AC adapter into the external power input terminal 42 and the external power input terminal 44. The power supply is switched to supply from the external power input terminal 42 and the external power input terminal 44.

The battery section 40 is, for example, a rechargeable battery, and sends the power to the power supply switching section 38 . The voltage of this battery section 40 is ■. is set to approximately the same voltage (■.=Vt) as the voltage vI of the external power supply from the external power supply input terminal 42.

The external power input terminal 42 and the external power input terminal 44 are used to connect an external power source when an external power source is used. In this case, the voltage V of the external power input terminal 42 and the voltage of the external power input terminal 44 are set using a booster device or the like so that V2>V1.

Next, the operation of this embodiment will be explained. When using a built-in battery, unless an external power source is connected to the external power input terminal 42 and the external power input terminal 44, the power supply switching unit 38 selects the built-in battery mode and switches the circuit. By turning on the power switch 36, power is supplied to the transmitter 6 and the receiver 8. In the receiving section 8, the stabilizing voltage 32 receives power from the battery section 40, and supplies power to each circuit block of the receiving section 8 at a constant voltage.

In this case, the high frequency amplifying section 1 of the front end 10 of the receiving section
2 and the first frequency mixing section 14 are supplied with power from a stabilized power source 32 via a diode 18.

When using an external power source, connect the external power source to the external power input terminal 42 and the external power input terminal 44.

When connected, the power supply switching unit 38 selects the external power supply mode and switches the circuit. and external power input terminal 42
From the voltage V, the power switching section 38 power switch 3
Power is supplied to the stabilized power supply 32 via the stabilized power supply 6, and the stabilized power supply [
Power is supplied from 32 to each circuit block of the receiving section 8 at a constant voltage. Power is also supplied from the external power input terminal 44 using a booster device or the like, and power is supplied to the high frequency amplifying section 12 and first frequency mixing section 14 of the front end 10 of the receiving section via the diode 16. In the case of the external power supply mode, the voltage V0 of the power supply switching unit 38 and the voltage ■1 of the external power input terminal 42 are almost the same voltage (voξV,), and the voltage ■2 of the external power input terminal 44 is the voltage of the external power input terminal ■, Set to a higher voltage (Vz > V+).

As explained above, the power supply system of the mobile phone according to the present invention serves as a power supply to the front end of the reception unit of the mobile phone.
Different voltages can be supplied in external power mode and built-in battery mode. Therefore, by setting the voltage in the external power mode higher than the voltage in the built-in battery mode, the voltage applied to the high frequency amplification section and the frequency mixing section in the front end will be reduced in the external power mode state, which may be connected to a booster device, etc. The voltage can be increased.

On the other hand, when the built-in battery is in use, current consumption can be suppressed within the range that satisfies the performance required for the front end.

In this embodiment, the receiving section is constructed using a double super-heteri-log system, but it is also possible to use a single-super-heteri-log receiving section that does not include a second frequency mixing section and a second local oscillation. However, the present invention can be fully applied. [Effects of the Invention] As explained above, according to the present invention, by using a built-in battery and an external power supply, it is possible to supply power at different voltages to the front end of the reception section of a mobile phone. Therefore, by setting the voltage in external power mode higher than the voltage in built-in battery mode, when using an external power source that may be connected to a booster device, etc., the voltage applied to the high frequency amplification section and frequency mixing section in the front end Increase the voltage to the active element. By weakening the current constraints, it is possible to realize a mobile phone with a receiving section that can handle even severe values of receiving sensitivity and intermodulation characteristics. Furthermore, when the built-in battery is in use, current consumption can be suppressed within a range that satisfies the performance required of the front end of the receiving section, thereby reducing the power consumption of the mobile phone.

[Brief explanation of drawings]

FIG. 1 is a circuit block diagram showing an embodiment of the present invention, and FIG. 2 is a circuit block diagram showing a conventional power supply system for a mobile phone. 8, 56... Receiving unit 10... Front end 32 of the receiving unit. 70・
...Stabilized power supply 36. 62...Power switch 38. 64...Power switching unit 40. 66...Battery section

Claims (1)

[Claims] (1) A front end including a high frequency amplification section and a frequency mixing section is provided in a superheterodyne receiving section,
In a power supply system of a mobile phone that supplies power to the reception unit using a built-in battery or an external power input terminal, the external power input terminal receives a predetermined voltage V_1 corresponding to the standard voltage of the built-in battery. one external power input terminal that inputs a predetermined voltage V_2 such that V_2>V_1, and the other external power input terminal that inputs a predetermined voltage V_2 such that V_2>V_1. A power supply system for a mobile phone, characterized in that power is supplied to the front end from the power input terminal.