JPH07131412A - Power supply circuit for transmission/reception equipment - Google Patents

Abstract

PURPOSE:To extend the time for which a portable telephone can be used by one charging by using a lithium ion battery as the power source of the portable telephone and organically using a DC-DC converter. CONSTITUTION:The power supply circuit for transmission/reception equipment where a lithium ion battery 11 is used as the power source is provided with a DC-DC converter 12 having >=85% conversion efficiency. The output voltage of the lithium ion battery 11 is supplied to the DC-DC converter 12 and is converted to the output voltage having a prescribed value, and this output voltage of the DC-DC converter 12 is supplied to at least the output stage of a transmission circuit 1 as the operating voltage. The energy corresponding to the difference between the output voltage of the lithium ion battery 11 and the operating voltage of the output stage is used as the energy for operation of the transmission/reception equipment. Consequently, the portable telephone is used for a longer time when the conversion efficiency of the DC-DC converter 12 is improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply circuit of a transmitting / receiving device such as a mobile phone.

[0002]

2. Description of the Related Art A secondary battery is used as a power source for a mobile phone. A Ni-Cd battery is used as the secondary battery.
There are Ni-MH batteries and lithium-ion batteries. Among them, the lithium-ion battery has a high output voltage per unit cell and a high energy density, and is therefore suitable as a power source for mobile phones.

[0003]

By the way, when a lithium ion battery is used as a power source for a mobile phone, if the capacity of the lithium ion battery is 2400 mAh and the current consumption during a call is 600 mA, the time available for a call is , 2400 [mAh] / 600 [mA] = 4 [hours].

Alternatively, if the current consumption during standby is 40 mA, the standby time is 2400 [mA] / 40 [mA] = 60 [hours].

The present invention intends to make the usable time of the mobile phone longer than the above-mentioned time when the lithium ion battery is used as the power source of the mobile phone.

[0006]

Although the nominal output voltage per unit cell of a lithium ion battery is 3.6 V, the discharge voltage is measured and the output voltage per unit cell is shown in FIG.
As shown in, the starting voltage is about 4.2.
V, the final voltage is about 2.7V.

On the other hand, circuits used in mobile phones are modularized, but the modules have operating voltage (power supply voltage) specifications of 5.8V and 4.8V. There is.

This invention pays attention to the above points and uses a lithium ion battery as a power source for a mobile phone.
By organically utilizing the DC-DC converter,
The mobile phone can be used for a longer period of time than the above.

That is, in the present invention, when the reference numerals of the respective parts correspond to the embodiments described later, in the power supply circuit of the transmitter / receiver using the lithium ion battery 11 as the power supply, the conversion efficiency is 85% or more DC-DC. Converter 1
2 is provided. Then, the output voltage of the lithium-ion battery 11 is supplied to the DC-DC converter 12 to be converted into an output voltage of a predetermined value, and the output voltage of the DC-DC converter 12 is at least output to the output stage 4 of the transmission circuit 1. The operating voltage is supplied.

[0010]

The energy corresponding to the voltage difference between the output voltage of the lithium ion battery 11 and the operating voltage of the output stage 4 is also used as the energy when the transceiver device operates.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIG. 1, reference numeral 1 denotes a transmission circuit of a mobile phone, and 2
Indicates its receiving circuit, and 3 indicates its control circuit. Then, the transmission / reception circuits 1 and 2 transmit / receive a voice signal and various data of a call between the mobile phone and the base station, and the control circuit 2 performs various processes for realizing the call. And control.

The main parts of these circuits 1 to 3 are modularized as described above, but the operating voltage has a specification value of 4.8V.

Further, 11 indicates a lithium ion battery. In this example, the lithium-ion battery 11 has four
One unit cell is packed into one, two unit cells are connected in series, and two of the series circuits are connected in parallel. Therefore, the nominal output voltage of the lithium-ion battery 11 is 7.2V, and the actual output voltage is about 8.4V to about 5.5V. The total capacity of the lithium-ion battery 11 is 2400 mAh.

Reference numeral 12 denotes a DC-DC converter. The converter 12 down-converts the output voltage of the lithium ion battery 11 to 4.8V and supplies it to the circuits 1 to 3 as their operating voltage.

In this case, as the DC-DC converter 12, one having a conversion efficiency as high as possible, that of at least 85% or more is used. FIG. 2 shows a DC-D with high conversion efficiency.
An example of the C converter 12 is shown. In the converter 12, Q1 is an IC for DC-DC converter of LTC1148 series or LTC1147 series of LINEAR TECHNOLOGY, USA.

Then, in this converter 12,
A PWM pulse is output from the IC (Q1), and this PWM
The pulses alternately turn on / off the FETs (Q2, Q3) to chop the input voltage, and as a result, a DC voltage of a desired magnitude is output to the capacitor C1. At this time, the output voltage is fed back to the IC (Q1), the pulse width of the PWM pulse is changed corresponding to the output voltage, and the output voltage is controlled to a constant value.

3 and 4 are DC-DC of FIG.
The conversion efficiency of the converter 12 is shown. As is clear from these figures, the conversion efficiency of the DC-DC converter 12 of FIG. 2 is extremely high, and depending on the magnitude of the output current, when the input voltage is 10 V or less, that is, the lithium ion battery 11 In the output voltage change range, the conversion efficiency is 90% or more (Figs. 2 to 4 are quoted from the IC (Q1) manual).

With such a configuration, the usable time of the mobile phone can be made considerably longer than the above-mentioned time. That is, the amount of energy E11 possessed by the lithium-ion battery 11 is E11 = 7.2 [V] × 2400 [mAh] = 17.28 [Wh].

If the current consumption of the circuits 1 to 3 during a call is 600 mA as described above, the power consumption PLD of the circuits 1 to 3 during a call is PLD = 4.8 [V] × 600 [mA] = It becomes 2.88 [W].

Therefore, if the conversion efficiency of the DC-DC converter 12 is 85%, conservatively, the input power P12 of the converter 12 during a call is P12 = 2.88 [W] / 85 [%] ≈3.39 [W ] Becomes

Therefore, the time TCT during which the call can be made is TCT = E11 / P12.apprxeq.17.28 [Wh.h] /3.39 [W] .apprxeq.5.1 [time]. In other words, you can talk for more than 5 hours,
Compared to the four hours mentioned above, the time available for talking is 27% longer.

If the current consumption of the circuits 1 to 3 during standby is 40 mA as described above, the power consumption PLD of the circuits 1 to 3 during standby is PLD = 4.8 [V] × 40 [mA] = It becomes 192 [mW].

Therefore, if the conversion efficiency of the DC-DC converter 12 is 85%, the input power P12 of the converter 12 during standby is P12 = 192 [mW] / 85 [%] ≅226 [mW].

Therefore, the standby time TSB is TSB = E11 / P12.apprxeq.17.28 [Wh.multidot.h] / 226 [mW] .apprxeq.76.5 [hours]. In other words, the time that you can wait is just over 76 hours, which is 27% longer than the above 60 hours.

Thus, according to this power supply circuit, even if the same lithium ion battery is used, the mobile phone can be used for a longer time with one charge. Further, as is clear from the above, the DC-DC converter 1
If the conversion efficiency of 2 becomes higher, the mobile phone can be used for a longer time.

In the example shown in FIG. 5, only the output stage (high frequency power amplifier module) of the transmission circuit 1 is DC-D.
This is the case where the operating voltage is supplied through the C converter 12.

That is, the circuit 4 shows the output stage of the transmitter circuit 1. In this example, the specification value of the power supply voltage is 5.8.
It is V. In addition, the DC-DC converter 12
When the output voltage of the lithium-ion battery 11 is 6.3 V or more (6.3 V is a voltage value that allows for a drop voltage 0.5 V in the converter 12), the battery voltage is down-converted to 5.8 V, and when the output voltage is less than 6.3 V. , Up-converted and converted to 5.8V. And
The voltage resulting from the conversion of the converter 12 is supplied to the output stage 4 as its operating voltage.

The specification value of the operating voltage of the circuits 1 to 3 is 5.
The output voltage of the lithium-ion battery 11 is directly supplied as an operating voltage while being set to 8V. In this case, when the remaining amount of the lithium-ion battery 11 is large,
The output voltage becomes higher than the specification value 5.8V of the operating voltage of the circuits 1 to 3, but there is no particular problem as long as it is in this example.

According to this structure, the mobile phone can be used for a longer period of time by charging once for the same reason as above. Further, the DC-DC converter 12 has a current consumption of the output stage 4, that is, 100 m.
Since it is only necessary to output a current of about A to 150 mA, size reduction and cost reduction can be achieved.

Also in the example shown in FIG. 6, the operating voltage is supplied only to the output stage 4 of the transmission circuit 1 through the DC-DC converter 12.

That is, in this example, the specification value of the power supply voltage of the output stage 4 is 5.8V. Also, DC-
The DC converter 12 is configured to down-convert the battery voltage to 5.8 V when the output voltage of the lithium-ion battery 11 is 6.3 V or higher. When the output voltage of lithium-ion battery 11 is less than 6.3V, converter 12 does not have to operate.

A first switching transistor Q11 is connected between the lithium-ion battery 11 and the power supply line of the output stage 4, and the converter 12
A second switching transistor Q12 is connected between the output terminal of the second switching element and the power supply line of the output stage 4.

When the output voltage of the lithium-ion battery 11 is 6.3 V or more, the transistor Q11 is turned off and the transistor Q12 is turned on so that the output voltage of the converter 12 is 5.8 V and the output voltage of the output stage 4 is 5.8 V. When the output voltage of the lithium-ion battery 11 is less than 6.3V, the transistor Q11 is turned on and the transistor Q12 is turned off, so that the voltage of the lithium-ion battery 11 is directly applied to the output stage 4 by its operating voltage. Supplied as.

According to such a configuration, the mobile phone can be used for a longer time with one charge for the same reason as described above. Further, since the DC-DC converter 12 only needs to output the current consumed by the output stage 4 and only needs to perform the down-conversion, the design becomes easier, and the size and cost can be further reduced.

In this example, when the operation of the DC-DC converter 12 can be directly permitted or prohibited, the operation of the DC-DC converter 12 may be permitted or prohibited without providing the transistor Q3. Further, a signal for controlling the on / off of the transistor Q11 can be obtained from the D-DC converter 12.

[0036]

According to the present invention, in a mobile phone using a lithium-ion battery as a power source, the mobile phone can be used for a longer time with one charge. Further, if the conversion efficiency of the DC-DC converter 12 is increased, the mobile phone can be used for a longer time.

[Brief description of drawings]

FIG. 1 is a system diagram showing an example of the present invention.

FIG. 2 is a connection diagram showing an example of a part of the circuit of FIG.

FIG. 3 is a characteristic diagram for explaining the circuit of FIG.

FIG. 4 is a characteristic diagram for explaining the circuit of FIG.

FIG. 5 is a system diagram showing another example of the present invention.

FIG. 6 is a system diagram showing another example of the present invention.

FIG. 7 is a diagram showing discharge characteristics of a lithium-ion battery.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 transmitter circuit 2 receiver circuit 3 control circuit 4 output stage of transmitter circuit 11 lithium ion battery 12 DC-DC converter Q1 DC-DC converter IC

Claims (4)

[Claims] 1. A power supply circuit of a transmitter / receiver using a lithium ion battery as a power supply, comprising a DC-DC converter having a conversion efficiency of 85% or more, wherein the output voltage of the lithium ion battery is the DC-DC converter. To the output voltage of the DC-DC converter, and the output voltage of the DC-DC converter is supplied to at least the output stage of the transmission circuit as its operating voltage. 2. The power supply circuit of the transmitter / receiver according to claim 1, wherein the operating voltage of the transmitting circuit, the receiving circuit, and the control circuits of the transmitting circuit and the receiving circuit is lower than the final voltage of the lithium ion battery. In the DC-DC converter, the output voltage of the lithium-ion battery is down-converted to values of operating voltages of the transmission circuit, the reception circuit, and the control circuit, and the down-converted output voltage is The above transmission circuit,
A power supply circuit of a transmitting / receiving device, which is adapted to supply the receiving circuit and the control circuit as their operating voltage. 3. The power supply circuit of the transmitter / receiver according to claim 1, wherein the operating voltage of the output stage of the transmitter circuit is set to a value between the start voltage and the end voltage of the lithium ion battery, When the output voltage of the ion battery is higher than a predetermined voltage value, the output voltage of the lithium ion battery is down-converted to the value of the operating voltage of the output stage of the transmission circuit in the DC-DC converter. The output voltage of the lithium ion battery is supplied to the output stage of the transmission circuit as its operating voltage, and when the output voltage of the lithium ion battery is lower than the predetermined voltage value, the output voltage of the lithium ion battery is changed to the DC-DC. In the converter, up-convert to the value of the operating voltage of the output stage of the transmitter circuit, and then up-convert the output voltage. The power supply circuit of the transmitting and receiving apparatus adapted to supply as an operating voltage to the output stage of the transmitter circuit. 4. The power supply circuit of the transmitter / receiver according to claim 1, wherein the operating voltage of the output stage of the transmitter circuit is set to a value between the start voltage and the end voltage of the lithium ion battery, When the output voltage of the ion battery is higher than a predetermined voltage value, the output voltage of the lithium ion battery is down-converted to the value of the operating voltage of the output stage of the transmission circuit in the DC-DC converter. The output voltage of the lithium ion battery is supplied as an operating voltage to the output stage of the transmitter circuit, and when the output voltage of the lithium ion battery is lower than the predetermined voltage value, the output voltage of the lithium ion battery is directly transmitted to the transmitter circuit. The power supply circuit of the transmitter / receiver, which is supplied to the output stage as the operating voltage.