JP2011135539A - Portable communication terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress influences to be exerted upon a GPS (Global Positioning System) band by tertiary intermodulation distortion caused by receiving signals of both an AWS (Advanced Wireless Services) band and a PCS (Personal Communication Service) band in a portable communication terminal and amplifying the signals with an amplifier. <P>SOLUTION: When the portable communication terminal is under communication on any other channel than channels 25 and 675 to 875 of the AWS band and an amplification factor of a power amplifier for transmission is high in order to suppress influences of tertiary intermodulation distortion which may occur when amplifying the signals of the AWS band and the PCS band in a low noise amplifier 180 for GPS, a switch 220 is opened to increase a base potential of a transistor 200, thereby increasing a collector current I<SB>C</SB>. Otherwise, when the portable communication terminal transmits a signal in the PCS band at high output, the collector current I<SB>C</SB>is increased. In other cases, the switch 220 is conducted and the collector current I<SB>C</SB>is decreased. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a mobile communication terminal, and more particularly to suppression of the influence on the GPS function of third-order intermodulation distortion caused by signals in two frequency bands.

  In a mobile communication terminal, a GPS function may be executed while performing communication by selecting one frequency band from a plurality of frequency bands. However, depending on the frequency band used for communication, the GPS function cannot be used for accurate positioning due to interference from third-order intermodulation distortion (sometimes abbreviated as IM3 (3rd order Inter Modulation)). there is a possibility. Third-order intermodulation distortion is generated when signals in two frequency bands are amplified almost simultaneously by an amplifier such as a low noise amplifier. For example, if one frequency of signals in two frequency bands is f1, and the other frequency is f2, the so-called third-order intermodulation distortion is called a frequency band obtained from the difference between the double frequency of the one and the other frequency. Distortion component is generated. That is, third-order intermodulation distortion occurs in the frequency bands indicated by 2f1-f2 and 2f2-f1. Note that when the amplifier is ideal, third-order intermodulation distortion does not occur. However, in reality, there is no ideal amplifier and basically third-order intermodulation distortion occurs.

Usually, in a mobile communication terminal, when a signal is received by an antenna, a signal other than a desired band is dropped by a filter and then amplified by a low noise amplifier. At this time, when the unnecessary signal cannot be dropped by the filter and there are signals in two frequency bands, third-order intermodulation distortion occurs.
As a specific example, for example, it is assumed that the mobile communication terminal can communicate in both the PCS band and the AWS band. At this time, the mobile communication terminal may receive a signal in the AWS band from another communication terminal as an interference wave while transmitting a signal to the base station in the PCS band. Alternatively, a mobile communication terminal may receive a signal in the PCS band from another communication terminal as an interference wave while transmitting a signal to the base station in the AWS band.

Then, a state occurs in which a signal transmitted from the terminal itself and a signal transmitted from another form communication terminal are received by the antenna of the terminal itself. Then, when the two signals are not completely dropped by the filter, third-order intermodulation distortion occurs during amplification by the low noise amplifier.
As shown in FIG. 7, the 1.9 GHz band is used for the PCS band and the 1.7 GHz band is used for the AWS band. When both signals are amplified by a low noise amplifier, the 1.5 GHz band and the 2.1 GHz band are used. Third-order intermodulation distortion appears.

When a mobile communication terminal has a GPS function, a signal from a GPS satellite is received and filtered by an antenna and then amplified by a low noise amplifier. One of the third-order intermodulation distortions generated at this time May become noise and interfere with demodulation of signals from GPS satellites. This is because the frequency band used in GPS is the 1.5 GHz band.
For this reason, it is necessary to improve the distortion characteristics with respect to the third-order intermodulation distortion of the low-noise amplifier provided for the GPS, that is, to prevent the third-order intermodulation distortion as much as possible. It is necessary to increase the third-order intercept point (hereinafter referred to as IP3 (3rd order Intercept Point)) of the amplifier. This is because by increasing IP3, the generation level of the third-order intermodulation distortion can be suppressed to a level that can be ignored as the error range.

Although FIG. 8 is a circuit diagram showing a low-noise amplifier for GPS which is also conventionally used to increase the IP3, it is generally known that it is sufficient to increase the collector current I _C of FIG. 8 ing.
Patent Document 1 discloses a technique for increasing IP3 when the terminal transmits a signal with high output.

JP 2002-217774 A

By the way, as a mobile communication terminal, when receiving a signal in the AWS band as an interference wave while transmitting a signal in the PCS band, or when receiving a signal in the PCS band as an interference wave while transmitting a signal in the AWS band Since it is unpredictable, it is desirable to keep the collector current I _C always high. However, increasing the collector current I _C, because that would current consumption in the low noise amplifier increases, undesirable in devices where it is desirable to operate a long time in the internal power supply such as a mobile communication terminal.

  Therefore, the present invention provides a portable communication terminal that can suppress the current consumption in a low-noise amplifier for GPS and suppress the influence of third-order intermodulation distortion generated by an AWS band signal and a PCS band signal. For the purpose.

  In order to solve the above problems, the present invention has a GPS (Global Positioning System) function, a function for executing communication in the AWS (Advanced Wireless Services) band, and a function for executing communication in the PCS (Personal Communication Service) band. A mobile communication terminal comprising an antenna, an amplifier that amplifies and outputs a signal output from the antenna, and the terminal is communicating on a predetermined channel among the plurality of channels in the AWS band, This is a case where the third-order intermodulation distortion generated by the amplification of the signal in the frequency band of the predetermined channel and the signal in the PCS band by the amplifier overlaps or occurs in the vicinity of the GPS band. And a control unit that executes control to increase the third-order intercept point of the amplifier when the transmission power is higher than a predetermined power value. It is characterized by.

  With the configuration as described above, the mobile communication terminal according to the present invention suppresses current consumption in the amplifier for GPS and is generated when the AWS band signal and the PCS band signal are amplified by the amplifier. The influence of the next intermodulation distortion can be suppressed.

It is a functional block diagram which shows the function structure of the mobile telephone which concerns on this invention. It is a circuit diagram which shows the circuit structure of the low noise amplifier for GPS. It is a flowchart which shows operation | movement when operating the GPS function of the mobile telephone which concerns on this invention. It is a table | surface which shows the frequency of the 3rd order intermodulation distortion of the GPS band vicinity which generate | occur | produces in the center frequency of each channel of AWS band and PCS band. It is a table | surface which shows the frequency of the 3rd order intermodulation distortion of the GPS band vicinity which generate | occur | produces in the center frequency of each channel of AWS zone | band and PCS zone | band, and its use frequency zone. It is a circuit diagram which shows another structure of the control mechanism of a low noise amplifier. It is a schematic diagram for demonstrating the third-order intermodulation distortion. It is a circuit diagram which shows the circuit structure of the conventional low noise amplifier for GPS.

Hereinafter, a mobile phone which is an embodiment of a mobile communication terminal according to the present invention will be described with reference to the drawings.
<Embodiment>
<Configuration>
As shown in FIG. 1, a mobile phone 100 includes an antenna 110, an antenna 111, a switch 120, a PCS band communication circuit 130, a transmission power amplifier 131, a cellular band communication circuit 140, and an AWS band communication circuit 150. , A transmission power amplifier 151, a CPU 160, a filter 170, a filter 171, a low noise amplifier 180, and a demodulation circuit 190.

The switch 120 has a function of switching the connection state between the antenna 111 and each communication circuit in accordance with an instruction from the CPU 160. FIG. 1 shows a state where the antenna 111 and the AWS band communication circuit 150 are connected.
The PCS band communication circuit 130 is equivalent to a communication circuit having a function of executing communication in a conventional PCS band, includes a transmission power amplifier 131, and receives the PCS via the antenna 111 in accordance with an instruction from the CPU 160. It has a function to execute communication with an external device such as a base station in the band. Specifically, the signal transmitted from the CPU 160 is modulated, amplified by the transmission power amplifier 131, and transmitted from the antenna 111. The signal received by the antenna 111 is demodulated and demodulated. It has a function to transmit to the CPU 160.

  The PCS band here refers to a broadband PCS band of 1850 MHz to 1910 MHz upstream and 1930 MHz to 1990 MHz downstream. The channels in the PCS band are set to increase by 0.05 MHz for each channel. That is, the frequency of the 25 channels in the PCS band is 1851.25 MHz, the frequency of the 26 channel is 1851.30 MHz,..., The frequency of the 1174 channel is 1908.70 MHz, and the frequency of the 1175 channel is 1908.75 MHz. . In addition, the frequency of 25 channels downstream of the PCS band is 1931.25 MHz, the frequency of 26 channels is 1931.30 MHz,..., The frequency of 1174 channels is 1988.70 MHz, and the frequency of 1175 channels is 1988.75 MHz. . Note that, in practice, channels in increments of 25 channels are used for communication so that bandwidths do not overlap between adjacent frequencies.

  The transmission power amplifier 131 has a function of determining an amplification factor in accordance with an instruction from the CPU 160 and amplifying the supplied modulated signal. The amplified signal is transmitted from the antenna 111. The amplification factor of the transmission power amplifier 131 has two states of high (hereinafter referred to as “high”) and low (hereinafter referred to as “low”), and the CPU 160 is either high or low according to an instruction from the base station. Instruct.

  Cellular band communication circuit 140 is equivalent to a conventional communication circuit having a function of performing communication in the Cellular band, and in accordance with an instruction from CPU 160, an external device such as a base station in Cellular band via antenna 111 And a function for executing communication. The Cellular band uses frequency bands of 824 to 849 MHz for uplink and 869 to 894 MHz for downlink, and the cellular band signal has third-order intermodulation distortion generated in the PCS band and AWS band signals in the GPS band. There is no duplication.

  The AWS band communication circuit 150 is equivalent to a conventional communication circuit having a function of performing communication in the AWS band, and includes a transmission power amplifier 151. According to an instruction from the CPU 160, the AWS band communication circuit 150 is connected to the AWS band via the antenna 111. It has a function to execute communication with an external device such as a base station in the band. Specifically, the signal transmitted from the CPU 160 is modulated, amplified by the transmission power amplifier 151, and transmitted from the antenna 111. The signal received by the antenna 111 is demodulated and demodulated, and the demodulated signal is It has a function to transmit to the CPU 160.

  The AWS band here refers to a frequency band of 1710 MHz to 1755 MHz upstream and 2110 to 2155 MHz downstream. Similarly to the PCS band, the AWS band channel is set in increments of 0.05 MHz. In the upstream direction, the frequency of the 25 channel is 1711.25 MHz, the frequency of the 26 channel is 1711.30 MHz,... , The frequency of the 874 channel is 1753.70 MHz, and the frequency of the 875 channel is 1753.75 MHz. In the AWS band, the third-order intermodulation distortion with the PCS band overlaps with the GPS band in the upstream channel signal, and the downstream channel signal has no effect. In practice, channels in increments of 25 channels are used in communication.

The transmission power amplifier 151 has a function of determining an amplification factor according to an instruction from the CPU 160 and amplifying the supplied modulated signal. The amplified signal is transmitted from the antenna 111. The amplification factor of the transmission power amplifier 151 has two states of high and low, and the CPU 160 instructs whether it is high or low according to the instruction from the base station.
The CPU 160 has a function of controlling each part of the mobile phone 100 and executes various functions that the mobile phone 100 normally has.

  The CPU 160 determines amplification factors of the transmission power amplifier 131 and the transmission power amplifier 151 according to a control signal for determining transmission power received from the base station. In other words, when the control signal from the base station requests transmission at a high output, the amplification factor of the transmission power amplifier is set to high, and the control signal from the base station requests normal transmission. In this case, the amplification factor of the transmission power amplifier is set to low. In addition, the CPU 160 is in a state where the GPS positioning system is in operation, and when the signal is transmitted at a high output with a channel other than the 25th channel of the AWS band and the 675-875 channel, and the PCS band. When a signal is transmitted at a high output, a switch 220 provided in the low-noise amplifier 180, which will be described later, is turned off, that is, opened. In other cases, control is performed so that the switch 220 is turned on. Further, the CPU 160 has a function of switching the switch 120 according to the frequency band to be used and the service.

The filter 170 is a band-pass filter that shields a signal received by the antenna 110 except for a signal in a specific frequency band. Specifically, the filter 170 passes a signal having a frequency up to about 30 MHz before and after the limit of the characteristics as a filter with a center frequency of 1575.42 MHz.
The filter 171 is a band-pass filter that blocks the signal amplified by the low noise amplifier 180 except for a signal in a specific frequency band. Specifically, the filter 171 passes a signal having a frequency up to about 30 MHz before and after the limit of the characteristics as a filter with a center frequency of 1575.42 MHz. In other words, the filters 170 and 171 basically have the same filter characteristics.

The low noise amplifier 180 is a low noise amplifier that amplifies the signal that has passed through the filter 170. FIG. 2 shows a circuit configuration of the low noise amplifier 180. As shown in FIG. 2, the low noise amplifier 180 is configured using a bipolar transistor 200 whose emitter is grounded. By applying a power supply voltage V _CC to the collector side, the collector current I _{C is changed} to that of the transistor 200. The signal is passed through the collector electrode, thereby amplifying the signal passing through the GPS filter 170 input to the base electrode.

The low noise amplifier 180 includes a resistor 210d, a resistor 210e, a switch 220, and a capacitor 230, as shown in FIG. 2, in addition to the conventional configuration shown in FIG.
As shown in FIG. 2, the low-noise amplifier 180 has a configuration in which a resistor 210d, a resistor 210e, and a switch 220 are connected in series, and one end is connected to the base electrode of the transistor 200 and the other is grounded. One end of a capacitor 230 is connected between the resistor 210d and the resistor 210e, and the other end is grounded.

When the switch 220 is turned on, that is, in a conductive state, a current flows to the resistor 210d side, and the base potential decreases. Then by the base potential is lowered, since the resistor 210c current easily flows, so that the collector current I _C decreases.
In other words, when the switch 220 is turned off, that is, opened, the base potential of the transistor 200 does not decrease. At this time, the collector current I _C increases, so that IP3 increases.

Based on the control of the CPU 160, the switch 220 is normally set to on, that is, in a conductive state. By setting the base potential of the transistor 200 in this state as a reference potential and opening the switch 220, the base potential can be made higher than the reference potential.
Returning to FIG. 1, the demodulation circuit 190 has a function of demodulating a signal after the signal amplified by the low noise amplifier 180 is filtered by the filter 171 and transmitting the demodulated signal to the CPU 160. The CPU 160 executes a positioning function from the transmitted signal. As a positioning method, a conventional method is used, and details thereof are omitted here.
<Operation>
Next, the operation when the GPS function of the mobile phone 100 according to the present embodiment is executed will be described with reference to the flowchart shown in FIG.

The CPU 160 of the mobile phone 100 activates the GPS function (step S301).
At this time, the CPU 160 issues a signal transmission instruction to the AWS band communication circuit 150, and determines whether communication is being performed in the AWS band (step S302).
If a signal is transmitted in the AWS band (YES in step S302), it is determined whether or not the channel being used corresponds to a channel other than the 25th channel and the 675-875 channel in the AWS band (step S302). S303). Here, the channels other than the 25th channel and the 675-875 channel mean channels other than the 25th channel and channels other than the 675-875channel.

  When the channel being used corresponds to a channel other than the 25 channel of the AWS band and the 675-875 channel (YES in step S303), the CPU 160 itself sets the amplification factor of the transmission power amplifier 151 to high. Whether or not (step S304). This may be determined, for example, by searching the control log for the transmission power amplifier 151 of the CPU 160, or may be determined by a status flag indicating the amplification factor of the transmission power amplifier 151.

When the amplification factor of transmission power amplifier 151 is set to high (YES in step S304), CPU 160 turns off switch 220, that is, opens (step S307). And CPU160 performs positioning by GPS (step S308).
Even if the AWS band 25 channel and 675-875 channel are used (NO in step S303), or the channel other than the AWS band 25 channel and 675-875 channel is used, the transmission power amplifier 151 If the amplification factor is low (NO in step S304), the process proceeds to step S308.

When CPU 160 does not instruct signal transmission in the AWS band (NO in step S302), CPU 160 determines whether or not the PCS band communication circuit 130 is instructed to transmit a signal using the PCS band next. (Step S305).
When the signal is transmitted in the PCS band (YES in step S305), the CPU 160 determines whether or not the amplification factor of the transmission power amplifier 131 is set to high (step S306). This may be determined, for example, by searching the control log for the transmission power amplifier 131 of the CPU 160, or may be determined by a status flag indicating the amplification factor of the transmission power amplifier 131.

When the amplification factor of the transmission power amplifier 131 is set to high (YES in step S306), the CPU 160 turns off, that is, opens the switch 220. (Step S307). And the positioning function by GPS is performed (step S308).
If communication is not being performed in the PCS band (NO in step S305), or if the amplification factor of the transmission power amplifier 131 is not set to high (NO in step S306), the process proceeds to step S308 and GPS is performed. The positioning function by is executed (step S308).

Although the description has been given here for the case of starting the GPS, the mobile phone 100 transmits the signal in the AWS band or the signal in the PCS band even when positioning by the GPS is required. Triggered by performing the above-mentioned determination before the transmission, that is, whether the amplification factor of the transmission power amplifier is high, or the channel to be used in the case of signal transmission in the AWS band Is a channel other than the 25 and 675-875 channels, the switch 220 is controlled.
<Discussion>
In mobile phone 100 according to the present embodiment, a signal transmitted from antenna 111 may be reflected, diffracted, or directly received by antenna 110. Further, the antenna 110 may receive a signal transmitted from a nearby base station or mobile phone. At this time, the antenna 110 receives two signals unrelated to the signal from the GPS satellite. One of the two signals is a signal having a transmission frequency in the PCS band, and the other is a signal having a transmission frequency in the AWS band. In some cases, although the two signals are attenuated by the filter 170, the components that could not be attenuated are amplified by the low noise amplifier 180, resulting in third-order intermodulation distortion in the GPS band. .

Then, the signal amplified and output by the low noise amplifier 180 includes a component obtained by amplifying the signal from the GPS satellite, a signal component of the PCS band that has been attenuated by the filter 170 and then amplified by the low noise amplifier 180, and the AWS band. , The third-order intermodulation distortion component generated by the amplification of the PCS band signal component and the AWS band signal component.
The signal output from the low noise amplifier 180 is filtered by the filter 171 and then demodulated by the demodulation circuit 190. At this time, the components removed by the filter 171 are the PCS band signal component and the AWS band signal component. Therefore, signal components from other GPS satellites and third-order intermodulation distortion components generated in the GPS band pass through the filter 171.

Then, in the demodulation circuit 190, only the signal component from the main body GPS satellite should be demodulated, but the third-order intermodulation distortion component is included therein as noise, so that it cannot be demodulated correctly.
That is, when the third-order intermodulation distortion generated when the signals of the PCS band and the AWS band are amplified by the low-noise amplifier 180 passes through the filter 171 and overlaps the GPS band, the third-order intermodulation distortion is generated by the low-noise amplifier 180. It is necessary to increase the IP3 of the low-noise amplifier 180 to such an extent that components are not generated as much as possible, or even if they are generated, only a level that can be ignored as an error range is generated. However, it is not always necessary to increase IP3. Particularly problematic here is a third-order intermodulation distortion component that overlaps between 1574.42 MHz and 1576.42 MHz, which is the use band of the GPS band.

Hereinafter, it will be considered how the timing conditions for increasing IP3 as described in <Operation> are determined.
FIG. 4 shows that in each channel (frequency) of the transmission signal of the AWS band and the transmission signal of the PCS band, the signal of the channel is generated at or near the GPS band when passing through the low noise amplifier 3 It is the table | surface which showed the frequency of the next intermodulation distortion.

In the table shown in FIG. 4, the horizontal axis represents the frequency corresponding to the AWS band uplink channel, and the vertical axis represents the frequency corresponding to the PCS band uplink channel. The values corresponding to the respective values are obtained by subtracting the frequency of the PCS band from the frequency twice the frequency of the AWS band.
As shown in FIG. 4, for example, the frequency of the third-order intermodulation distortion generated by amplifying the AWS channel 150 channel signal and the PCS band 175 channel signal by a low noise amplifier is 1576.25 MHz. . As described above, this subtracts the frequency (1858.75) of the PCS band from twice the frequency of the AWS band (1717.50 × 2 = 3435.00) (3435.00-1858.75 = 1576.25). Since the frequency of the third-order intermodulation distortion is between 1574.42 and 1576.42 MHz, it overlaps with the GPS band. On the other hand, for example, the frequency of the third-order intermodulation distortion generated by the 50-band signal in the AWS band and the 175-channel signal in the PCS band is 1566.25 MHz, which does not overlap with the GPS band. In FIG. 4, the black and white inverted display shows the third-order intermodulation distortion overlapping the GPS band. The reason why the 600 and 700 channels of the AWS band in FIG. 4 are not shown is that they are unused channels.

In this way, the frequency of the third-order intermodulation distortion generated when passing through the low noise amplifier 180 is calculated for each of the upstream frequency in the AWS band and the upstream frequency in the PCS band, and the third-order intermodulation distortion is actually calculated. That pass through the filter 171 and overlap with the GPS band can be obtained.
The table shown in FIG. 4 is created considering only the center frequency of each channel in the AWS band and the center frequency of each channel in the PCS band.

The frequency actually used is a frequency band of ± 0.625 MHz of each center frequency. Therefore, FIG. 5 shows a table showing the frequency of the third-order intermodulation distortion generated by the frequency considering ± 0.625 MHz (± 12.5 channels) of each center frequency in order to determine the conditions more strictly. FIG. 5 shows the frequency step width finer than that shown in FIG. 4, and in the same manner as FIG. 4, the portion where the third-order intermodulation distortion overlapping in the GPS band appears is displayed in black and white. In FIG. 5, the unused channels 600 are not shown.
As can be seen from FIG. 5, when a signal is transmitted on 50 channels of the AWS band and a 25-channel signal of the PCS band is received as an interference wave, the frequency used on the 25-channel of the PCS band. It can be seen that third-order intermodulation distortion overlapping with the GPS band appears at 1850.63 MHz on the lower limit side of the band.

Thus, it was found that the mobile communication terminal shown in the present embodiment is affected by third-order intermodulation distortion when a signal is transmitted on a channel other than the AWS channel 25 and 675-875. .
In addition, when transmitting a signal in the PCS band, looking at FIG. 4 alone, it seems that there is no frequency in the AWS band that affects the GPS band in the 1075 channel and the 1100 channel, but the frequency band used is also considered. As can be seen from FIG. 5, it was also found that the mobile phone 100 is affected by third-order intermodulation distortion that occurs with any channel signal in the AWS band.

Therefore, in the mobile phone 100 according to the present embodiment, the switch 220 is opened under the following two conditions, and is kept conductive otherwise. The two conditions are:
(Condition 1) When the mobile phone 100 is in the AWS band, communication is being performed on a channel other than the 25th channel and the 675-875th channel, and the amplification factor of the transmission power amplifier 151 is set to high (Condition 2) This is a case where the mobile phone 100 is communicating in the PCS band and the amplification factor of the transmission power amplifier 131 is set to high.

Note that the power value of the third-order intermodulation distortion is negligible as an error range unless the mobile phone 100 transmits at a high output, so the above-mentioned frequency condition and transmission power are high. The condition is that the output, that is, the transmission power is higher than a predetermined reference.
As a result, the mobile phone 100 opens the switch 220 in order to increase IP3 only when the above-described conditions are met, and in other cases, the collector current can be reduced, and at the time of transmission in the PCS band, the AWS When transmitting on channels other than the 25 and 675-875 channels, the PCS band signal and the AWS band signal can suppress the effect of third-order intermodulation distortion that occurs during amplification by the low noise amplifier 180. .
<Supplement>
Although the present invention has been described in the above embodiment, the present invention is of course not limited thereto. Hereinafter, various modified examples included in the present invention other than the above-described embodiment will be described.
(1) In the above embodiment, the switch 220 is opened when a signal is transmitted at a high output on a channel other than the 25 channel of the AWS band and the 675-875 channel. However, the channel is determined by the use band of the GPS band (1574.42 MHz to 1576.42 MHz). Therefore, when the use band of the GPS band is changed, the condition for opening the switch 220 may be changed according to the changed band. Specifically, using the table showing the third-order intermodulation distortion shown in FIG. 4, a channel in which the frequency of the third-order intermodulation distortion overlaps the use band of the GPS band is selected, and in the case of that channel, the switch 220 is selected. Will be released.
(2) In the above embodiment, the switch 220 is provided between the ground and the resistor 210e. However, the switch 220 is a conductive / non-conductive switch between the base of the transistor 200 and the resistors 210d and 210e to the ground. It may be anywhere as long as the state can be controlled. For example, it may be provided between the resistor 210d and the base electrode of the transistor 200.
(3) In the above embodiment, the mechanism for setting the amplification factor of the transmission power amplifier has not been described in detail as being conventionally used. Two amplification stages are provided. When the amplification factor is high, the transmission signal is passed through the two amplification stages. When the amplification factor is low, the transmission signal is passed through only one amplification stage. A circuit mechanism is configured, and the number of amplification stages to be passed through is switched by, for example, a switching element.
(4) In the above-described embodiment, the transmission power amplifier is described as being capable of selecting two states of amplification rate, high or low. However, this is not limited to these two states, and may be, for example, three states of high, middle, and low. At this time, for example, only when it is high, or it becomes high or middle. The switch 220 may be opened during In the case of high, middle, and low, the power amplifier for transmission is provided with three amplification stages. In the case of high, three amplification stages are passed, in the case of middle, two stages are passed, and in the case of low, one amplification stage is passed. The configuration to be taken is taken. Note that the high, middle, and low configurations of the three-stage switching power amplifier are not limited to this, and other configurations can be used as long as they are not contrary to the spirit of the present invention.

Alternatively, the power amplifier for transmission may be one that can arbitrarily set the amplification factor.In this case, it is determined whether the transmission power is high or not depending on whether the amplification factor is higher than a predetermined reference value. When the amplification factor exceeds the reference value, control may be performed such that the switch 220 is opened.
The reference value is a range of errors caused by a third-order intermodulation distortion component that can be generated when a signal amplified by the transmission power amplifier is transmitted from the antenna 111, received by the antenna 110, and amplified by the low noise amplifier 180. Determine and set lines that cannot be ignored.
(5) In the above embodiment, the base station does not particularly describe a reference for transmitting a control signal for requesting transmission of a signal at a high output. When the signal reception intensity is lower than 13.4 dBm, a control signal requesting transmission of a signal at a high output is transmitted to the mobile phone. The standard may have different values depending on the service.
(6) The control mechanism of the low noise amplifier 180 shown in the above embodiment is not limited to this. Any mechanism that can control the increase / decrease of the collector current may be used. For example, the control may be executed by a circuit as shown in FIG.

  In the circuit illustrated in FIG. 6, a resistor 610 a and a resistor 610 b are connected in series to the emitter of the transistor 200, and a collector of the bipolar transistor 600 is connected to an intermediate point between the resistors 610 a and 610 b. The emitter is grounded, and a resistor 610c is connected to the base. The resistor 610c and the switch 220 are connected. The switch 220 is switched between conductive and non-conductive under the control of the CPU 160 as in the above embodiment.

When the switch 220 is made conductive, the internal resistance of the transistor 600 is originally small, so that an emitter current flows through the path of the resistor 610a → the transistor 600.
On the other hand, when the switch 220 is turned off, the transistor 600 is regarded as not being present, and the emitter current flows through a path from the resistor 610a to the resistor 610b. As for the resistance value of the resistor 610b and the internal resistance of the transistor 600, the resistance value of the normal resistor 610b is higher. As a result, the magnitude of the emitter current can be controlled depending on whether the switch 220 is conductive or non-conductive. Since the emitter current can be controlled, the current amount of the collector current can also be controlled from the relationship of I _E (emitter current) = I _B (base current) + I _C. What is necessary is just to control the magnitude of collector current by controlling non-passage.
(7) In the above embodiment, a mobile phone has been described as an example of a mobile communication terminal. However, the mobile communication terminal according to the present invention has a GPS function and performs communication in the AWS band and PCS band. Any mobile communication terminal may be used as long as it has a.
(8) In the above-described embodiment, the mobile phone 100 has been described as having a function of executing communication in any of the PCS band, the AWS band, and the Cellular band. However, with regard to the communication function in the Cellular band, It does not have to be implemented. In addition, when the mobile phone 100 has a function of executing communication only in the AWS band, the mobile phone does not control when transmitting in the PCS band, but considers only when transmitting in the AWS band. Will be performed.
(9) In the above embodiment, the GPS antenna 111 and the communication antenna 110 are described as separate antennas. However, each communication circuit and the GPS reception system may share one antenna. .
(10) In the above embodiment, when it is necessary to transmit a signal during the execution of the GPS function and the AWS band is used, the mobile phone 100 uses 25 channels as the frequency band to be used. Alternatively, the base station may be requested to use any one of the channels 675 to 875, and the signal may be transmitted on the channel.
(11) In the above embodiment, the low noise amplifier has been described as an example of the amplifier. However, this is not limited to the low noise amplifier, and the signal can be amplified and the third order intermodulation distortion is generated by the amplification. If there is, it becomes a control target.
(12) An operation related to the control of the low noise amplifier by taking into account the communication during execution of the GPS function shown in the above-described embodiment, an on / off process of the switch 220 (see FIG. 3), etc. A control program composed of program codes to be executed by various circuits connected to the processor can be recorded on a recording medium, or can be distributed and distributed via various communication paths. Such recording media include IC cards, hard disks, optical disks, flexible disks, ROMs, and the like. The distributed and distributed control program is used by being stored in a memory or the like that can be read by the processor, and the processor executes the control program, thereby realizing various functions as shown in the embodiment. Will come to be.

  The mobile communication terminal according to the present invention is capable of communication in both the PCS band and the AWS band, and is affected by the third-order intermodulation distortion of the PCS band and the AWS band in a mobile phone equipped with a GPS function. It can be used as a mobile phone that can achieve power saving while suppressing.

100 Mobile phone (mobile communication terminal)
110, 111 Antenna 120 Switch 130 PCS band communication circuit 131 Transmission power amplifier 140 Cellular band communication circuit 150 AWS band communication circuit 151 Transmission power amplifier 160 CPU (control unit)
170 filter (first filter)
171 filter (second filter)
180 Low noise amplifier 190 Demodulator circuit 200, 600 Transistors 210a, 210b, 210c, 210d, 210e, 610a, 610b, 610c Resistor 220 Switch 230 Capacitor

Claims (5)

A mobile communication terminal having a GPS (Global Positioning System) function, a function for executing communication in the AWS (Advanced Wireless Services) band, and a function for executing communication in the PCS (Personal Communication Service) band,
An antenna,
An amplifier that amplifies and outputs the signal output from the antenna;
This occurs when the terminal is communicating on a predetermined channel among a plurality of channels in the AWS band, and the signal in the frequency band of the predetermined channel and the signal in the PCS band are amplified by the amplifier 3 If the second order intermodulation distortion overlaps with or occurs in the vicinity of the GPS band, and the transmission power is higher than a predetermined power value, the third order intercept point (3rd order point) of the amplifier A mobile communication terminal comprising: a control unit that executes control for increasing an Intercept Point). The amplifier is a low noise amplifier using a bipolar transistor whose emitter is grounded,
The control unit is communicating with a predetermined channel among a plurality of channels in the AWS band, and a signal in a frequency band of the predetermined channel and a signal in the PCS band are amplified by the amplifier. When the third-order intermodulation distortion caused by the above overlaps with or occurs in the vicinity of the GPS band, and the transmission power is higher than a predetermined power value, the base potential of the low noise amplifier The mobile communication terminal according to claim 1, wherein the third-order intercept point is increased by executing a control to increase the third-order intercept point higher than a predetermined reference potential. The amplifier includes a configuration in which a resistance element and a switch are connected in series, one end of the resistance element is connected to a base of the bipolar transistor, and one end of the switch is grounded.
The mobile communication terminal according to claim 2, wherein the control unit increases the base potential by opening the switch. The control unit performs control to make the base potential of the low noise amplifier higher than a predetermined reference potential even when the terminal is communicating in the PCS band and the transmission power is higher than a predetermined power value. The mobile communication terminal according to claim 3. The predetermined channel is any one of channels other than the 25 channels of the AWS band and channels other than the 675 to 875 channels,
The mobile communication terminal according to claim 2, wherein the GPS band is a frequency band of 1574.42 MHz to 1576.42 MHz.

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