KR950006934Y1 - Circuit for switching received intermediate frequency of wireless console unit - Google Patents

Abstract

No content.

Description

Frequency switching circuit during reception of wireless terminal

1 is an intermediate frequency switching circuit diagram of a wireless terminal according to the present invention.

2 is a detailed view of an intermediate frequency signal processor according to FIG. 1;

3 is a voice signal level characteristic diagram compared to a received RF level according to the present invention.

* Explanation of symbols for main parts of the drawings

1 antenna 2 transceiver

3: low noise amplification section 4: mixing section

5: first intermediate frequency amplifier 6: intermediate frequency signal processing unit

7: first intermediate frequency amplifier control unit 8: microprocessor

9: receiving local oscillator

The present invention relates to a switching circuit of a receiver intermediate frequency amplifier in a wireless terminal using a battery as a power source, and in particular, by sensing the signal field strength according to the distance between the base station and the terminal, the receiver does not affect the receiver characteristics. The present invention relates to a receiving intermediate frequency switching circuit of a wireless terminal for disabling an intermediate frequency (IF) amplifier in a strong field intensity region, thereby reducing a terminal current consumption.

In the conventional wireless terminal, since the intermediate frequency amplifier is always enabled regardless of the electric field strength of the received signal, there is no function to save the current consumption (about 3-4 mA) in the intermediate frequency amplifier.

Therefore, the present invention measures the electric field signal strength from the base station in accordance with the trend to extend the battery life in the battery product, and then in the case of the electric field signal strength that does not affect the normal call quality, An object of the present invention is to provide an intermediate frequency signal processing circuit of a wireless terminal for disabling the first intermediate frequency amplifier during signal processing to reduce power consumption and extend the life of a battery.

The object of the present invention is a mixer that receives a signal received through a transceiver and a low noise amplifier and mixes it with a receiving local oscillation signal, and an intermediate frequency (IF) at the front end for the intermediate frequency processing of the received signal output from the mixer. In a reception processing system of a wireless terminal comprising a first intermediate frequency amplifier for amplification and an intermediate frequency processing unit for performing intermediate frequency (IF) signal processing and outputting a demodulated signal, the received electric field strength signal from the intermediate frequency processing unit A microprocessor which receives the RSSI and generates a control signal by comparing it with a predetermined reference value, and disables the first intermediate frequency amplifier under the control of the microprocessor, so that an output signal of the mixer is directly transmitted to the intermediate frequency processor. It is achieved by configuring a first intermediate frequency amplifier control unit for controlling the Described in detail with reference to the drawings as follows.

1 is a diagram of an intermediate frequency signal processing circuit of a wireless terminal according to the present invention. As shown in FIG. 1, a transmitting and receiving unit 2 for transmitting and receiving data through an antenna 1 and the transmitting and receiving unit 2 are provided. A low noise amplifier 3 for low noise amplifying a signal received through the receiver, a reception local oscillator 9 for oscillating a reference frequency for demodulation of a received signal, a reference frequency of the reception local oscillator 9, and the low noise amplification unit (3) a mixing unit 4 for mixing the received signal, a first intermediate frequency amplifier 5 for amplifying the output signal of the mixing unit 4 in advance for intermediate frequency processing, and the first intermediate frequency An intermediate frequency processor (6) which receives the output signal of the amplifier (5) and demodulates the received signal by intermediate frequency (IF) signal processing to output a demodulated signal, and measures and outputs the received electric field strength; Before reception of the processing unit 6 A microprocessor 8 which receives the intensity RSSI and compares it with a reference value and outputs a disable signal to the first intermediate frequency amplifier 5 and a control signal of the microprocessor 8. A first intermediate frequency amplifier controller 7 controls the first intermediate frequency amplifier 5.

Here, the intermediate frequency processor 6 receives the output signal of the first intermediate frequency amplifier 5 through the band pass filter 6a as shown in FIG. 2 and oscillates the second local oscillator 6c. A second mixing unit 6b for mixing with a frequency; a second intermediate frequency amplifying unit 6e for receiving and amplifying the output signal of the second mixing unit 6b through a band pass filter 6d; The output signal of the intermediate frequency amplifier 6e is input through the band pass filter 6f to limit the threshold value and output as a received signal, thereby limiting the voltage detected from the second intermediate frequency amplifier 6e. And a limiter 6g outputting the electric field strength signal voltage RSSI and a demodulator 6h demodulating the received signal output from the limiter 6g and outputting it as a report signal.

The operation and effects of the intermediate frequency switching circuit during the reception of the inventive wireless terminal configured as described above are as follows.

A communication signal is received by the transmitting and receiving unit 2 through the antenna 1 of the wireless terminal, and the signal received through the transmitting and receiving unit 2 is low-pass amplified by the low noise amplifying unit 3, and this low-pass amplification is performed. The mixed signal is mixed with the carrier generated by the receiving local oscillator 9 in the mixing section 4.

In this way, the received signal on the carrier which becomes the reception reference frequency is amplified by the first intermediate frequency amplifier 5 and then input to the intermediate frequency processor 6 and output as a demodulated signal by intermediate frequency processing.

At this time, the intermediate frequency processor 6 receives the output signal of the first intermediate frequency amplifier 5 and passes the necessary signal band through the band pass filter 6a, and the signal through the band pass filter 6a is mixed. In (6b) it is mixed with the oscillation signal of the second local oscillator 6c and outputted to the band pass filter 6a.

The signal through the bandpass filter 6d is amplified by the second intermediate frequency amplifier 6e and again input to the limiter 6g through the bandpass filter 6f.

The limit signal of the limiter 6g is output as a demodulation signal through the demodulator 6h.

Here, the voltage level signal of the second intermediate frequency amplifier 6e is output as the received field strength signal RSSI voltage.

Accordingly, the microprocessor 8 receives the received field strength signal RSSI voltage and compares the received field strength signal RSSI voltage with a reference value for field strength that does not affect the receiver characteristics even if the gain of the receiving block is reduced. In this larger case, a control signal is output to disable the first intermediate frequency amplifier 5.

By this control signal, the first intermediate frequency amplifier control unit 7 disables the first intermediate frequency amplifier 5 so that the output signal of the mixer 4 is not directly passed through the first intermediate frequency amplifier 5, but directly to the intermediate frequency signal. Since the switching is input to the processor 6, the power consumed by the first intermediate frequency amplifier 5 is reduced in an area where the received electric field strength is strong.

As described in detail above, the present invention measures the strength of the received electric field signal transmitted from the base station so as not to use the first intermediate frequency amplifier in a region above a predetermined level, thereby maintaining the normal call quality while maintaining the first intermediate frequency amplifier. It can reduce current consumption by about 5mA, which can extend from 18 hours up to 10% (about 1 hour 30 minutes). This eliminates the problem that the first intermediate frequency amplifier is saturated and generates unnecessary radiation waves, thereby degrading the call quality, thereby increasing the call quality.

Claims (2)

Transmission and reception means for transmitting and receiving data transmitted and received through an antenna; low noise amplification means for low-pressure amplifying a signal received through the transmission and reception means; and reception local oscillation means for oscillating a reference frequency for demodulation of a received signal; Mixing means for mixing the reference frequency of the receiving local oscillating means and the received signal through the low noise amplifying means, first intermediate frequency amplifying means for amplifying the output signal of the mixing means in advance for intermediate frequency processing, and the first means. 1) intermediate frequency processing means for receiving an output signal of an intermediate frequency amplifying means and demodulating a received signal by intermediate frequency (IF) signal processing to output a demodulated signal, and measuring and outputting a received electric field strength; The first intermediate frequency amplification number is received by receiving the received field strength (RSSI) of the means and comparing the reference value with the reference value. And a first intermediate frequency amplifier control means for controlling the first intermediate frequency amplifying means by a control signal of the microprocessor. Switching circuit. The method of claim 1, wherein the intermediate frequency processing means is a second mixing means for receiving the output signal of the first intermediate frequency amplifying means through a first band pass filter and mixing with the oscillation frequency of the second local oscillator; Second intermediate frequency amplifying means for receiving and amplifying the output signal of the mixing means through the second band pass filter, and receiving the output signal of the second intermediate frequency amplifying means through the third band pass filter to limit the limit value. A demodulator outputting the received signal, limiting the voltage detected by the second intermediate frequency amplifying means to output the field strength signal voltage (RSSI), and demodulating the demodulated signal and demodulating the received signal output from the limiter. A receiving intermediate frequency switching circuit of a wireless terminal, characterized in that consisting of means.