KR0140418B1 - Cellular phone - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

Portable cordless phone

2. The technical problem to be solved by the invention

Fine adjustment of frequency deviation in portable radiotelephone

3. Summary of the Solution of the Invention

A method for compensating frequencies in a portable radiotelephone includes generating a corresponding channel frequency as a first reference frequency when selecting a channel, and generating a first intermediate frequency by combining the received radio signal with the first reference frequency. And synthesizing the first intermediate frequency and the second reference frequency to generate a second intermediate frequency, detecting the reception sensitivity strength at the second intermediate frequency, and multiplying the reception sensitivity strength and the reference sensitivity strength. When the reference sensitivity is large in the comparing process, the step of increasing the first reference frequency and then returning to the process of generating the first intermediate frequency; and in the comparing process, the reference sensitivity is small. And reducing the first reference frequency and then returning to generating the first intermediate frequency.

4. Important uses of the invention

In the portable radiotelephone, the frequency deviation is finely adjusted to demodulate the received signal at the optimum level.

Description

Frequency Compensation Method and Apparatus of a Portable Cordless Telephone

1 is a diagram showing the configuration of a receiver of a portable radio telephone according to the present invention.

2 is a flowchart for compensating for frequency deviation in a portable radiotelephone according to the present invention.

The present invention relates to a method and apparatus for compensating the frequency of a portable radiotelephone, and more particularly, to a method and apparatus for measuring the sensitivity of a signal received from a portable radiotelephone to compensate for the frequency deviation in an optimal state.

In general, a portable radiotelephone is a mobile communication device and communicates wirelessly with a cell site allocated to a certain cell. Such a system is called a cellular system. The cellular system includes an ETACS system and an EAMPS system. The frequency synthesis in the portable radiotelephone synthesizes the required number of cellular systems (ETACS system = 1320, EAMPS system = 832) using a reference frequency.

Dozens of conventional portable radiotelephones typically use a superheterodyne receiver that converts the frequency of the signal received in two stages. In the portable wireless telephone using the super heterodyne method, the first reference frequency oscillator for performing the first frequency conversion uses a temperature compensated oscillator, and the second reference frequency oscillator for performing the second frequency conversion Use a common crystal oscillator. The first reference frequency converting means generates an intermediate frequency of the channel selected by the first reference frequency as the channel selection information, generates an intermediate frequency of the channel selected by the second frequency, and the second frequency converting means. Generates a converted signal so that it can demodulate the intermediate frequency received in the latter stage. In this case, the frequency deviation of the temperature compensated oscillator has a 2.5PPPM standard, so that the first reference frequency can be accurately generated, but the second reference frequency has a frequency deviation of 15PPM.

However, since the first reference frequency and the second reference frequency are fixed in the portable radiotelephone as described above, it is impossible to compensate for the frequency difference caused by the surrounding environment. In addition, the frequency deviation is different according to each component constituting the portable radiotelephone, it is difficult to constant compensation. In addition, when a user uses a portable radiotelephone mounted in a vehicle, the frequency deviation becomes larger according to the Doppler effect, which causes noise to degrade the call quality.

Accordingly, an object of the present invention is to provide a method and apparatus for improving call quality by compensating for frequency deviation by analyzing signal strength received from a portable radiotelephone.

Another object of the present invention is to compensate for the first reference frequency of the first frequency conversion means by measuring the sensitivity of the signal received on the selected channel in the receiver of the portable radiotelephone having the first frequency conversion means and the second frequency conversion means Therefore, the present invention provides a method and apparatus capable of maintaining an optimal channel state at all times.

Means for generating a first intermediate frequency by synthesizing the received radio signal and the first reference frequency to achieve the objects of the present invention, and the first intermediate frequency and the second reference frequency Synthesizing means to generate a second intermediate frequency, means for detecting a reception sensitivity at the second intermediate frequency, generating first and second divided data for generating the first reference frequency, A control means for increasing the first division data when the reference sensitivity intensity is large by comparing the reception sensitivity intensity with the reference sensitivity intensity, and reducing the first division data when the reference sensitivity intensity is small, and a phase synchronous loop means. And means for loading the first division data and the second division data, respectively, and generating the first reference frequency according to the difference between the two division data. , By controlling the first reference frequency in accordance with the change of the reception strength it is adaptively characterized in that for compensating for the deviation of the received frequency.

In addition, in order to achieve the object of the present invention, the frequency compensation method of a portable radiotelephone includes generating a corresponding channel frequency as a first reference frequency when selecting a channel, synthesizing a received radio signal with the first reference frequency, and Generating a first intermediate frequency, synthesizing the first intermediate frequency and the second reference frequency, generating a second intermediate frequency, detecting a reception sensitivity strength at the second intermediate frequency, and receiving the sensitivity Comparing the intensity with the reference sensitivity intensity, increasing the first reference frequency when the reference sensitivity intensity is large in the comparison process, and then returning to generating the first intermediate frequency; When the reference sensitivity is small, the process of returning to the process of generating the first intermediate frequency after reducing the first reference frequency Gong.

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

The term reception sensitivity used herein refers to a signal representing the strength of a reception signal detected by a current first reference frequency. The term reference sensitivity intensity is the strength of the received signal detected by the second intermediate frequency in the previous state. That is, the reception sensitivity strength of the previous state becomes the reference sensitivity strength in the next state.

1 is a block diagram of a receiver of a portable radiotelephone according to the present invention. A duplexer filter 11 is connected to an antenna and performs a function of separating a transmission radio signal and a reception radio signal. The low noise amplifier 12 is connected to the duplexer 11 and amplifies the received radiofrquency RF with low noise. A band pass filter 13 is connected to the low noise amplifier 12 and filters the amplified radio signal RF into a signal band and outputs it. Such a configuration becomes a means for receiving a radio signal. In this case, in the case of the ETACS system, the frequency of the received radio signal RF is 917 MHz to 950 MHz. In this case, the band of the band filter 13 may be set to the frequency band of the corresponding system. At this time, the received signal has a deviation equal to the frequency deviation of the system.

The first mixer 14 receives a first local frequency LF1 and a radio signal RF, and mixes the two signals and outputs the mixed signals. The signal output from the first mixer 14 becomes | RF ± LF1 |. The band filter 15 filters the signal band | RF-LF1 | from the | RF ± LF1 | output from the first mixer 14 and outputs the signal at the first intermediate frequency IF1. Accordingly, the band filter 15 is a first intermediate frequency band filter for selectively filtering and outputting the first intermediate frequency IF1 at the output of the first mixer 14. The amplifier 16 is a first intermediate frequency band filter output from the band filter 15. The amplifier 16 becomes a first intermediate frequency amplifier for amplifying the first intermediate frequency IF1 output from the bandpass filter 15. Such a configuration becomes a first frequency converting means for converting the received radio signal RF into a first intermediate frequency IF1.

The second mixer 17 mixes and outputs the first intermediate frequency IF1 and the second reference frequency LF2 output from the amplifier 16. The signal output from the second mixer 17 becomes | F1 ± LF2 |. The band filter 18 filters the | IF-LF2 | signal band from the | IF ± LF2 | output from the first mixer 17 and outputs the second intermediate frequency IF2. Accordingly, the band filter 18 is a second intermediate frequency band filter for selectively filtering and outputting the second intermediate frequency IF2 at the output of the second mixer 18. The amplifier 19 is a first intermediate frequency amplifier for amplifying the second intermediate frequency IF2 output from the band filter 18. This configuration serves as a means for converting the first intermediate frequency IF1 to the second intermediate frequency IF2.

Here, the oscillator 28 generating the second reference frequency LF2 typically uses a crystal oscillator.

A Receive Signal Strength Indicator detector 20 receives the output of the amplifier 19 and detects the level of the second intermediate frequency IF2 to generate a receive sensitivity strength RSSI2. Here, the reception sensitivity strength RSSI2 represents a sensitivity strength of a signal detected at a current frequency and is used as a comparison sensitivity signal when correcting a frequency deviation.

The band filter 21 receives the output of the RSSI detector 20 and outputs the filter in the band of the second intermediate frequency IF2. The demodulator 23 demodulates the signal of the second intermediate frequency band output to the band filter 21 and reproduces the original signal.

In the above configuration, the first mixer 17, the amplifier 19, the RSSI detector 20, the amplifier 22, and the demodulator 23 can use a 606DK manufactured and sold by Philips as a demodulation integrated circuit.

The signal processor 24 digitally processes the demodulated signal output from the demodulator 23 and restores the original signal. The signal in the demodulator 23 becomes a signal or voice of a portable radiotelephone. The signal processor 24 may use a digital signal processor.

An analog-to-digital converter 25 converts the received sensitivity strength RSSI into digital data. The control unit 27 receives the output of the A / D converter 25 at regular intervals and generates the first division data N1 and the second division data N2 for selecting a channel having the largest reception sensitivity. Here, the second frequency division data N2 is a selected channel frequency and means frequency division data for generating the first reference frequency LF1. In addition, the first division data N1 refers to the distribution data for compensating for the deviation caused by the surrounding environment upon reception. Accordingly, the controller 27 sets the second division data N2 to the frequency of the selected channel and sets the first division data N1 to a value corresponding to the reference clock signal. The memory 26 stores the reception sensitivity strength of the previous state output from the controller 27 as the reference sensitivity strength. Therefore, the control unit 27 receives the received sensitivity and compares it with the reference sensitivity. If the reference sensitivity is large, the first division data N1 is increased, and if the reference sensitivity is small, the first division data N1 is decreased. Let's do it. Accordingly, it can be seen that the controller 27 compensates for the variation in the reception frequency by adaptively controlling the period of the click according to the change in the received sensitivity. The controller 27 stores the currently received received sensitivity strength RSSI2 in the memory 26 for use as the reference sensitivity strength RSSI1 of the next state. Such a configuration becomes a logic custom integrated circuit (Iogic custom IC).

The oscillator 31 is a temperature compensated oscillator and generates a reference clock signal for generating the first reference frequency LF1. The oscillator 31 generates a stable frequency in response to changes in the temperature of the surrounding environment, and has a frequency deviation of 2.5 PPM. The first divider 32 loads the first divided data N1 output from the controller 27, counts the output of the oscillator 31, and outputs a first divided signal. The second divider 33 loads the second divided data N2 output from the controller 27, counts the first reference frequency, and outputs a second divided signal. The comparator 34 compares the outputs of the first and second dividers 32 and generates a difference signal between the two divided signals. Amplifier 35 amplifies and outputs the output of the comparator 35. The low pass filter 36 receives the output of the amplifier 35 and generates a DC voltage. The voltage controlled oscillator 37 is oscillated according to the magnitude of the voltage output from the low pass filter 36 to generate the first reference frequency LF1. Such a configuration becomes a means for generating the first reference frequency LF1. Referring to the operation of issuing the first reference frequency LF1, the value of the first division data N1 is increased or decreased according to the sensitivity strength of the received signal, and the first reference frequency LF1 is changed according to this change to adaptively. It can be seen that the frequency deviation is compensated for. In the above configuration, the first divider 32, the second divider 33, the comparator 34 and the amplifier 35 are PLL integrated circuits, and MB15BO1 manufactured and sold by Fujitsu Corporation can be used.

In the case of the ETACS system, the received signal RF output from the duplexer 11 is a signal having a band of 917 MHz to 950 MHz as described above. A portable radiotelephone using a super heterodyne receiver includes a first frequency converting means and a second frequency converting means. In the present invention, a means for generating the first reference frequency LF1 of the first frequency converting means is implemented using a PLL. At this time, the PLL inputs the second division data N2 for setting the channel frequency and the first division data N1 for controlling the reference clock to a value corresponding to the reception sensitivity, and adaptively adjusts the deviation of the reception frequency generated by the surrounding environment. To compensate. That is, the first divided data N1 which varies according to the change in reception sensitivity is compared with the second divided data N2 which means the frequency of the selected channel, and the voltage controlled oscillator 37 is controlled according to the difference between the two divided data. Generate the reference frequency LF1. At this time, the first reference frequency LF1 output from the voltage controlled oscillator 37 becomes 1009 MHz-1042 MHz.

The first mixer 14 mixes the received signal RF and the first reference frequency LF1, and the band filter 15 generates a first intermediate frequency IF1 by down converting a low frequency from the mixed signal. At this time, the second reference frequency LF2 generated by the oscillator 28 is 91.5325 MHz. Then, the second mixer 17 mixes the first intermediate frequency IF1 and the second reference frequency LF2, and the band filter 18 filters the low frequency from the mixed signal to generate the second intermediate frequency IF2. At this time, the second inter-frequency IF2 has a band of 455 KHz.

At this time, the RSSI detector 20 outputs a DC level according to the magnitude of the second intermediate frequency IF2 level. That is, the reception sensitivity strength RSSI2 is detected. Then, the A / D converter 25 converts the reception sensitivity strength RSSI2 into digital data and outputs the digital data to the control unit 27. Then, the control unit 27 compares the reception sensitivity strength RSSI2 with the reference sensitivity strength RSSI1 and controls the generation of the first reference frequency LF1. In this case, when the reference sensitivity strength RSSI1 is greater than the reception sensitivity strength RSSI2, the first division data N1 is increased. When the reference sensitivity strength RSSI1 is less than the reception sensitivity strength RSSI2, the first division data N1 is decreased. In the present invention, the amount of increase / decrease of the first frequency division data N1 is set to 100 Hz to finely adjust the deviation compensation of the first reference frequency LF1.

Looking at the frequency deviation compensation process according to the present invention in the portable radiotelephone having the configuration as described above with reference to the flowchart of FIG. 2, the control unit 27 selects arbitrary channels while changing the second division data N2, and selects the selected channel. It analyzes the received sensitivity strength RSSI2 and checks whether a signal is detected in the selected channel. The beginning of the flowchart as shown in FIG. 2 shows a procedure of an operation of compensating for frequency deviation by measuring reception sensitivity of a selected channel in a state in which an arbitrary reception channel is set.

First, when a received signal is detected in an arbitrary channel, the controller 27 determines the initial division ratio of the means for generating the first reference frequency LF1 in step 211. That is, the controller 211 loads the first division data N1 into the first divider 32 and the second division data N2 into the second divider 33 in step 211. Here, it is assumed that the oscillator 31 is a temperature compensated oscillator generating a frequency of 12.8 MHz, and the frequency of the selected channel is 1009 MHz. Then, when the initial channel is selected, the first division data N1 may be set to 128,000 and the second division data N2 may be set to 10,090,000.

When the first divided data N1 and the second divided data N2 are output as described above, the first divider 32 starts to count the clock output from the oscillator 31 after loading the first divided data N1. The divider 33 loads the second division data N2 and starts counting the first reference frequency LF1 output from the voltage controlled oscillator 37. The comparator 34 compares and outputs the divided signals output from the two dividers 32 and 33, and the low pass filter 36 generates a voltage value according to the difference between the two divided signals. Thus, the voltage controlled oscillator 37 generates the voltage. 1 Reference frequency LF1 is generated.

When the channel is selected in the initial driving state as described above, the first mixer 14 mixes the first reference frequency LF1 and the received signal RF, and the band filter 15 filters the first intermediate frequency band of the low band from the mixed signal. Selective output with intermediate frequency IF1. In addition, the second mixer 17 mixes the first intermediate frequency IF1 and the second intermediate frequency LF2, and the band filter 18 filters and outputs the second intermediate frequency IF2 by filtering the low frequency intermediate frequency band from the mixed signal. Then, the RSSI detector 20 detects the level of the second intermediate frequency to generate a reception sensitivity strength RSSI2. The A / D converter 25 converts the reception sensitivity strength RSSI2 into digital data and outputs the digital data.

In this case, the control unit 27 receives the reception sensitivity strength RSSI2 from the A / D converter 25 at a predetermined period in step 213, and stores the reception sensitivity strength RSSI2 received in step 215 as the reference sensitivity strength RSSI. In operation 217, the first dispensing data N 1 is increased. As described above, the reception of the received sensitivity strength RSSI2 is performed at regular intervals, and it can be seen that the RSSI2 received in the previous state is used as the reference sensitivity strength RSSI1 in the next state.

Here, the first intermediate frequency LF1 is 91.9875 MHz and the second intermediate frequency is demodulated at 455 KHz, but is not demodulated to the maximum level having a frequency deviation. Accordingly, the reception sensitivity RSSI2 value is also changed. Accordingly, when the RSSI2 is received, the controller 27 compares the RSSI2 currently received and the RSSI1 previously received and stored in step 221. In this case, if the RSSI1 value is greater than or equal to the RSSI2 value, the RSSI2 is stored as the RSSI1 in the memory 26 in step 215, and the first division data N1 is increased by one in step 217. In this case, the first division data N1 is increased by 1, which means that the first reference frequency LF1 is increased by 100 Hz. That is, when the first reference frequency LF1 that is currently generated is 1009 MHz, when the first frequency division data N1 is increased by 1, the first reference frequency LF1 is changed to 1009.0001 MHz by the PLL. As a result, the first intermediate frequency IF1 and the second intermediate frequency IF2 also increase by 100 Hz.

In addition, as a result of comparing the RSSI2 currently received and the RSSI1 previously received and stored in step 221, if the value of the RSSI1 is smaller than the value of the RSSI2, the received RSSI2 is also stored as the RSSI1 in the memory 26 in step 223. In operation 225, the first sentence data N1 is decreased by two. In this case, the first division data N1 is increased by 2, which means that the first reference frequency LF1 is decreased by 200 MHz. That is, when rddn having the first reference frequency LF1 generated at 1009 MHz and the first divided data N1 are increased by 1, the first reference frequency LF1 is changed to 1009.9998 MHz by the PLL. As a result, the first intermediate frequency IF1 and the second intermediate frequency IF2 are also reduced by 200 Hz. Therefore, when an arbitrary channel is set, the control unit 27 receives the reception sensitivity strength RSSI2 at regular intervals, and then finely adjusts the first division data N1 by comparing the RSSI2 with the RSSI1 in a previous state. Therefore, it can be seen that the first division data N1 performs a function of finely increasing or decreasing the division ratio of the oscillator 31 as a result. By repeating the above process, the first reference frequency LF1 finely compensates for the deviation according to the change in the reception sensitivity, thereby demodulating the signal received at the optimal level in the selected channel.

In addition, by adjusting the first reference frequency LF1 as described above, even in the case of the transmission using the same reference frequency of the deviation adjustment, since the correct frequency is transmitted, the transmission frequency can be compensated.

Claims (6)

A frequency compensating apparatus for a portable radio telephone, comprising: means for generating a first intermediate frequency by synthesizing a received radio signal and a first reference frequency, and synthesizing a second intermediate frequency by synthesizing the first intermediate frequency and the second reference frequency; Means for generating, means for detecting a reception sensitivity at the second intermediate frequency, and generating first and second division data for generating the first reference frequency, wherein the reception sensitivity and the reference sensitivity are generated. Comparing the intensity, the control means for increasing the first division data when the reference sensitivity intensity is large, and reducing the first division data when the reference sensitivity intensity is small, and the ideal synchronization loop means, the first division data and the first Two dividing data are respectively loaded, and means for generating the first reference frequency according to the difference between the two dividing data are included. Adaptively to the frequency compensation device for a portable radio telephone, characterized in that for compensating for the deviation of the reception frequency by controlling the first reference frequency. 2. The apparatus of claim 1, wherein the control unit generates an analog / digital converter for converting the reception sensitivity into digital data, and the first division data corresponding to the reference clock and the second division data corresponding to the selected channel frequency. A control unit for detecting the reception sensitivity intensity at a set period and increasing the first division data when the reference sensitivity strength is large and decreasing the first division data when the reference sensitivity strength is small, compared with the reference sensitivity strength, And a memory for storing the received sensitivity intensity outputted from the controller as a reference sensitivity intensity. The twelfth divider according to claim 2, further comprising: a means for generating a first reference frequency, an oscillator for generating a reference clock, and a load of the first division data to divide the output of the oscillator to generate a first division signal. And a second divider which loads the second divided data and divides the first reference frequency to generate a second divided signal, and compares the first divided signal and the second divided signal to obtain a difference between the two divided signals. A portable radio comprising: a comparator for generating a signal, a low pass filter for converting the output of the comparator to a low pass filter to a DC voltage, and a voltage controlled oscillator controlled oscillation by the voltage to generate the first reference frequency. Frequency compensator for telephones. First frequency converting means for generating a first intermediate frequency by mixing a first reference frequency and a received signal, second frequency converting means for generating a second intermediate frequency by mixing the second reference frequency and a first intermediate frequency; In the receiving method of a portable radiotelephone comprising a means for detecting the reception sensitivity at the second intermediate frequency, the method comprising: generating a channel frequency set at the time of initial channel selection as the first reference frequency; Comparing the received sensitivity intensity of the signal with the reference sensitivity intensity, repeating the steps after increasing the first reference frequency when the reference sensitivity intensity is large in the comparison process, and repeating the reference procedure in the comparison process When the sensitivity strength is small, the first reference frequency is decreased, and then the steps are repeatedly performed. To maintain a receiving method for a portable radio telephone, characterized in that to compensate for deviations of the first reference frequency. Means for generating a first reference frequency according to the difference between the two signals after detecting the difference between the first divided signal and the second divided signal, and generating a first intermediate frequency by mixing the first reference frequency and the received signal. And first frequency converting means, second frequency conversion means for generating a second intermediate frequency by mixing the second reference frequency and the first intermediate frequency, and means for detecting the reception sensitivity at the second intermediate frequency. In the receiving method of a portable radiotelephone, the frequency division of a selected channel is set as the second division signal and the division ratio of a phase synchronization loop is set by setting the first division signal as an initial value, and after performing the process. Comparing the reception sensitivity strength and the reference sensitivity strength, and when the reference sensitivity strength is greater than the reception sensitivity strength in the comparison process, the first divided signal is increased and the reception sensitivity strength is increased. Waiting for input of the next reception sensitivity after storing the signal; and reducing the first divided signal when the reference sensitivity is less than the reception sensitivity in the comparison process, and storing the reception sensitivity as the reference sensitivity. And a process of waiting for an input of a next reception sensitivity strength and repeating the reception sensitivity strength and the reference sensitivity strength after performing the waiting process. A frequency compensation method of a portable radio telephone, comprising: generating a corresponding channel frequency as a first reference frequency when selecting a channel, synthesizing a received radio signal with the first reference frequency and generating a first intermediate frequency; And synthesizing the first intermediate frequency and the second reference frequency to generate a second intermediate frequency, detecting a reception sensitivity intensity at the second intermediate frequency, and comparing the reception sensitivity intensity with the reference sensitivity intensity. And returning to the process of generating the first intermediate frequency after increasing the first reference frequency when the reference sensitivity is large in the comparing process, and when the reference sensitivity is small in the comparing process, 1) a portable radiotelephone comprising a process of returning to the process of generating the first intermediate frequency after reducing the reference frequency Receiving method.