RU2251211C2 - Method and device for conversion and frequency reduction of signals transferred by using plurality of modulation formats to common intermediate-frequency band - Google Patents

Abstract

FIELD: radio engineering; mobile radio communication systems.

SUBSTANCE: receiver converts signals modulated by using various modulation formats and transmitted in various frequency bands and has, among other things, band selection filters for selecting desired frequency band; first step-down frequency changer connected to output of first band selection filter; second step-down frequency changer selectively connected to output of second or third band selection filter and provided with input for connecting frequency doubling circuit; voltage-controlled generator connected to input of first step-down converter and to input of frequency doubling circuit.

EFFECT: minimized hardware used in multiple-mode telephone sets.

42 cl, 6 dwg

Description

The invention relates to mobile radio communication systems. More specifically, this invention relates to mobile radio communication devices that can receive and demodulate signals in different frequency ranges that have been modulated in accordance with many modulation formats. Even more specifically, this invention relates to a new and improved receiver circuit that downconverts such signals in different frequency ranges to a common frequency range using a minimum number of hardware components.

State of the art

Currently, mobile radiotelephones typically communicate in a number of different modes corresponding to different modulation formats. For example, there are so-called “dual-mode” mobile radiotelephones that communicate using both analog signals and code division multiple access (CDMA) signals. As the number of modes supported by this phone increases, the complexity of the circuitry required in the phone to convert down-frequency and sample input signals usually increases. This is due to the fact that in multi-mode telephones, input signals are received in different frequency ranges, depending on the operating mode, and down-conversion and sampling of signals from each frequency range usually requires separate circuits for each range. Therefore, it would be desirable to have a receiver that could be used in multi-mode telephones for down-conversion and sampling of input signals, which would use conventional hardware for down-conversion and sampling operations, thereby reducing the hardware requirements needed for multi-mode phone operation.

SUMMARY OF THE INVENTION

The invention relates to a receiver that down-converts input signals modulated using the first, second, third and fourth modulation formats into a common range of intermediate frequencies. The first and second modulation formats are transmitted to the receiver in the first frequency band, the third modulation format is transmitted to the receiver in the second frequency band, and the fourth modulation format is transmitted to the receiver in the third frequency band. These input signals arrive at the first and third band selection filters, which respectively select the first, second, and third frequency ranges. The first step-down converter is connected to the output of the first band selection filter and down-converts the signals from the first frequency range to the common range of intermediate frequencies. The second step-down converter selectively connects via a switch to either the output of the second band selection filter or the output of the third band selection filter and down-converts the signals from either the second frequency range or the third frequency range to a common intermediate frequency range. The second buck converter has an output connected to a frequency doubling circuit. The switching circuits selectively supply either the first oscillation signal from the voltage control of the generator (UNG) having the frequency range of the UNG, or the second oscillation signal with a second frequency, which is outside the frequency range of the UNG, to the output of the first step-down converter and to the input of the frequency doubling circuit.

In a preferred embodiment, the UNG is controlled by control circuits and selectively generates a first oscillation signal at a frequency of a communication channel associated with a first modulation format, and a first step-down converter mixes the output signal of a first filter of a band selection with a first oscillation signal at a frequency of a communication channel associated with a first modulation format , for down-converting the signals modulated in accordance with the first modulation format from the first frequency range to a common range of intermediate frequencies. The UNG, in addition, selectively generates a first oscillation signal at a frequency of a communication channel associated with the second modulation format, and the first buck converter mixes the output signal of the first filter of the band selection with a first oscillation signal at a frequency of the communication channel associated with the second modulation format for down-conversion frequencies of signals modulated in accordance with a second modulation format from a first frequency range to a common intermediate frequency range. In addition, in a preferred embodiment, the UNG also selectively generates a first oscillation signal at a communication channel frequency associated with a third modulation format, the first oscillation signal at a communication channel frequency associated with a third modulation format, being supplied to a frequency doubling circuit. The second step-down converter then mixes the output signal of the second band selection filter with the output signal of the frequency doubling circuit if the first oscillation signal at the frequency of the communication channel associated with the third type of modulation is supplied to the frequency doubling circuit for down-converting signals modulated in accordance with a third modulation format, from a second frequency range to a common range of intermediate frequencies.

The receiver of the invention also preferably includes a mixer that generates an oscillation signal at a second frequency by shifting the frequency of the first oscillation signal. The second oscillation signal is selectively supplied to the frequency doubling circuit, and the second step-down converter mixes the output signal of the third band selection filter with the output signal of the frequency doubling circuit for down-converting the signals modulated in accordance with the fourth modulation format from the third frequency range to the common intermediate range frequencies.

In accordance with yet another aspect, a receiver of the invention includes one or more coupling selection filters that are coupled to the outputs of the first and second buck converters. The communication channel selection filter (s) provide filtering of the down-converted signals generated by the first and second downconverters. The sampling circuit is connected to the output of the filter (s) for selecting a communication channel. The sampling circuit selectively samples the down-converted signals by a sampling clock that samples signals from either the first or second sampling frequency. The sampling clock signal is input into the third oscillation signal at the third frequency, and the third oscillation signal is an input signal to the mixer, which generates a second oscillation signal at the second frequency. The first sampling frequency provided by the sampling clock is equal to the third frequency divided by x, and the second sampling frequency provided by the sampling clock is equal to the third frequency divided by y, where x and y are integers and, in one example, are 3 and 15. This aspect of the invention minimizes redundant hardware at the receiver since the third waveform at the third frequency is used both in the down-conversion process and in the sampling process. In one embodiment, the sample circuit samples the down-converted signals modulated in accordance with the second, third or fourth modulation formats in accordance with the first sampling frequency, and the sample circuit samples the down-converted signals modulated in accordance with the first modulation format, according to the second sampling rate.

In one embodiment, a single communication channel selection filter is connected to the outputs of the first and second downconverters, and this single communication channel selection filter provides filtering of the down-converted signals modulated in accordance with the first and second modulation formats provided by the first downconverter a single communication channel selection filter further filters down-converted signals modulated in accordance with the third and fourth modulation formats, issued by the second buck converter.

In yet another embodiment, the first and second communication channel selection filters are connected to the outputs of the first and second buck converters. The first communication channel filter provides filtering of the down-converted signals modulated in accordance with the first modulation format provided by the first downconverter, the second communication channel filter provides the filtering of down-converted signals modulated in accordance with the second modulation format issued in the first downconverter , the second communication channel selection filter also filters down-converted signals modulated in accordance with and with a third modulation format provided by the second down-converter, and a second communication channel selection filter filters down-converted signals modulated in accordance with the fourth modulation format provided by the second down-converter.

In yet another embodiment, the first, second, and third communication channel selection filters are connected to the outputs of the first and second buck converters. The first communication channel selection filter provides filtering of the down-converted signals modulated in accordance with the first modulation format provided by the first downconverter, the second communication channel filter provides the filtering of down-converted signals modulated in accordance with the first modulation format in accordance with the second modulation format of the first converter , the second communication channel selection filter filters down-converted signals modulated in accordance with the third m modulation format output from the second downconverter, and the third communication channel selection filter filters the down-converted signals from frequency modulated in accordance with the fourth modulation format issued by the second downconverter.

In the above embodiments, two buck converters are connected to the outputs of the band selection filters. In yet another embodiment, the third buck converter is coupled to the output of the first band selection filter, and also provides down-conversion from the first frequency range to the common intermediate frequency range. In this embodiment, the switching circuit selectively feeds the first oscillation signal from the UNG or the second oscillation signal to the inputs of the first and third buck converters and to the input of the frequency doubling circuit. While in previous embodiments, the input signals modulated in accordance with the second modulation format were downconverted using the first step-down converter, in this embodiment, the third step-down converter mixes the output signal of the first band selection filter with the first waveform at the communication channel frequency, associated with the second modulation format for down-converting signals modulated in accordance with the second modulation format from the first h stot a common intermediate frequency range. In this embodiment, one, two or three communication channel selection filters are alternatively connected to the outputs of the first, second and third downconverters, and accordingly the communication channel selection filters provide filtering of down-converted signals modulated in accordance with the first, second and fourth modulation formats.

Brief Description of the Drawings

Signs, objectives and advantages of the present invention are explained in the following detailed description, illustrated by drawings, in which the same reference numerals denote the corresponding elements and which show the following:

Figure 1 is a block diagram of a receiver that downconverts signals transmitted in three different frequency ranges and modulated using the first, second, third and fourth modulation format into a common range of intermediate frequencies using three downconverters, in accordance with preferred embodiment of the invention. In the receiver of FIG. 1, three communication channel selection filters are used to process down-converted signals generated by three downconverters.

FIG. 2 is a block diagram of a receiver that down-converts signals transmitted in three different bands and modulated using the first, second, third and fourth modulation formats into a common intermediate frequency range using three buck converters, in accordance with a preferred an embodiment of the invention. In the receiver of FIG. 2, two communication channel selection filters are used to process down-converted signals from three downconverters.

Figure 3 is a block diagram of a receiver that down-converts signals transmitted in three different frequency ranges and modulated using the first, second, third and fourth modulation formats into a common range of intermediate frequencies using three downconverters, in accordance with another preferred embodiment of the invention. In the receiver of FIG. 3, a single communication channel selection filter is used to process down-converted signals from three downconverters.

Figure 4 is a block diagram of a receiver that downconverts signals transmitted in three different frequency ranges and modulated using the first, second, third and fourth modulation formats into a common range of intermediate frequencies using two downconverters, in accordance with preferred embodiment of the invention. In the receiver of FIG. 4, three communication channel selection filters are used to process down-converted signals from two downconverters.

5 is a block diagram of a receiver that downconverts signals transmitted in three different frequency ranges and modulated using the first, second, third and fourth formats into a common range of intermediate frequencies using two buck converters, in accordance with one alternative preferred embodiment of the invention. In the receiver of FIG. 5, two communication channel selection filters are used to process down-converted signals generated by two downconverters.

6 is a block diagram of a receiver that downconverts signals transmitted in three different frequency ranges and modulated using the first, second, third and fourth modulation formats into a common range of intermediate frequencies using two downconverters, in accordance with another preferred embodiment of the invention. In the receiver of FIG. 6, a single communication channel selection filter is used to process down-converted signals from two downconverters.

Detailed Description of Preferred Options

1 shows a block diagram of a receiver 2 for use in a multi-mode mobile radiotelephone that alternatively communicates using any one of four different modulation formats. A receiver converts input signals modulated using one of four modulation formats into a common range of intermediate frequencies. In the shown embodiment, the first, second, third, and fourth modulation formats correspond to analog modulation, CDMA signal modulation, personal communication service (SPS) signal modulation, and GPS global positioning system signal modulation, although it should be understood by those skilled in the art that the architecture of this invention , can be used for down-conversion of signals modulated in accordance with other modulation formats. The first and second modulation formats are transmitted to the receiver in the first frequency band, the third modulation format is transmitted to the receiver in the second frequency band, and the fourth modulation format is transmitted to the receiver in the third frequency band. In the shown embodiment, the first and second frequency ranges correspond to the frequency bands commonly used for analog and CDMA transmissions of cell phones, i.e. 869-894 MHz;

the third frequency range corresponds to the frequency band commonly used for ATP transmissions, i.e. 1930-1990 MHz; and the fourth frequency range corresponds to the frequency band commonly used for transmitting GPS systems, i.e. 2 MHz wide band with a center frequency of 1575.42 MHz.

The input signals received by the receiver are supplied to a first selection filter 10, which selects a first frequency range (e.g., a frequency range corresponding to an analog band and a CDMA band, a second band selection filter 12, selects a second frequency range (e.g., ATP band), and a third the band selection filter 14 selects a third frequency band (e.g., GPS band).

A buck converter (or mixer) 20 is connected to the output of the first band selection filter 10 and downconverts the signals modulated in accordance with the first modulation format (e.g., analog signals) output by the first band selection filter 10 from the first frequency range to a common range intermediate frequencies. The overall range of intermediate frequencies is centered on the intermediate center frequency of the IF, which is preferably about 183.48 MHz. Step-down converter 20 biases the output of the first band selection filter 10 (i.e., the entire frequency band of the analog signal) down the frequency spectrum to the intermediate frequency range, so that the communication channel of interest (i.e., the communication channel in the analog frequency band) channels to which the receiver is tuned) is centered on the center frequency corresponding to the inverter.

The second buck converter (or mixer) 22 is also connected to the output of the first band selection filter 10, and downconverts the signals modulated in accordance with the second modulation format (e.g., CDMA signals) output by the first band selection filter 10 from the first frequency range into the general range of intermediate frequencies. The buck converter 22 biases the output of the first band selection filter 10 (i.e., the entire CDMA band) down the frequency spectrum to the intermediate frequency band so that the communication channel of interest (i.e., the communication channel in the CDMA band is which the receiver is tuned to) is centered on the center frequency corresponding to the inverter.

The third step-down converter (or mixer) 24 is selectively connected by a switch 16 to either the output of the second strip selection filter 12 or the output of the third strip selection filter 14. The third buck converter 24 provides a down-conversion of either (i) signals modulated in accordance with a third modulation format (e.g., ATP signals) provided by the second band selection filter 12 from a second frequency band to a common intermediate frequency range, or (ii) signals modulated in accordance with the fourth modulation format (for example, GPS system signals) provided by the third band selection filter 14 from the third frequency band to the common intermediate frequency band. Depending on the position of the switch 16, the buck converter 24 either converts the output signal of the second band selection filter 12 (i.e., the entire ATP frequency band down the frequency spectrum into the intermediate frequency range so that the communication channel of interest (i.e. the channel the communication in the frequency band of the ATP, to which the receiver is tuned) is centered on the center frequency corresponding to the IF, or the buck converter 24 converts the output signal of the third band selection filter 14 (i.e. the entire frequency band) down the frequency spectrum into the range of intermediate frequencies so that the intepec communication channel (that is, the communication channel in the GPS system band to which the receiver is tuned) is centered on the center frequency corresponding to the inverter. When switch 16 connects the output of the second band selection filter 12 to the third step-down the converter 24, the switch 29 connects the output of the third step-down converter 24 with the second communication channel selection filter 62 (described below). Similarly, when the switch 16 connects the output of the third strip selection filter 14 to the third step-down converter 24, the switch 29 connects the output of the third step-down converter 24 to the third communication channel selection filter 64 (also described below).

The third buck converter 24 has an input coupled to a frequency doubling circuit 26. The switching circuit 28 selectively supplies either the first oscillation signal 30 controlled by the voltage of the generator (UNG) 34 having the UNG frequency range, or the second oscillation signal 32 with a second frequency that is outside the UNG frequency range, to the inputs of the first and second step-down converters 20, 22 and to the input of the frequency doubling circuit 26. In a preferred embodiment, the frequency range of UNG 34 is 1052-1087 MHz.

UNG 34 is controlled by a control circuit 36, which provides in UNG 34 the formation of a first oscillation signal 30 with a frequency associated with the analog communication channel to which the receiver is tuned when analog signals are received by antenna 40 (i.e., when the mobile radiotelephone is operating in analog mode) . When such signals are received, the first step-down converter 20 mixes the output signal of the first band selection filter 10 with the first oscillation signal 30 at a frequency associated with the analog communication channel to which the receiver is tuned to convert down-frequency signals from the first frequency range to a common intermediate range frequencies. In a down-converted signal, the communication channel of interest (i.e., the analog communication channel to which the receiver is tuned) is centered on the center frequency corresponding to the IF.

The control circuit 36 further provides, in the UNG 34, the formation of the first oscillation signal 30 with a frequency associated with the CDMA communication channel to which the receiver is tuned when the CDMA signals are received by the antenna 40 (i.e., when the mobile radio operates in the CDMA mode. When such signals are received , the second buck converter 22 mixes the output signal of the first band selection filter 10 with the first oscillation signal 30 at a frequency associated with the CDMA communication channel to which the receiver is tuned, for down-converting the signal from the first frequency range to the general range of intermediate frequencies.In the signal converted with decreasing frequency, the communication channel of interest (i.e., the CDMA communication channel to which the receiver is tuned) is centered on the center frequency corresponding to the IF.

The control circuit 36 provides the formation of the UNG 34 in the UNG of the first oscillation signal 30 with a frequency associated with the SPS communication channel to which the receiver is tuned when the SPS signals are received by the antenna 40 (i.e., when the mobile radio operates in the SPS mode. When such signals are received , the first oscillation signal 30 with a frequency associated with the ATP communication channel to which the receiver is tuned is supplied to the frequency doubling circuit 26, and the third step-down converter 24 mixes the output signal of the second band selection filter 14 with the output signal frequency doubling circuits 26 for down-converting ATP signals from the second frequency range to a common range of intermediate frequencies. In the down-converted signal, the communication channel of interest (that is, the ATP communication channel to which the receiver is tuned) is centered on the center frequency corresponding to IF

In a preferred embodiment, when the receiver is operating either in analog mode or in CDMA mode, the first oscillation signal 30 supplied from the UNG 34 is within the frequency range 1052.52-1077.45 MHz. This frequency range allows down-converters 20, 22 to down-convert any communication channel of interest, either in the analog band or in the CDMA band, to the center frequency of the inverter. Similarly, in a preferred embodiment, when the receiver operates in the ATP mode, the first oscillation signal 30 generated in the UNG 34 is within the frequency range 1056.74-1086.74 MHz. This frequency range allows the buck converter 24 to convert any communication channel of interest in the ATP band to the center frequency of the inverter.

When the mobile radio operates in GPS mode and the GPS signals are received by the antenna 42, the mixer 50 generates a second oscillation signal 32 with a frequency that is outside the frequency range of the UNG 34 by shifting the frequency of the first oscillation signal 30. This frequency shift can be performed using, for example, a mixer 50 with suppression of the mirror frequency. The frequency of the second oscillation signal 32 is connected to the GPS communication channel to which the receiver is tuned. When the mobile radio communication device is in GPS mode, the second oscillation signal 32 with a frequency associated with the GPS communication channel to which the receiver is tuned is supplied to the frequency doubling circuit 26, and the third step-down converter 24 mixes the output signal of the third band selection filter 14 with the output the signal of the frequency doubling circuit 26 for downconverting the signals of the GPS system from the third frequency range to the general range of intermediate frequencies. In a signal downconverted, the communication channel of interest (i.e., the GPS communication channel to which the receiver is tuned) is centered on the center frequency corresponding to the IF.

In a preferred embodiment, when the receiver is in GPS mode, a second oscillation signal 32 supplied to the frequency doubling circuit 26 is within the frequency range, with a center frequency of about 879.45 MHz. This frequency range allows the buck converter 24 to down-convert any communication channel of interest in the GPS system band to the center frequency corresponding to the IF.

As indicated above, the mixer 50 generates a second oscillatory signal 32 with a frequency that is outside the frequency range of the UNG 34 by shifting the frequency of the first oscillating signal 30. In a preferred embodiment, this frequency shift is performed by mixing the output signal of the UNG 34 with the signal 33 generated by the generator 35. The signal 33 has a frequency that is equal to three times the sampling frequency (F _s ). The sampling frequency (F _s ) associated with the generator 35 is preferably selected so that the sampling frequency and the center frequency (f _iF ) mentioned above are related in accordance with equality (1)

F _IF = [(2k + 1) / 4] · (F _s ), where k = 0, 1, 2, ... (1)

The receiver of FIG. 1 also preferably includes a plurality of communication channel selection filters 60, 62, 64 for selecting or tuning to specific communication channels associated with each of the four modulation formats. The communication channel selection filters 60, 62, 64 are connected to the outputs of the first, second, and third step-down converters and filter the down-converted signals generated by the first, second, and third step-down converters. A sampling circuit 70 is connected to the output of the communication channel selection filters by means of anti-aliasing filters 80, 82. The sampling circuit 70 selectively samples the down-converted signals by a sampling clock 72, which alternatively samples the signals from either the first or second sampling frequency. The sampling clock 72 is coupled to a signal 33, which, as mentioned above, is also supplied as an input to a mixer 50, which generates a second oscillation signal 32. The first sampling rate provided by the sampling clock is preferably 3 · F _s (i.e., signal frequency 33) divided by 3, and the second sampling frequency provided by the sampling clock is preferably equal to (3 · F _s ) divided by 15. These two sampling frequencies allow the receiver of the invention to sample either analog signals, or CDMA, ATP, or GPS signals using a conventional sampling circuit 70. In particular, the present invention uses a first sampling rate to sample CDMA, ATP and GPS signals, and a second sampling rate to sample analog signals. This aspect of the invention minimizes redundant hardware at the receiver since the oscillation signal 33 is used both in the down-conversion process and in the sampling process.

Also in a preferred embodiment, the radio frequency integrated circuit is preferably used to implement all of the components indicated within the block 5 shown by the dotted line.

FIG. 2 shows a block diagram of a receiver that down-converts signals modulated using the first, second, third and fourth modulation formats into a common intermediate frequency range using three down-converters, in accordance with an alternative preferred embodiment of the invention. The receiver shown in FIG. 2 is essentially the same as the receiver of FIG. 1, except that the receiver of FIG. 2 uses only two communication channel selection filters 60, 62A for processing down-converted signals emitted by three buck converters. Thus, in the receiver of FIG. 2, the second communication channel selection filter 62A filters the down-converted signals modulated in accordance with the second modulation format (e.g., CDMA signals) provided by the second down-converter 22, the second communication channel selection filter 62A also filters the converted with decreasing frequency, the signals modulated in accordance with the third modulation format (for example, ATP signals) provided by the third step-down converter 24, and the second communication channel selection filter 62A is also fil truet down converted signals modulated in accordance with the fourth modulation format (e.g., GPS system signals) output from the third down-converter 24.

FIG. 3 shows a block diagram of a receiver that downconverts signals modulated using the first, second, third and fourth modulation formats to a common intermediate frequency range using three downconverters, in accordance with yet another alternative preferred embodiment inventions. The receiver of FIG. 3 is essentially the same as the receiver of FIG. 1, except that the receiver of FIG. 3 uses only one communication channel selection filter 62A for processing down-converted signals generated by three down-converters .

FIG. 4 is a block diagram of a receiver that downconverts signals modulated using the first, second, third, and fourth modulation formats to an intermediate frequency in accordance with a preferred embodiment of the invention. Unlike the receiver of FIGS. 1-3, only two step-down converters 20, 24 are used in the receiver of FIG. 4 to perform down-conversion for all four operating modes. Thus, according to FIG. 4, only the step-down converter 20 is connected to the output of the first band selection filter 10. The step-down converter 20 down-converts the signals modulated in accordance with either the first modulation format (e.g., analog signals) or the second modulation format (for example, CDMA signals provided by the first band selection filter 10 from the first frequency range to the common range of intermediate frequencies. In this embodiment, the buck converter 20 shifts the output signal of the first filter 10 selecting a band (i.e., the entire analog band of the frequency band or the MKDR band of frequencies) down the frequency spectrum to the range of intermediate frequencies so that the communication channel of interest (i.e., the communication channel in the analog band or in the CDMA band, which the receiver is tuned to) is centered on the center frequency corresponding to the inverter. The remaining inverter components of the receiver of Fig. 4 operate essentially the same as the corresponding components described above in connection with Fig. 1, except that in Fig. 4 the first waveform 30 which wounds e was supplied to the mixer 22 (FIG. 1), fed instead to the mixer 20 (FIG. 4) when the receiver was operating in CDMA mode. In addition, in the embodiment of FIG. 4, an additional switch 29A is provided for directing the output of the mixer 20 to the second communication channel selection filter 62 when the receiver is in CDMA mode.

5 is a block diagram of a receiver that downconverts signals modulated using the first, second, third, and fourth modulation formats into a common intermediate frequency range using two downconverters, in accordance with an alternative preferred embodiment of the invention. The receiver of FIG. 5 is essentially the same as the receiver of FIG. 4, except that the receiver of FIG. 5 uses only two communication channel selection filters 60, 62A for processing down-converted signals generated by two buck converters. Thus, in the receiver of FIG. 5, the second communication channel selection filter 62A filters the down-converted signals modulated in accordance with the second modulation format (e.g., CDMA signals) provided by the down-converter 20, the second communication channel selection filter 62A also filters the converted with decreasing frequency, the signals modulated in accordance with the third type of modulation (for example, ATP signals) provided by the downconverter 24, and the second communication channel selection filter 62A also filters the conversion bathrooms and downconverts signals modulated in accordance with the fourth modulation format (e.g., GPS system signals) output from the down converter 24.

FIG. 6 shows a block diagram of a receiver that downconverts signals modulated using the first, second, third and fourth modulation formats to an intermediate frequency range using two downconverters, in accordance with yet another alternative preferred embodiment of the invention . The receiver of FIG. 6 is essentially the same as the receiver of FIG. 4 except that the receiver of FIG. 6 uses only one communication channel selection filter 60A for processing down-converted signals generated by two down-converters converters.

The above description of the preferred options allows any person skilled in the art to make or use the present invention. Although the invention has been described with reference to a mobile radiotelephone receiver, the principles of the invention can be applied in other contexts and applications. In addition, various modifications to the options described above are readily apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments without the use of invention. Thus, the present invention is not limited to the methods and devices shown here, but should correspond to the broadest scope of the invention.

Claims (42)

1. A receiver for down-converting signals modulated using a plurality of modulation formats into a common range of intermediate frequencies, wherein the plurality of modulation formats include first, second, third, fourth modulation formats, the signals of the first and second modulation formats transmit to the receiver in the first frequency range, signals of the third modulation format are transmitted to the receiver in the second frequency range, and signals of the fourth modulation format are transmitted to the receiver in the third a frequency band containing a first band selection filter for selecting a first frequency range, a second band selection filter for selecting a second frequency range, a third band selection filter for selecting a third frequency range, a first step-down converter connected to the output of the first band selection filter, for down-converting frequencies of signals from the first frequency range to the general range of intermediate frequencies, the second step-down converter selectively connected by a switch to the output of the second field selection filter wasps when the receiver is operating in the mode using signals modulated in accordance with the third modulation format, or with the output of a third band selection filter when the receiver is operating in the mode using signals modulated in accordance with the fourth modulation format, respectively, for down-converting signals either from the second frequency range, or from the third frequency range to the general range of intermediate frequencies, and the second step-down converter has an input connected to the circuit doubled frequency, switching circuit for selectively supplying a first oscillation signal from a voltage-controlled oscillator (UNG) in the UNG frequency range when the receiver is operating using signals modulated in accordance with the first, second and third modulation formats, or a second oscillation signal with a second frequency out of range UNG frequencies when the receiver is operating using signals modulated in accordance with the fourth modulation format, to the input of the first step-down converter and to the input of the frequency doubling circuit, 2. The receiver according to claim 1, characterized in that the UNG is controlled by a control circuit and selectively generates a first oscillation signal with a communication channel frequency associated with the first modulation format, and the first down converter mixes the output signal of the first band selection filter with the first oscillation signal with a frequency a communication channel associated with a first modulation format for down-converting signals modulated in accordance with a first modulation format from a first frequency range to a common intermediate range frequencies. 3. The receiver according to claim 2, characterized in that the UNG additionally selectively generates a first oscillation signal with a communication channel frequency associated with the second modulation format, and the first down converter mixes the output signal of the first band selection filter with the first oscillation signal with the communication channel frequency, associated with the second modulation format, for down-converting signals modulated in accordance with the second modulation format from the first frequency range to a common range of intermediate frequencies. 4. The receiver according to claim 3, characterized in that the UNG additionally selectively generates a first oscillation signal with a communication channel frequency associated with the third modulation format, wherein the first oscillation signal with a communication channel frequency associated with the third modulation format is supplied to a frequency doubling circuit and the second buck converter mixes the output signal of the second band selection filter with the output signal of the frequency doubling circuit when the first oscillation signal with the frequency of the communication channel associated with the third modulation format is supplied to a frequency doubling circuit for down-converting signals modulated in accordance with a third modulation format from a second frequency range to a common range of intermediate frequencies. 5. The receiver according to claim 4, characterized in that it further comprises a mixer that generates a second oscillation signal with a second frequency by shifting the frequency of the first oscillation signal. 6. The receiver according to claim 5, characterized in that the second oscillation signal is selectively fed to the frequency doubling circuit and the second buck converter mixes the output signal of the third band selection filter with the output signal of the frequency doubling circuit when the second oscillation signal is supplied to the frequency doubling circuit for conversion decreasing the frequency of the signals modulated in accordance with the fourth modulation format from the third frequency range to the general range of intermediate frequencies. 7. The receiver according to claim 6, characterized in that the first modulation format corresponds to analog modulation, the second modulation format corresponds to CDMA modulation, the third modulation format corresponds to ATP modulation, the fourth modulation format corresponds to GPS modulation, the first frequency range is 869-894 MHz, the second frequency range is 1930-1990 MHz and the third frequency range is 1574.42-1576.42 MHz. 8. The receiver according to claim 7, characterized in that the total range of intermediate frequencies is centered at a frequency of about 183.48 MHz. 9. The receiver according to claim 7, characterized in that the oscillation signal with the frequency of the communication channel associated with the first modulation format has a frequency range of 1052.52-1077.45 MHz. 10. The receiver according to claim 9, characterized in that the first oscillation signal with the frequency of the communication channel associated with the second modulation format has a frequency range of 1052.52-1077.45 MHz. 11. The receiver of claim 10, wherein the first oscillation signal with a communication channel frequency associated with the third modulation format has a frequency range of 1056.74-1086.74 MHz. 12. The receiver according to claim 11, characterized in that the second oscillation signal with a communication channel frequency associated with the fourth modulation format has a frequency range centered at a frequency of 879.45 MHz. 13. The receiver according to claim 5, characterized in that it further comprises one or more communication channel selection filters connected to the outputs of the first and second step-down converters, which filter the down-converted signals generated by the first and second step-down converters, a sampling circuit connected with the output of one or more communication channel selection filters, which selectively samples the down-converted signals by a sampling clock, which alternatively dis it samples signals with either the first or second sampling frequency, and the sampling clock is connected to the third oscillation signal with a third frequency, and the third oscillation signal is an input signal for the mixer, which generates a second oscillation signal with a second frequency. 14. The receiver of claim 13, wherein the first sampling frequency provided by the sampling clock is equal to the third frequency divided by x, and the second sampling frequency provided by the sampling clock is equal to the third frequency divided by y, where x and y are integers. 15. The receiver of claim 14, wherein the first sampling frequency generated by the sampling clock is 1/3 of the third frequency, and the second sampling frequency generated by the sampling clock is one fifteenth of the third frequency. 16. The receiver according to 14, characterized in that the sampling circuit samples down-converted signals modulated in accordance with the second, third or fourth modulation formats, in accordance with the first sampling frequency, and the sampling circuit samples down-converted signals, modulated in accordance with the first modulation format, in accordance with the second sampling rate. 17. The receiver according to clause 16, wherein the one or more filters of the choice of the communication channel include only one filter of the choice of the communication channel. 18. The receiver according to clause 16, wherein one or more communication channel selection filters include first and second communication channel selection filters, the first communication channel selection filter filters down-converted signals modulated in accordance with the first modulation format, provided by the first downconverter, the second communication channel selection filter filters down-converted signals modulated in accordance with the second modulation format, provided by the first downconverter eat, the second communication channel selection filter also filters down-converted signals modulated in accordance with the third modulation format provided by the second down-converter, and the second communication channel selection filter also filters down-converted signals modulated in accordance with the fourth modulation, issued by the second buck converter. 19. The receiver according to clause 16, wherein one or more communication channel selection filters include first, second and third communication channel selection filters, the first communication channel selection filter filters down-converted signals modulated in accordance with the first format modulations provided by the first downconverter, the second communication channel selection filter filters down-converted signals modulated in accordance with the second modulation format, provided by the first downconverters As an indicator, the second communication channel selection filter also filters down-converted signals modulated in accordance with the third modulation format provided by the second downconverter and the third communication channel selection filter filters down-converted signals modulated in accordance with the fourth modulation format second buck converter. 20. The receiver according to claim 13, characterized in that it further comprises a plurality of spectral protection filters connected to the output of one or more communication channel selection filters and to the input of the sampling circuit. 21. The receiver according to claim 1, characterized in that it further comprises a third step-down converter connected to the output of the first band selection filter, which downconverts the signals from the first frequency range to a common range of intermediate frequencies, while the switching circuit selectively delivers the first signal oscillations from the UNG or the second oscillation signal to the inputs of the first and third step-down converters and to the input of the frequency doubling circuit. 22. The receiver according to item 21, wherein the UNG is controlled by a control circuit and selectively generates a first oscillation signal with a communication channel frequency associated with the first modulation format, and the first step-down converter mixes the output signal of the first band selection filter with the first oscillation signal at a frequency a communication channel associated with a first modulation format for down-converting signals modulated in accordance with a first modulation format from a first frequency range to a general range of intermediate x frequencies. 23. The receiver according to item 22, wherein the UNG additionally selectively generates a first oscillation signal with a frequency of the communication channel associated with the second modulation format, and a third step-down converter mixes the output signal of the first band selection filter with the first oscillation signal at the frequency of the communication channel, associated with the second modulation format, for down-converting signals modulated in accordance with the second modulation format from the first frequency range to a common range of intermediate frequencies. 24. The receiver according to item 22, wherein the UNG additionally selectively generates a first oscillation signal with a communication channel frequency associated with the third modulation format, the first oscillation signal with a communication channel frequency associated with the third modulation format, is fed to the frequency doubling circuit and the second buck converter mixes the output signal of the second band selection filter with the output signal of the frequency doubling circuit when the first oscillation signal with the frequency of the communication channel associated with the third modulation format delivers I in the frequency doubling circuit for down-converting the frequency signals modulated in accordance with the third modulation format from the second frequency range to the common intermediate frequency range. 25. The receiver according to p. 24, characterized in that it further comprises a mixer that generates a second oscillation signal with a second frequency by shifting the frequency of the first oscillation signal. 26. The receiver according to claim 25, wherein the second oscillation signal is selectively supplied to the frequency doubling circuit, and the second buck converter mixes the output signal of the third band selection filter with the output signal of the frequency doubling circuit when the second oscillation signal is supplied to the frequency doubling circuit for down-converting signals modulated in accordance with the fourth modulation format from a third frequency range to a common intermediate frequency range. 27. The receiver according to claim 26, wherein the first modulation format corresponds to analog modulation, the second modulation format corresponds to CDMA modulation, the third modulation format corresponds to ATP modulation, the fourth modulation format corresponds to GPS modulation, the first frequency range is 869-894 MHz, the second frequency range is 1930-1990 MHz and the third frequency range is 1574.42-1576.42 MHz. 28. The receiver according to item 27, wherein the total range of intermediate frequencies is centered at a frequency of about 183.48 MHz. 29. The receiver according to claim 27, wherein the first oscillation signal with a communication channel frequency associated with the first modulation format has a frequency range of 1052.52-1077.45 MHz. 30. The receiver according to clause 29, wherein the first oscillation signal with the frequency of the communication channel associated with the second modulation format has a frequency range of 1052.52-1077.45 MHz. 31. The receiver according to claim 30, wherein the first oscillation signal with a communication channel frequency associated with the third modulation format has a frequency range of 1056.74-1086.74 MHz. 32. The receiver according to p, characterized in that the second oscillation signal with the frequency of the communication channel associated with the fourth modulation format has a frequency range centered at a frequency of 879.45 MHz. 33. The receiver according A.25, characterized in that it further comprises one or more filters for selecting a communication channel connected to the outputs of the first, second and third step-down converters, filtering the down-converted signals generated by the first, second and third step-down converters, a circuit a sample connected to the output of one or more communication channel selection filters, which selectively samples the down-converted signals by a sampling clock, which alto rnativno samples the signals of either first or second sampling frequency, the sampling clock generator is connected with the third oscillation signal at the third frequency, the third oscillation signal is input to the mixer that forms the second signal with a second oscillation frequency. 34. The receiver according to claim 33, wherein the first sampling frequency provided by the sampling clock is equal to the third frequency divided by x, and the second sampling frequency provided by the sampling clock is equal to the third frequency divided by y, where x and y are integers. 35. The receiver according to clause 34, wherein the first sampling rate provided by the sampling clock is 1/3 of the third frequency, and the second sampling frequency provided by the sampling clock is one fifteenth of the third frequency. 36. The receiver according to clause 34, wherein the sample circuit samples the down-converted signals modulated in accordance with the second, third or fourth modulation formats, in accordance with the first sampling frequency, and the sample circuit samples the down-converted signals, modulated in accordance with the first modulation format, in accordance with the second sampling rate. 37. The receiver according to clause 36, wherein one and several filters for selecting a communication channel include only one filter for selecting a communication channel. 38. The receiver according to clause 36, wherein one and more communication channel selection filters include first and second communication channel selection filters, the first communication channel selection filter filters down-converted signals modulated in accordance with the first modulation format, provided by the first downconverter, the second communication channel selection filter filters down-converted signals modulated in accordance with the second modulation format issued by the third downconverter eat, the second communication channel selection filter also filters down-converted signals modulated in accordance with the third modulation format provided by the second down-converter, and the second communication channel selection filter also filters down-converted signals modulated in accordance with the fourth modulation, issued by the second buck converter. 39. The receiver according to clause 36, wherein one or more communication channel selection filters include first, second and third communication channel selection filters, the first communication channel selection filter filters down-converted signals modulated in accordance with the first format modulations provided by the first downconverter, the second communication channel selection filter filters down-converted signals modulated in accordance with the second modulation format, provided by the third downconverter by the developer, the second communication channel selection filter also filters down-converted signals modulated in accordance with the third modulation format provided by the second down-converter and the third communication channel selection filter filters down-converted signals modulated in accordance with the fourth modulation format second buck converter. 40. The receiver according to claim 33, characterized in that it further comprises a plurality of spectral protection filters connected to the output of one or more communication channel selection filters and to the input of the sampling circuit. 41. A method of down-converting received signals modulated using a plurality of modulation formats into a common range of intermediate frequencies, wherein the plurality of modulation formats include first, second, third and fourth modulation formats, the signals of the first and second modulation formats being transmitted to the receiver in the first frequency range, the signals of the third modulation format are transmitted to the receiver in the second frequency range and the signals of the fourth modulation format are transmitted to the receiver in the third range of frequencies, including the steps of supplying input signals to a first band selection filter for selecting a first frequency range, supplying input signals to a second band selection filter for selecting a second frequency range, supplying input signals to a third band selection filter for selecting a third frequency range, selective feed or first the oscillation signal of the UNG with a frequency in the frequency range of the UNG during the operation of the receiver using signals modulated in accordance with the first, second or third modulation formats, or the second signal oscillations with a frequency outside the UNG frequency range when the receiver is operating using signals modulated in accordance with the fourth modulation format, to the input of the first step-down converter and to the input of the frequency doubling circuit, down-conversion by the first step-down converter of signals from the first frequency range to the general range of intermediate frequency conversion with decreasing frequency by the second step-down signal converter or from the second frequency range when the receiver is operating using the signals modulated in accordance with the third modulation format, or from the third frequency range when the receiver uses signals modulated in accordance with the fourth modulation format, into the common range of intermediate frequencies, the second step-down converter having an input connected to the frequency doubling circuit, this second step-down converter, respectively, selectively connected by a switch either to the output of the second band selection filter, or to the output of the third band selection filter. 42. An apparatus for down-converting signals modulated using a plurality of modulation formats into a common range of intermediate frequencies, wherein the plurality of modulation formats include first, second, third and fourth modulation formats, the signals of the first and second modulation formats being transmitted to the receiver in the first frequency range, the signals of the third modulation format are transmitted to the receiver in the second frequency range and the signals of the fourth modulation format are transmitted to the receiver in the third frequency range comprising means for supplying input signals to a first band selection filter for selecting a first frequency range; means for supplying input signals to a second band selection filter for selecting a second frequency range; means for supplying input signals to a third band selection filter for selecting the third frequency range, means for selectively supplying either the first UNG oscillation signal in the UNG frequency range when the receiver is operating using signals modulated in in accordance with the first, second and third modulation formats, or a second oscillation signal with a frequency outside the UNG frequency range when the receiver is operated using signals modulated in accordance with the fourth modulation format, to the input of the first step-down converter and to the input of the frequency doubling circuit, means for converting with decreasing frequency by the first step-down converter of signals from the first frequency range to the general range of intermediate frequencies, means for converting with decreasing frequency by the second lower signal converter either from the second frequency range when operating the receiver using signals modulated in accordance with the third modulation format, or from the third frequency range when operating the receiver using signals modulated in accordance with the fourth modulation format, into a common range of intermediate frequencies, the second step-down converter has an input connected to the frequency doubling circuit, while the second step-down converter is selectively connected yuchatelem or yield of the second filter band selection, either output of the third band selection filter.

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