WO2006026249A2

WO2006026249A2 - Method and apparatus for processing multiple wireless communication services

Info

Publication number: WO2006026249A2
Application number: PCT/US2005/029858
Authority: WO
Inventors: Erica Ellyn Aycin; Gerard Klahn; Tanbir Haque; Fryderyk Tyra; John W. Haim
Original assignee: Interdigital Technology Corporation
Priority date: 2004-08-26
Filing date: 2005-08-22
Publication date: 2006-03-09
Also published as: CN102420624B; KR20070046971A; KR101062804B1; MX2007002265A; EP1800412A2; CA2578037A1; TW200931847A; JP4456635B2; WO2006026249A3; KR20070047321A; NO20071487L; EP1800412A4; TWI280754B; JP2008511260A; CN102420624A; KR100860629B1; TW200620870A

Abstract

A method and apparatus for processing multiple wireless communication services in a receiver (100). A receiver (100) receives more than one wireless communication service simultaneously via a wireless interface. Each service is transmitted via a different carrier frequency band. The multiple received carrier signals are down-converted to an intermediate frequency (IF) band using a mixer (110, 116) and a local oscillator (LO). The LO and sampling frequencies are adjusted such that the converted IF band signals of the input signals are spectrally adjacent or overlapping each other to some degree. SINAD of the services is measured at each of a plurality of spectrally overlapping conditions. The LO frequencies and the sampling frequency are then adjusted based on the SINAD measurement results.

Description

[0001] METHOD AND APPARATUS FOR PROCESSING

MULTIPLE WIRELESS COMMUNICATION SERVICES

[0002] FIELD OF INVENTION

[0003] The present invention is related to wireless communication systems.

More particularly, the present invention is related to a method and apparatus for processing multiple wireless communication services in a receiver.

[0004] BACKGROUND

[0005] Software defined radio (SDR) is a scheme in which multiple wireless communication standards are supported in a wireless transmit/receive unit (WTRU) and radio frequency (RF) signals are processed by software defined units. With SDR, a single hardware platform can support multiple wireless communication standards without replacing hardware components, and downloaded software can reconfigure the hardware. In this way, WTRUs can be rapidly configured to support newly developed wireless communication standards and protocols.

[0006] Typical single-mode cellular base stations and WTRUs include a heterodyne radio receiver analog front end, a fixed sampling rate analog-to- digital converter (ADC) and subsequent digital processing units. In the analog front end, the desired signal is filtered and then down-converted to a fixed intermediate frequency (IF) band. The ADC operates at a fixed sampling rate that is chosen a priori based on the bandwidth of the desired signal requirements of the demodulation algorithms of the digital process and other factors. [0007] Currently, WTRUs are configured to process multiple services received through multiple channels. For example, a WTRU may support communications both in a digital cellular system (DCS) and a wideband code division multiple access (WCDMA) system. Each service is processed through a corresponding receiver path in the WTRU and separately input into a modem in the WTRU for processing. However, only one service is supported at a given time in each receiver path.

[0008] Current WTRU designs also include front-end configurations that involve a switch or a multiplexer and multiple filters that separate the signals into different receiver paths for the frequency band of each service. When the base station or WTRU is supporting multiple simultaneous services and/or channels at different carrier frequencies in a single radio receiver, the various services and/or channels are filtered and separately down-converted in the analog front end to IF and then separately converted to digital samples at fixed sampling rates.

[0009] The sampling rate of the ADC is one of the factors that affects the power consumption of the receiver. The power consumption of the ADC and other processing blocks in a modem is, in general, proportional to the sampling rate; higher sampling rates require more power than do lower sampling rates. [0010] Therefore, prior art WTRUs require extensive hardware resources to support multiple services and the configuration is not desirable in terms of battery life of the WTRU.

[0011] SUMMARY

[0012] The present invention is related to a method and apparatus for processing multiple wireless communication services in a receiver. In accordance with the present invention, more than one wireless communication service is received and processed simultaneously. The services are transmitted via different carrier frequency bands and the received carrier frequency bands are down-converted to an intermediate frequency (IF) band. Local oscillator (LO) frequencies are set such that the down-converted IF bands of the multiple services fall into a single IF band. In an alternative embodiment, Software Defined Radio (SDR) is implemented using one ADC and adaptively selecting the sampling frequency for analog-to-digital conversion of a plurality of input signals comprising two or more services received in two or more different frequency bands and adaptively selecting the LO frequencies. Each input signal carries a different service via a different frequency band. The input signals are received simultaneously. Each service is subject to a minimum signal-to-noise and distortion ratio (SINAD) requirement. The input signals are converted to IF band signals by mixing the input signals with multiple LO signals at certain frequencies. The LO frequencies are adaptively selected such that the IF bands are spectrally adjacent or overlapping to each other to some degree. The SINAD of the services is measured at each of a plurality of spectrally overlapping conditions. The LO frequencies and the sampling frequency are then adjusted based on the SINAD measurement results. The process is preferably continually repeated.

[0013] BRIEF DESCRIPTION OF THE DRAWINGS

[0014] A more detailed understanding of the invention may be had from the following description of the preferred embodiments, given by way of example and to be understood in conjunction with the accompanying drawings wherein:

[0015] Figure 1 is a block diagram of a receiver in accordance with a first embodiment of the present invention;

[0016] Figures 2A-2D are diagrams of signal spectrum at each stage in the receiver of Figure 1;

[0017] Figure 3 is a block diagram of a receiver in accordance with a second embodiment of the present invention;

[0018] Figures 4A-4D are diagrams of signal spectrum at each stage in the receiver of Figure 3;

[0019] Figure 5 is a block diagram of a receiver in accordance with a third embodiment of the present invention;

[0020] Figures 6A-6D are diagrams of signal spectrum at each stage in the receiver of Figure 5;

[0021] Figure 7 is a block diagram of a look-up table (LUT) used to implement adaptive frequency down-conversions in accordance with the present invention;

[0022] Figure 8 is a block diagram for synthesizing frequencies for local oscillators in accordance with the present invention;

[0023] Figure 9 is a flow diagram of a process for simultaneously processing multiple wireless communication services in a receiver in accordance with the present invention;

[0024] Figure 10 is a block diagram of a receiver for adaptively selecting the sampling frequency for analog-to-digital conversion of two input signals in accordance with the present invention;

[0025] Figures 11A-11F are block diagrams illustrating frequency translation of RF bands to the final IF frequencies in accordance with the present invention; and

[0026] Figure 12 is a flow diagram of a process for adaptively selecting the sampling frequency for analog-to-digital conversion of a plurality of input signals in a receiver in accordance with the present invention.

[0027] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0028] Hereafter, the terminology "WTRU" includes but is not limited to a user equipment, a mobile station, a fixed or mobile subscriber unit, a pager, or any other type of device capable of operating in a wireless environment. When referred to hereafter, the terminology "base station" includes but is not limited to a Node-B, a site controller, an access point, or any other type of interfacing device in a wireless environment.

[0029] The features of the present invention may be incorporated into an integrated circuit (IC) or may be configured in a circuit comprising a multitude of interconnecting components.

[0030] The present invention provides a method and apparatus for use in supporting simultaneous reception of multiple wireless communication services in a single receiver chain. The hardware can be configured by software. Hereinafter, the present invention will be explained with reference to DCS and WCDMA frequency division duplex (FDD) as examples of simultaneous services. However, it should be noted that the present invention is applicable to any other services and any number of simultaneous services. The numerical values shown in the drawings are provided as an example, not a limitation, and any other numerical values may be implemented without departing from the teachings of the present invention. [0031] Figure 1 is a block diagram of a receiver 100 in accordance with a first embodiment of the present invention. Figures 2A-2D are diagrams of signal spectrum at each stage in the receiver 100 of Figure 1. A diplexer 102 and a circulator 104 band-limit the input spectrum, which is shown in Figure 2 A, and combine the desired service downlink bands, while minimizing component loss before a low noise amplifier (LNA) 106. This also establishes the system noise figure which primarily comprises the noise figure of the LNA 106 plus any loss before the LNA 106, as long as the LNA 106 has sufficient gain (10-15 dB) to minimize the second stage noise figure contributions from the rest of the receiver chain. The diplexer 102 removes any intermediate uplink bands, (such as FDD uplink band in Figure 2A), that fall between the desired downlink bands and therefore prevents saturation of the wideband LNA 106. Arbitrary channels in two full receive bands can be simultaneously received and the service selection is software configurable.

[0032] The band-limited input spectrum is amplified by the LNA 106 and filtered by a first filter 108. The input spectrum after being filtered by the first filter 108 is shown in Figure 2B. The band-limited input signal is down- converted to a first IF bandwidth by a mixer 110 with a fixed LOl frequency. The first IF is filtered again by a second filter 112 to remove image frequencies and blockers; and then amplified by a variable gain amplifier (VGA) 114. The first IF spectrum as output by the VGA 114 is shown in Figure 2C. [0033] Using image frequency translations, a second down-conversion is conducted by a mixer 116 with LO2. The second IF spectrum is shown in Figure 2D. LO2 frequency is set such that the second down-conversion causes the multiple service downlink bands to be folded into a single second IF bandwidth as shown in Figure 2D. The DCS downlink band and the WCDMA FDD downlink band are folded in a single second IF bandwidth. This allows the use of high Q filters to attenuate out-of-band blockers and jammers at the second IF bandwidth. Multiple LO frequencies can also be used to place the downlink bands of multiple services anywhere within a defined second IF bandwidth. [0034] The receiver 100 of Figure 1 performs two down-conversions. However, it should be noted that the configuration of the receiver 100 in Figure 1, and other embodiments of the present invention which will be explained later, are merely preferable embodiments of the present invention, and one or more than two down-conversions may be implemented. The local oscillators, LOl and LO2, are set using an adaptive frequency plan with fixed filters to fold the receive downlink bands to a second IF while minimizing the second IF bandwidth. [0035] The final IF signals are further down sampled by an analog-to- digital converter (ADC) 124 after being processed by filters 118, 122 and a VGA 120. By minimizing the second IF bandwidth, the sampling frequency of the ADC 124 can be adaptive, thus minimizing power consumption of the final digital down conversion to baseband.

[0036] The final IF bandwidth is dependent on the receiver's signal-to-noise and distortion ratio (SINAD) measurement. The SINAD measurement includes the distortion products that are within the receiver's processing bandwidth. Normally only one signal is present within this bandwidth and distortion products are not generated, so only a signal-to-noise ratio (SNR) measurement is required. Since there are multiple signals present in the receiver, distortion products are generated within the processing band and these levels need to be accounted for in the SNR measurement. In accordance with the present invention, the minimum bandwidth is selected when the highest SINAD is measured, and conversely the largest final bandwidth is selected when the lowest SINAD is measured.

[0037] Figure 3 is a block diagram of a receiver 200 in accordance with a second embodiment of the present invention. Figures 4A-4D are diagrams of signal spectrum at each stage in the receiver of Figure 3. A diplexer 202 and a circulator 204 band-limit the input spectrum, which is shown in Figure 4A. The band-limited input spectrum is amplified by a LNA 206 and filtered by a first filter 208. The input spectrum after being filtered by the first filter 208 is shown in Figure 4B.

[0038] The input signals are then down-converted to IF signals by mixing the input signals with signals generated by a LOl. In the second embodiment, the two-downlink bands are converted to adjacent bands at the final IF using two fixed LOl frequencies and two fixed LO2 frequencies. The input signals of each service is down-converted using different LO frequencies. In this example, the DCS downlink band is down-converted with LOlA and L02A frequencies, and the WCDMA FDD downlink band is down-converted with LOlB and L02B frequencies.

[0039] The band-limited input signal of each service is down-converted to a first IF bandwidth by a mixer 210 with LOlA and LOlB frequencies, respectively, and filtered again by a second filter 212 to remove image frequencies and blockers and amplified by a VGA 214. The first IF spectrum as output by the VGA 214 is shown in Figure 4C.

[0040] A second down-conversion is conducted by a mixer 216 with LO2A and LO2B, respectively. The second IF spectrum as output by a filter 218 is shown in Figure 4D. LOlA, LOlB, LO2A and L02B frequencies are set such that the second down-conversion causes the multiple service downlink bands to be located adjacent each other in the second IF bandwidth as shown in Figure 4D. In this example, the DSC downlink band and the WCDMA FDD downlink band are converted to adjacent bands in the final IF band. Multiple LO frequencies can also be used to place the downlink bands of multiple services anywhere within a defined second IF bandwidth. The final intermediate frequency is further down sampled by an ADC 224 after being processed by filters 218, 222 and the VGA 220. By minimizing the second IF bandwidth, the sampling frequency of the ADC 224 can be adaptive, thus minimizing power consumption of the final digital down conversion to baseband. [0041] Figure 5 is a block diagram of a receiver 300 in accordance with a third embodiment of the present invention. Figures 6A-6D are diagrams of signal spectrum at each stage in the receiver 300 of Figure 5. A diplexer 302 and a circulator 304 band-limit the input spectrum, which is shown in Figure 6A. The band-limited input spectrum is amplified by a LNA 306 and filtered by a first filter 308. The input spectrum after being filtered by the first filter 308 is shown in Figure 6B. [0042] The band-limited input signal of each service is down-converted to a first IF bandwidth by a mixer 310 with LOlA and LOlB frequencies, respectively, and filtered again by a second filter 312 to remove image frequencies and blockers; and amplified by a VGA 314. The first IF spectrum as output by the VGA 314 is shown in Figure 6C.

[0043] In the third embodiment, any arbitrary channels from the downlink bands can be down-converted to arbitrarily spaced channels at IF band by using a configurable LO2. A second down-conversion of the two input signals is conducted by a mixer 316 with LO2A and LO2B, respectively. The second IF spectrum after being filtered by a filter 318 is shown in Figure 6D. LO2A and LO2B frequencies are adjustable so that the second down-conversion causes the multi-service downlink bands to be located in the second IF bandwidth separated from each other as shown in Figure 6D.

[0044] As an alternative, LOlA and LO2A may be adjustable and LO2A and LO2B may be fixed, or both LOs may be adjustable. Multiple LO frequencies can also be used to place the downlink bands of multiple services anywhere within a defined second IF bandwidth. The final intermediate frequency is further down sampled by an ADC 324 after being processed by filters 318, 322 and the VGA 320. By minimizing the second IF bandwidth, the sampling frequency of the ADC 324 can be adaptive, thus minimizing power consumption of the final digital down conversion to baseband.

[0045] Figure 7 is a block diagram of a look-up table (LUT) 400 in the modem of the receiver used to implement adaptive frequency down-conversions in accordance with the present invention. The desired services, sampling bandwidth and desired second IF are used as inputs to the LUT 400, and the LUT 400 outputs the LOl and LO2 frequency settings and the ADC sampling frequency. The LUT 400 optimizes the frequency plan, sample frequency and sampling bandwidth according to the available services and the SINAD measurements. The LUT may be utilized in any embodiments of the present invention. [0046] Figure 8 is a block diagram of a LO frequency synthesizer 500 for synthesizing frequencies for local oscillators in accordance with the present invention. Since the receivers shown in the second and third embodiments require multiple LO frequencies, the synthesizer 500 must be able to generate these frequencies. The LO frequency synthesizer 500 comprises a reference oscillator 502 and one or more synthesizers 504. The LO frequency synthesizer may optionally further comprise one or more isolators 506 and one or more circulators 508. The reference oscillator 502 generates the reference frequency which is input into the plurality of synthesizers 504. Each synthesizer 504 is tuned to generate IF frequencies in accordance with the LOl and LO2 frequency settings generated by the LUT 400. The IF frequencies generated by the synthesizers 504 are sent to a LO port of a mixer to down-convert the input signals.

[0047] A circulator 508 is preferably used to combine the two synthesizers'

LO frequencies in a low loss combining scheme that will minimize synthesizer power consumption. Isolators 506 are provided at the output of each synthesizer 504 to provide sufficient reverse isolation to eliminate frequency pulling in either synthesizer due to the other synthesizer. Alternatively, buffer amplifiers in the synthesizers 504 may be used to provide isolation. This allows the synthesizer approach to be further simplified by removing the isolators 506. [0048] Figure 9 is a flow diagram of a process 600 for simultaneously processing multiple wireless communication services in a receiver in accordance with the present invention. More than one service is received simultaneously via a wireless interface (step 502). Each service is transmitted via a different carrier frequency band. The received carrier frequency bands are down-converted to IF bands using a local oscillator (LO) such that the down-converted frequency bands fall into a single IF band (step 504).

[0049] In an alternative embodiment, the SDR simultaneously receives two or more services and/or channels by utilizing two or more summed local oscillators to independently control the final IF frequencies of the two or more services and/or channels and to adaptively select the two or more local oscillator frequencies and sampling frequency. The SDR in accordance with this embodiment of the present invention adaptively minimizes the sampling frequency and thus reduces the power consumption of the ADC and the processing blocks in the modem and increases overall battery life. This embodiment of the present invention can be implemented both in a base station and a WTRU.

[0050] Figure 10 is a block diagram of a receiver 600 for adaptively selecting LO frequencies and a sampling frequency for analog-to-digital conversion of a plurality of simultaneously received input signals in accordance with the present invention. The receiver 600 comprises an antenna 602, a low noise amplifier (LNA) 604, a mixer 606, two LOs 608a and 608b, a summer 618, an ADC 610, a digital IF processing unit 612, a baseband processing unit 614, and a controller 616. Two or more input signals are detected simultaneously by the antenna 602 for two or more services and/or channels. Each service and/or channel is transmitted via a different carrier frequency band and is subject to a unique signal-to-interference, noise and distortion ratio (SINAD) requirement. The LNA 604 amplifies the received input signals.

[0051] Each LO 608a, 608b generates a LO signal of a corresponding frequency for each service and/or channel. Figure 1 illustrates only two LOs as an example, but more than two LOs can be used to place the downlink bands of multiple services and/or channels anywhere within the final IF bandwidth. The frequencies of the LO signals are controlled by the controller 616. The LO signals are summed together by the summer 618 and forwarded to the mixer 606.

[0052] The mixer 606 mixes the input signals with LO signals to convert each RF input signal to an IF signal. Only one stage of mixing is illustrated in Figure 1. However, it should be noted that more than one stage of mixing may be implemented to convert each RF signal to a final IF signal. The final IF bands are selected such that the IF bands of the services and/or channels spectrally adjacent or overlap each other to some degree. The spectral overlap may result in interference within the receiver to one or both of the bands and/or channels. [0053] Figures 11A-11F are block diagrams of IF spectra illustrating frequency translation of RF input signals to final IF bands in accordance with the present invention. The shaded region in Figures 1 IA- HF represents the frequency channel of interest.

[0054] The LO frequencies are adjusted so that the down-conversion causes the input signals to be converted in the final IF bands adjacent or overlapping each other to some degree as shown in Figures HA- HF. In Figure HA, the IF bands for the services are adjacent and do not overlap each other. Therefore, no interference is caused by one band to the other. In Figure HB, the two IF bands overlap each other only in the non-interested frequency channels. In Figures HC and HD, one desired channel gets an interferer and in Figures HE and HF, both desired channels get interferers. In Figure HF, the entire IF band of one service and/or channel is overlapped to the other IF band. [0055] In order to avoid aliasing of any region of the IF bands, the sampling frequency should be set to a value at least twice higher than the highest frequency component of the highest IF band. The sampling frequency can be lower than that value, in that aliasing of a region of an IF band not within a channel of interest is acceptable. Therefore, the sampling frequency is determined by the service and/or channel having the highest frequency component among a plurality of services and/or channels processed simultaneously. A half of the minimum sampling frequency for avoiding aliasing in a channel of interest is indicated by the solid arrow in Figures HA-HF. A half of the minimum required sampling frequency for avoiding aliasing in the frequency band in interest is indicated by the dashed arrow in Figures HA-HF. The sampling frequency can be even lower than that shown by the dashed arrow, if SINAD degradation due to the aliasing of the upper frequency components into the channel of interest is tolerable.

[0056] As the degree of overlapping increases from Figure HA to Figure

HF, the sampling frequency decreases but the interference in the channels of interest increases. Therefore, the overlapping condition and sampling frequency should be selected considering both the sampling frequency and the interference. [0057] The selected IF bandwidth and the overlapping condition at the final IF band is adaptively adjusted as a function of the measured SINAD of the simultaneous services and/or channels of interest. Each service and/or channel has a minimum SINAD criterion that must be satisfied. Referring back to Figure 10, the baseband processing unit 614 measures SINADs at various overlap conditions and the controller 616 selects the overlap condition with the lowest sampling frequency satisfying the minimum SINAD criteria as the optimal sampling frequency.

[0058] The ADC 610 converts the IF band signals to digital signals at the sampling frequency set by the controller 616. The digital IF processing unit 612 and the baseband processing unit 614 process the digital signals for the services. The digital IF processing unit 612 performs final frequency conversion from IF to base band. The digital IF processing unit 612 separates the services from each other.

[0059] By adaptively controlling the final IF bands of the services and/or channels, the sampling frequency can be adaptively minimized. Minimizing the sampling frequency reduces the power consumption of the ADC and the processing blocks in the modem and increases overall battery life. [0060] Channel conditions, (such as distance from cells, changes in adjacent channels, etc.), changes over time. The selection of the overlap condition and the optimal sampling frequency is re-evaluated at some rate. Because the presence or absence of adjacent channels is unknown to the WTRU and can change at a rate faster than that anticipated for the above described re-evaluation, in order to prevent unacceptable sudden degradation of connections, the evaluation of the spectral overlapping and selection of the optimal sampling frequency can be confined to non-connected or idle periods, or periods in which only packet data is received. During periods in which sudden degradation is not acceptable, the receiver operates without spectral overlap at the highest sampling frequency supporting this condition.

[0061] Regardless of the selection of the overlap condition and optimal sampling frequency, the sampling frequency can be further reduced by deliberately introducing aliasing in the frequency band which is not in interest. [0062] Figure 12 is a flow diagram of a process 800 for adaptively selecting the sampling frequency for analog-to-digital conversion of a plurality of input signals in a receiver in accordance with the present invention. A receiver receives two or more input signals for two or more services and/or channels simultaneously (step 802). Each service and/or channel is subject to a minimum SINAD requirement. The input signals are converted to IF band signals by mixing the input signals with LO signals (step 804). The LO frequencies are adjusted such that the converted IF band signals of the input signals are spectrally adjacent or overlapping each other to some degree. The SINAD of the services and/or channels are measured at each of a plurality of spectrally overlapping conditions (step 806). The LO frequencies and the sampling frequency for analog-to-digital conversion of the IF signals are selected based on the SINAD measurement results (step 808). The steps 806 and 808 are preferably repeated, periodically or non-periodically.

[0063] Although the features and elements of the present invention are described in the preferred embodiments in particular combinations, each feature or element can be used alone without the other features and elements of the preferred embodiments or in various combinations with or without other features and elements of the present invention.

Claims

CLAIMS What is claimed is:

1. A method for processing multiple wireless communication services in a receiver simultaneously, the method comprising: receiving at least two services simultaneously via a wireless interface, each service being transmitted via a different carrier frequency band; down-converting the carrier frequency band to an intermediate frequency (IF) band using at least one local oscillator (LO), whereby the multiple carrier frequency bands are down-converted into a single IF band.

2. The method of claim 1 wherein a frequency of the LO is selected such that the down-converted frequency bands are folded together in the signal IF band.

3. The method of claim 1 wherein a frequency of the LO is selected such that the down-converted frequency bands are adjacent each other in the IF band.

4. The method of claim 1 wherein a frequency of the LO is selected such that the down-converted frequency bands are separated from each other in the IF band.

5. The method of claim 4 wherein the frequency of the LO is adjustable. i

6. The method of claim 1 further comprising the step of performing an analog-to-digital conversion of the IF band.

7. The method of claim 1 wherein a bandwidth of the IF band is dependent on receiver's signal-to-noise and distortion ratio (SINAD) measurement.

8. The method of claim 7 wherein a minimum IF bandwidth is selected when a highest SINAD is measured and a largest IF bandwidth is selected when a lowest SINAD is measured.

9. The method of claim 1 wherein the LO frequency is determined by a look-up table (LUT).

10. The method of claim 9 wherein the LUT uses as an input at least one of a desired service, a sampling bandwidth and desired final IF bandwidth.

11. A receiver for processing multiple wireless communication services simultaneously, the receiver comprising: a wireless interface for receiving at least two services simultaneously, each service being transmitted via a different carrier frequency band; a local oscillator (LO) for generating LO frequency; and a mixer for down-converting the carrier frequency band to an intermediate frequency (IF) band using the LO frequency, whereby the multiple carrier frequency bands are down-converted into a single IF band.

12. The receiver of claim 11 wherein the LO frequency is selected such that the down-converted frequency bands are folded together in the signal IF band.

13. The receiver of claim 11 wherein the LO frequency is selected such that the down-converted frequency bands are adjacent each other in the IF band.

14. The receiver of claim 11 wherein the LO frequency is selected such that the down-converted frequency bands are separated from each other in the IF band.

15. The receiver of claim 14 wherein the LO frequency is adjustable.

16. The receiver of claim 11 further comprising an analog-to-digital converter (ADC) for converting the IF band signals to a baseband signals.

17. The receiver of claim 11 wherein a bandwidth of the IF band is dependent on receiver's signal-to-noise and distortion ratio (SINAD) measurement.

18. The receiver of claim 17 wherein a minimum IF bandwidth is selected when a highest SINAD is measured and a largest IF bandwidth is selected when a lowest SINAD is measured.

19. The receiver of claim 11 wherein the LO frequency is determined by a look-up table (LUT).

20. The receiver of claim 19 wherein the LUT uses as an input at least one of a desired service, a sampling bandwidth and desired final IF bandwidth.

21. A method for adaptively selecting a sampling frequency for analog- to-digital conversion of a plurality of input signals in a receiver, each input signal carrying a different service via a different frequency band, the method comprising:

(a) simultaneously receiving at least two input signals for at least two services, each service being subject to a minimum signal-to-interference, noise and distortion ratio (SINAD) requirement;

(b) converting the input signals to intermediate frequency (IF) band signals by mixing the input signals with local oscillator (LO) signals, said LO frequencies being adjusted such that the converted IF band signals of the input signals are at least spectrally adjacent each other; (c) measuring said SINAD of the services at each of a plurality of spectrally overlapping conditions; and

(d) selecting the LO frequencies and a sampling frequency for analog-to- digital conversion of the IF signals based on the SINAD measurement results.

22. The method of claim 21 wherein said converted IF band signals are overlapping.

23. The method of claim 22 wherein the sampling frequency is selected to a minimum value for overlapping IF band signals that satisfy the minimum SIN AD requirements for the services.

24. The method of claim 21 wherein the steps (a)-(d) are repeated for reevaluating the selected sampling frequency and the LO frequencies.

25. The method of claim 24 wherein the reevaluation of the selected sampling frequency and the LO frequencies is performed periodically.

26. The method of claim 21 wherein the sampling frequency and the LO frequencies are selected such that no aliasing is introduced.

27. The method of claim 21 wherein the sampling frequency and the LO frequencies are selected to introduce aliasing in a portion of a frequency band not in interest, whereby the sampling frequency is reduced.

28. The method of claim 21 wherein the receiver is configurable by software.

29. A receiver for adaptively selecting local oscillator (LO) frequencies and a sampling frequency for analog-to-digital conversion of a plurality of input signals, each input signal carrying a different service via a different frequency band, the receiver comprising: an antenna for receiving a plurality of input signals for the services simultaneously, each service being subject to a minimum signal-to-interference, noise and distortion ratio (SINAD) requirement; a plurality of LOs for generating LO frequency signals; a mixer for mixing the input signals to the LO signals to generate an intermediate frequency (IF) band signals, said LO frequencies being adjusted such that the converted IF band signals of the input signals are at least spectrally adjacent each other; an analog-to-digital converter (ADC) for generating digital signals by sampling the IF band signals at the sampling frequency; a baseband processor for measuring said SINAD of the services at each of a plurality of spectrally overlapping conditions; and a controller for adjusting the LO frequency and the sampling frequency based on the SINAD measurement results.

30. The receiver of claim 29 wherein said converted IF band signals are overlapping.

31. The receiver of claim 30 wherein the sampling frequency is selected to a minimum value for overlapping IF band signals that satisfy the minimum SINAD requirements for the services.

32. The receiver of claim 29 wherein the controller subsequently reevaluates the selected sampling frequency and the LO frequencies.

33. The receiver of claim 32 wherein the reevaluation of the selected sampling frequency and the LO frequencies is performed periodically.

34. The receiver of claim 29 wherein the sampling frequency and the LO frequencies are selected such that no aliasing is introduced.

35. The receiver of claim 29 wherein the sampling frequency and the LO frequencies are selected to introduce aliasing in a frequency band not in interest, whereby the sampling frequency is reduced.

36. The receiver of claim 29 wherein the receiver is configurable by software.