Method and Arrangement for Transmitting and Receiving RF Signals Through Various Radio Interfaces of Communication Systems

Abstract

A method and arrangement for transmitting and receiving RF signals, associated with different radio interfaces of communication systems, employ a direct conversion based transceiver which substantially comprises one receive signal branch and one transmit signal branch. Mixing frequencies of the different systems are generated by a single common by use of an output frequency divider in combination with the synthesizer, and by use of filtering corresponding to a system channel bandwidth by means of a controllable low-pass filter operating at baseband frequency.

Description

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a continuation of U.S. application Ser. No. 14/272,191, filed May 7, 2014, which is a continuation of U.S. application Ser. No. 13/614,272, filed Sep. 13, 2012, which is a continuation of U.S. application Ser. No. 12/136,465, filed Jun. 10, 2008, which is a continuation of U.S. application Ser. No. 09/856,746, filed May 24, 2001 (issued as U.S. Pat. No. 7,415,247 on Aug. 19, 2008), which is a U.S. national stage of PCT/FI99/00974, filed Nov. 25, 1999, which is based on and claims priority to Finnish application no. 982559, filed Nov. 26, 1998, all incorporated by reference herein.

The invention relates to a method and arrangement for transmitting and receiving RF signals associated with various radio interfaces of communication systems. The invention finds particular utility in transceivers of general-purpose mobile stations.

Mobile communication systems are developing and expanding rapidly which has led to a situation in which there are in many areas systems complying with several different standards. This has brought about a need for mobile stations that can be used in more than one system. Good examples are the digital systems called GSM (Global System for Mobile communications) and DCS (Digital Cellular System), which operate on different frequency bands but have otherwise similar radio interfaces. In addition, the modulation, multiplexing and coding schemes used may be different. The systems mentioned above use the time division multiple access (TDMA) method; other methods include the frequency division multiple access (FDMA) and code division multiple access (CDMA).

One possible way of making a mobile station capable of operating in multiple systems is to have in the mobile station completely separate signal paths for each system. This, however, would lead to an unreasonable increase in the mobile station size and manufacturing costs. Therefore, the goal is to design a mobile station in which the differences relating to the radio interfaces of the various systems could be largely dealt with by means of programming, instead of having separate signal processing paths.

It is known e.g. from patent application document EP 653851 a transceiver arrangement using one local oscillator the frequency of which falls between the lower operating frequency band and the higher operating frequency band such that one and the same intermediate frequency (IF) can be used for both operating frequency bands. However, the disadvantage of such a solution is that the necessary IF stages make the implementation rather complex, and the manufacturing costs of the device will be high because of the great number of components. Furthermore, the IF stages require filters in order to eliminate spurious responses and spurious emissions. In addition, channel filtering at the intermediate frequency sets great demands on the IF filters.

In a direct-conversion, or zero-IF, receiver the radio-frequency (RF) signal is directly converted into baseband without any intermediate frequencies. Since no IF stages are needed, the receiver requires only a few components, therefore being an advantageous solution for general-purpose mobile stations which have multiple signal branches for different systems. To aid in understanding the problems relating to the direct conversion technique and prior art it is next described in more detail a prior-art solution.

FIG. 1 shows a direct conversion based arrangement for realizing a dual frequency band transceiver, known from the Finnish Patent document FI 100286. Depending on the receive frequency band, a RF signal received by an antenna is coupled by means of switch 104 either to a first receive branch (DCS) or second receive branch (GSM).

If the received signal is in the DCS frequency band, it is conducted to bandpass filter 106, low-noise amplifier (LNA) 108 and bandpass filter 110. After that the signal is brought to block 112 which produces signal components having a 90-degree phase difference. The in-phase component I and quadrature component Q are further conducted by means of switches 114 and 134 to mixers 116 and 136. The mixers get their mixing signals from a DCS synthesizer 140 the frequency of which corresponds to the received carrier frequency so that the mixing produces the in-phase and quadrature components of the complex baseband signal. The baseband signal is further processed in the receive (RX) signal processing unit, block 139.

If the signal received is a USM signal, switch 104 directs the received signal to the GSM branch which comprises, connected in series bandpass filter 126, low-noise amplifier 128, bandpass filter 130 and phase shifter 132 which generates two signals with a mutual phase difference of 90 degrees. The signals are further conducted by means of switches 114 and 134 to mixers 116 and 136 where the mixing frequency is now determined by a signal coming from the GSM synthesizer 150 via switch 161. The signals produced by the mixers are further conducted to the baseband RX signal processing unit 139.

The DCS synthesizer comprises in a known manner a phase-locked loop (PLL) which includes a voltage-controlled oscillator (VCO) 141 the output signal of which is amplified at amplifier 146 thus producing the synthesizer output signal. The frequency of the signal from oscillator 141 is divided by an integer Y in divider 142 and the resulting signal is conducted to phase comparator 43. Similarly, the frequency of the signal generated by reference oscillator 158 is divided by an integer X in divider 144 and conducted to phase comparator 143. The phase comparator produces a signal proportional to the phase difference of said two input signals, which signal is conducted to a low-pass filter (LPF) 145 producing a filtered signal that controls the voltage-controlled oscillator 141 The phase-locked loop described above operates in a known manner in which the output frequency of the synthesizer becomes locked to the frequency coming to the phase comparator from the reference frequency branch. The output frequency is controlled by varying the divisor Y.

The GSM synthesizer 150 comprises a voltage-controlled oscillator 150, amplifier 156, dividers 152 and 154, phase comparator 153 and a low-pass filter 155. The GSM synthesizer operates like the DCS synthesizer described above, but the output frequency of the GSM synthesizer corresponds to GSM frequency bands.

In the transmitter part, a baseband complex transmit (TX) signal is processed in a TX signal processing unit wherefrom the in-phase and quadrature components of the signal are conducted to mixers 162 and 182 that produce a carrier-frequency signal by multiplying the input signal by the mixing signal. If the transmission is at the DCS frequency, switch 161 selects the DCS synthesizer's output signal as the mixing signal. The carrier-frequency signal is conducted through switch 164 to the DCS branch where a 90-degree phase shift is first produced between the in-phase component and quadrature component, and the resulting signals are then summed, block 166. The resulting DCS signal is conducted to bandpass filter 168, amplifier 170, and bandpass filter 172. The RF signal thus produced is further conducted to the antenna 102 via switch 180.

If the transmission is at the GSM frequency, the output signal of the GSM synthesizer is used as the mixing signal. The resulting carrier-frequency signal is conducted to the GSM branch in which it is processed in the same manner as in the DCS branch blocks 186, 188, 190 and 192. The RF signal thus produced is conducted to the antenna 102 via switch 180. One and the same antenna 102 can be used in both transmission and reception if the TX and RX circuits are coupled to the antenna through a duplex filter, for example. If the apparatus is designed to operate in two or more frequency bands, it needs separate filters for each frequency band.

The circuit arrangement described above has, however, some disadvantages. First, separate carrier-frequency signal branches in the receiver and m the transmitter add to the complexity, size and manufacturing costs of the transceiver. Second, each operating frequency band needs a separate synthesizer of its own.

An object of the invention is to provide a simple solution for realizing a programmable transceiver operating in a plurality of systems in such a manner that the aforementioned disadvantages related to the prior art can be avoided.

In the direct conversion based transceiver according to the invention signal processing can be performed using one and the same signal processing line regardless of the system. This is achieved using the signal processing steps set forth below.

The method according to the invention for processing signals received from different radio interfaces of communication systems is characterized in that it comprises steps in which

• • a carrier-frequency signal is received from a radio interface,
  • the carrier-frequency signal is bandpass-filtered,
  • the filtered carrier-frequency signal is amplified,
  • an RX mixing signal at the receive frequency is generated,
  • a complex baseband signal is generated from the received carrier-frequency signal by mixing it with the RX mixing signal,
  • the baseband signal generated is low-pass-filtered,
  • the baseband signal generated is amplified,
  • the baseband signal is converted digital, and
  • the baseband signal converted digital is processed to produce an information signal encoded and modulated into the received signal.

The method according to the invention for processing signals transmitted to different radio interfaces of communication systems is characterized in that it comprises steps in which

• • a digital baseband quadrature signal is generated on the basis of the information signal to be transmitted,
  • the digital baseband signal is converted analog,
  • a TX mixing signal at the transmit frequency is generated,
  • a carrier-frequency transmission signal is generated from the baseband signal by mixing it with the TX mixing signal,
  • the carrier-frequency signal generated is amplified, and
  • the transmission signal is sent to the radio interface.

The direct-conversion receiver according to the invention operating at different interfaces of communication systems is characterized in that it comprises

• • antenna means for receiving a radio-frequency signal,
  • bandpass filter for filtering a carrier-frequency signal,
  • first RX amplifier for amplifying the filtered carrier-frequency signal,
  • means for generating an RX mixing signal at the receive frequency,
  • mixing means for generating a complex baseband signal from the received signal using the RX mixing signal,
  • low-pass filter for filtering the baseband signal,
  • second amplifier for amplifying the baseband signal,
  • analog-to-digital converter for converting the baseband signal digital, and
  • means for processing the baseband signal converted digital to produce an information signal encoded and modulated into the received signal.

The direct-conversion transmitter according to the invention operating at different radio interfaces of communication systems is characterized in that it comprises

• • means for generating a digital baseband quadrature signal on the basis of the information signal to be transmitted,
  • digital-to-analog converter for converting the baseband transmission signal analog,
  • synthesizer for generating a TX mixing signal at the transmit frequency,
  • mixing means for producing a signal at the carrier frequency from the baseband transmission signal using the TX mixing signal,
  • TX amplifier for amplifying the signal at the carrier frequency, and
  • antenna means for transmitting the amplified transmission signal at the carrier frequency.

Other preferred embodiments of the invention are described in the dependent claims.

In the present invention, signal band limiting is advantageously performed at the baseband frequency so that there is no need for “steep” filters and, therefore, system-specific filter lines. Filtering can thus be performed as low-pass filtering using a filter with a controllable cut-off frequency. This way, it is possible to completely avoid separate system-specific channel filtering circuits.

To enable the generation of mixing frequencies of the different operating frequency bands by one and the same synthesizer it is advantageously used frequency division of the synthesizer output signal. If the synthesizer's operating frequency is set higher than the frequencies used in the systems, it is possible to generate, in conjunction with the synthesizer frequency division, two mixing signals with a 90-degree phase difference, thus avoiding the need for phase shifters on the signal line and achieving a good phase accuracy.

Using the solution according to the invention it is possible to realize a general-purpose transceiver which is considerably simpler and more economical to manufacture than prior-art solutions. The circuit arrangement according to the invention requires only one TX signal branch and one RX signal branch. Moreover, one and the same synthesizer may be used to generate the mixing signals. Furthermore, there is no need for channel filters operating at the radio frequency. Therefore, the circuitry can be easily integrated. Since the invention involves only a few components, the advantages of the transceiver according to the invention include small size and low power consumption.

The invention will now be described in more detail with reference to the accompanying drawing wherein

FIG. 1 shows a block diagram of a dual-band direct-conversion transceiver according to the prior art,

FIG. 2 shows in the form of block diagram a solution according to the invention for a direct-conversion transceiver operating in multiple systems.

FIG. 1 was already discussed in conjunction with the description of the prior art. Next, a transceiver according to the invention will be described, referring to FIG. 2.

FIG. 2 shows in the form of block diagram a transceiver according to the invention. A RF signal received through an antenna is conducted via matching circuits 1 to controllable bandpass filters 2. The matching circuits 1 may advantageously be controllable (AX) with respect to the operating frequency band. A controllable bandpass filter 2 may be advantageously realized using a plurality of bandpass filters so that the RF signal is conducted via switch elements controlled by a control signal FX1 from the matching circuit 1 to the bandpass filter that corresponds to the selected operating frequency band. The bandpass filter may also be realized so as to be adjustable and tuneable by means of programming. The bandpass filtered carrier-frequency signal is further conducted to a low-noise amplifier 4, the gain of which is advantageously controllable. The control signal is marked GX1 in the drawing. In addition to amplifier 4, it is also possible to have integrated amplifiers in connection with the bandpass filters.

The signal is then conducted to a mixer 5 in which the carrier-frequency signal is mixed with an RX mixing signal at the receive frequency to produce a baseband quadrature signal. The RX mixing signal is advantageously generated by a synthesizer 10 the output signal frequency of which is divided by a divider 11 so as to correspond to the selected receive frequency. The synthesizer 10 operates in a similar manner as the synthesizers depicted in FIG. 1. Thus it comprises a voltage-controlled oscillator VCO which produces an output signal. The frequency of the VCO output signal is divided by S1 in a divider in the phase-locked loop PLL. The resulting signal is conducted to a first input of a phase comparator in the phase-locked loop. Similarly, the frequency of a signal generated by a reference oscillator in the phase-locked loop PLL is divided by an integer and conducted to a second input of the phase comparator. The phase comparator produces a signal which is proportional to the phase difference of the two input signals and conducted to a low-pass filter, and the filtered signal then controls the voltage-controlled oscillator VCO. The output frequency is controlled by varying the divisor S1.

The synthesizer output signal is divided in divider 11 by N1 so that the RX mixing signal corresponds to the selected receive frequency band. The output frequency of the synthesizer may be e.g. in the 4-GHz band, so that with 2-GHz systems the synthesizer output frequency is divided by two, and with 1-GHz systems it is divided by four (N1). This way, systems operating in the 1-GHz and 2-GHz bands can be covered with a synthesizer the operating frequency band of which is narrow with respect to the operating frequency.

To produce a quadrature baseband signal the mixer needs two mixing signals with a phase shift of 90 degrees. Phase-shifted components may be produced by a phase shifter in connection with the mixer or they may be produced as quotients generated already in the frequency divider 11, thus achieving an accurate phase difference. Therefore, it is advantageous to use a synthesizer operating frequency which is a multiple of the highest system frequency.

The in-phase component 1 and quadrature component Q from the mixer 5 are further conducted to low-pass filters 6. The higher cut-off frequency of the low-pass filters is advantageously controllable with control signal FX3. Thus the filtering can be performed at a bandwidth corresponding to the selected radio interface, and since the filtering is performed at baseband, it is easy to get the filtering function steep. Also, no strict demands are set on the bandpass filtering (2) of the RF signal.

The baseband signal is further conducted to a gain control block 7 which possibly includes an offset voltage correction block. On the other hand, considering the broad bandwidth of the CDMA system, the offset voltage can easily be removed by high-pass filtering. The amplifier advantageously realizes automatic gain control (AGC). Finally, the signal is convened digital in an analog-to-digital converter 8, and the digital baseband signal is further processed in a digital signal processor (DSP) 9. Channel filtering may also be performed digitally in the DSP, whereby the low-pass filtering of the baseband signal may be performed using a fixed cut-off frequency. Then, however, the dynamics of the analog-to-digital converter must be considerably better.

In the transmitter part, a quadrature baseband signal is first digitally generated in block 9 on the basis of the information signal to be sent. The components of the digital signal are converted analog by digital-to-analog converters 14, whereafter the analog signals are low-pass filtered by low-pass filters 15. Advantageously, the cutoff frequency of the low-pass filters can be controlled with control signal FX4 so as to correspond to the specifications of the selected radio interface.

A TX mixing signal at the carrier frequency is generated by a synthesizer 13 and divider 12. The synthesizer 13 operates in a similar manner as the synthesizer 10 in the receiver pan. Moreover, the synthesizers may share a reference oscillator. The frequency of the synthesizer output signal is controlled with control signal S2 within the synthesizer's operating frequency range. The frequency of the output signal from synthesizer 13 is divided in divider 12 so as to correspond to the selected transmission frequency band. Components phase-shifted by 90 degrees are generated from the TX mixing signal in order to perform complex mixing in mixer 16. The phase-shifted components may be generated in the same way as in the receiver part.

The signal at the carrier frequency is then amplified in an amplifier 17, the gain of which is advantageously controllable in order to set the transmission power and realize automatic gain control (AGC). The control signal is marked GX3 in FIG. 2. The signal is then conducted to a power amplifier 18. The operating frequency band of the power amplifier is advantageously selectable with control signal BX. This can be achieved e.g. such that the amplifier comprises partly separate signal lines for the different operating frequency bands.

The RF signal generated is filtered by a bandpass filter 3. The pass band of the bandpass filter is advantageously controllable with control signal FX2. This can be realized in the same way as in the receiver part. The receiver and transmitter part filters 2 and 3 are advantageously realized in duplex filter pairs for each transmit-receive frequency band associated with a given system. The filters may advantageously be surface acoustic wave (SAW) or bulk acoustic wave (BAW) filters so that several filters with their switches may be attached to one component.

The control signals in the mobile station transceiver according to FIG. 2 are preferably generated in a control block of the mobile station which advantageously comprises a processing unit such as a microprocessor. The control block generates the signal on the basis of a system switch instruction input from the keypad of the mobile station, for example. System selection may be e.g. menu-based so that the desired system is selected by choosing it from a displayed menu by pressing a certain key on the keypad. The control block then generates the control signals that correspond to the selected system. The system switch instruction may also come via the mobile communication system in such a manner that data received from the system may include a system switch instruction on the basis of which the control block performs the system switch. Advantageously, a control program is stored in a memory unit used by the control block, which control program monitors the received data and, as it detects a system switch instruction in the data, gives the control block an instruction to set the control signals into states according to the selection instruction.

The implementation of the blocks described above is not illustrated in more detail as the blocks can be realized on the basis of the information disclosed above, applying the usual know-how of a person skilled in the art.

Above it was described embodiments of the solution according to the invention. Naturally, the principle according to the invention may be modified within the scope of the invention as defined by the claims appended hereto, e.g. as regards implementation details and fields of application. It is especially noteworthy that the solution according to the invention may be well applied to communication systems other than the mobile communication systems mentioned above. Apart from the cellular radio interface proper, the solution may be used to realize e.g. a GPS receiver for the location of a mobile station or other apparatus. Furthermore, the operating frequencies mentioned are given by way of example only, and the implementation of the invention is in no way restricted to them.

It is also noteworthy that the solution according to the invention may be applied to all current coding techniques such as the narrow-band FDMA (Frequency Division Multiple Access) and TDMA (Time Division Multiple Access), as well as the broadband CDMA (Code Division Multiple Access) technique. In addition, the solution according to the invention may be used to realize an FM (Frequency Modulation) receiver.

Below is a table listing some of the so-called second generation mobile communication systems to which the present invention may be applied. The table shows the most important radio interface related characteristics of the systems.

	CELLULAR SYSTEM
							DECT	PHS
				GSM Global			Digital	Personal
				System for		PDC Personal	European	Handy
			IS-95 US	Mobile		Digital	Cordless	Phone
	AMPS	IS-54/136	CDMA	Communications	DCS 1800	Cellular	Telephone	System
RX FREQ. (MHz)	869-894	869-894	869-894	935-960	1805-1880	810-826,	1880-1900	1895-1918
						1429-1453
TX FREQ. (MHz)	824-849	824-849	824-849	890-915	1710-1785	940-956	1880-1900	1895-1918
						1477-1501
RF BANDWIDTH	25 MHz	25 MHz	25 MHz	25 MHz	75 MHz	16 MHz, 24 MHz	20 MHz	23 MHz
MULTIPLE ACCESS	FDMA	TDMA/	CDMA/	TDMA/	TDMA/	TDMA/	TDMA/	TDMA/
METHOD		FDMA	FDMA	FDMA	FDMA	FDMA	FDMA	FDMA
DUPLEX METHOD	FDD	FDD	FDD	FDD	FDD	FDD	TDD	TDD
NUMBER OF	832	832, 3 users/	20, 798 users/	124, 8 users/	374, 8 users/	1600, 3 users/	10, 12 users/	300, 4 users/
CHANNELS		channel	channel	channel	channel	channel	channel	channel
CHANNEL SPACING	30 kHz	30 kHz	1250 kHz	200 kHz	200 kHz	25 kHz	1.728 MHz	300 kHz
MODULATION	FM	π/4	QPSK/	GMSK 0.3	GMSK 0.3	π/4	GFSK 0.3	π/4
		DQPSK	OQPSK	Gaussian	Gaussian	DQPSK	Gaussian	DQPSK
				filter	filter		filter

Below is another table listing some of the so-called third generation mobile communication systems to which the present invention may be applied. The table shows the most important radio interface related characteristics of the system.

CELLULAR SYSTEM	WCDMA
RX FREQ. (MHz)	2110-2170	1900-1920
TX FREQ. (MHz)	1920-1980	1900-1920
MULTIPLE ACCESS METHOD	CDMA	TDMA
DUPLEX METHOD	FDD	TDD
CHANNEL SPACING	5 MHz	5 MHz
MODULATION	QPSK
CHANNEL BIT RATE	144 kb/s in rural outdoor,
	500 kb/s in urban outdoor and
	up to 2 Mb/s in indoor

Claims

1. A direct-conversion transceiver capable of operating with different radio interfaces including a first radio interface conforming to a code division multiple access (CDMA) system and a second radio interface conforming to a time division multiple access (TDMA) system, comprising:

a first controllable bandpass filter configured to filter a received signal according to a control signal that selects one of a plurality of passbands corresponding to one of the different radio interfaces, wherein the first controllable bandpass filter has a signal path common to both the first radio interface and the second radio interface;

a low-noise amplifier configured to amplify the filtered received signal according to a control signal that controls an amount of gain, wherein the low-noise amplifier has a signal path common to both the first radio interface and the second radio interface;

a first programmable synthesizer configured to generate a first mixing signal according to a control signal corresponding to the selected one radio interface, wherein the first programmable synthesizer has a signal path common to both the first radio interface and the second radio interface;

a first frequency divider coupled to the first programmable synthesizer and configured to divide a frequency of the first mixing signal by two to provide a first divided frequency signal according to a control signal corresponding to the selected one radio interface;

a first mixer coupled to the low-noise amplifier and configured to mix the amplified and filtered received signal with the first divided mixing signal to produce a first baseband quadrature signal, wherein the first mixer has a signal path common to both the first radio interface and the second radio interface and wherein the first mixer produces the first basedband quadrature signal on the basis of two 90-degree phase-shifted components produced from the first frequency divider and is operable to process either a TDMA signal or a CDMA signal;

a first low-pass filter coupled to the first mixer and configured to low-pass filter the first baseband quadrature signal according to a control signal corresponding to the selected one radio interface, wherein the first low-pass filter has a signal path common to both the first radio interface and the second radio interface and is operable to process either a TDMA signal or a CDMA signal;

a first gain-controlled amplifier coupled to the first low-pass filter and configured to provide gain-controlled amplification of the first low-pass filtered baseband quadrature signal, wherein the first gain-controlled amplifier has a signal path common to both the first radio interface and the second radio interface and is operable to process either a TDMA signal or a CDMA signal;

an analog-to-digital converter coupled to the first gain-controlled amplifier and configured to convert to digital form an output of the first gain-controlled amplifier;

a digital signal processor configured to receive digital output from the analog-to-digital converter and to further process said digital output;

a digital-to-analog converter coupled to the digital signal processor and configured to receive a second baseband quadrature signal therefrom and to provide analog output signals;

a second low-pass filter coupled to the digital-to-analog converter and configured to low-pass filter the analog output signals from the digital-to-analog converter according to a control signal corresponding to the selected one radio interface, wherein the second low-pass filter has a signal path common to both the first radio interface and the second radio interface and is operable to process either a TDMA signal or a CDMA signal;

a second programmable synthesizer configured to generate a second mixing signal according to a control signal corresponding to the selected one radio interface, wherein the second programmable synthesizer has a signal path common to both the first radio interface and the second radio interface;

a second frequency divider coupled to the second programmable synthesizer and configured to divide a frequency of the second mixing signal by two to provide a second divided frequency signal according to a control signal corresponding to the selected one radio interface;

a second mixer coupled to the second low-pass filter and configured to mix signals from the second low-pass filter and the second frequency divider to produce a carrier-frequency transmission signal, wherein the second mixer has a signal path common to both the first radio interface and the second radio interface and wherein the second mixer produces the carrier-frequency transmission signal on the basis of two 90-degree phase-shifted components produced from the second frequency divider and is operable to process either a TDMA signal or a CDMA signal;

a second gain-controlled amplifier coupled to the second mixer and configured to control gain according to a control signal corresponding to the selected one radio interface, wherein the second gain-controlled amplifier has a signal path common to both the first radio interface and the second radio interface and is operable to process either a TDMA signal or a CDMA signal;

a power amplifier coupled to the second gain-controlled amplifier and configured to produce an amplified output using a frequency band determined on the basis of a control signal corresponding to the selected one radio interface, wherein the power amplifier has a signal path common to both the first radio interface and the second radio interface;

a second controllable bandpass filter configured to filter an output of the power amplifier according to a control signal that selects one of a plurality of passbands corresponding to the selected one radio interface, wherein the second controllable bandpass filter has a signal path common to both the first radio interface and the second radio interface; and

a microprocessor configured to generate one or more control signals to cause selection of the selected radio interface.