Title of Invention	TELECOMMUNICATIONS SYSTEMS
Abstract	A reference frequency generator circuit for a radio frequency transmit and receive apparatus comprises: a first voltage controlled oscillator which is operable to produce a first reference frequency signal, a second voltage controlled oscillator which is operable to produce a second reference frequency signal, a switchable set of dividers, connected to receive the first and second reference frequency signals, and operable to produce a set of output reference frequency signals therefrom, a first subset of the set of output reference frequencies being derived from the first reference frequency, and a second subset of the set of output reference frequencies being derived from the second reference frequency, wherein the first and second reference frequency signals are not equal in frequency to the output reference frequency signals in the set of output reference frequency signals.

Title of Invention

TELECOMMUNICATIONS SYSTEMS

Abstract

A reference frequency generator circuit for a radio frequency transmit and receive apparatus comprises: a first voltage controlled oscillator which is operable to produce a first reference frequency signal, a second voltage controlled oscillator which is operable to produce a second reference frequency signal, a switchable set of dividers, connected to receive the first and second reference frequency signals, and operable to produce a set of output reference frequency signals therefrom, a first subset of the set of output reference frequencies being derived from the first reference frequency, and a second subset of the set of output reference frequencies being derived from the second reference frequency, wherein the first and second reference frequency signals are not equal in frequency to the output reference frequency signals in the set of output reference frequency signals.

Full Text	The present invention relates to mobile telecommunications systems, and, in particular, to systems for generating reference frequency signals in mobile telecommunications systems. Background of the Invention In mobile telecommunications systems of the GSM type, it is necessary to be able to transmit and receive on four common frequency bands - 850, 900, 1800 and 1900MHz. This requires frequency sources in the region of 900MHz and 1800MHz. Typically; current frequency sources use three different voltage controlled oscillators (VCOs), operating at about 1, 2 and 4GHz. The VCOs used for transmission operate on the same frequency as the required transmit channel and the VCOs used for reception operate at twice the required receive frequency to allow use of a well known digital divider circuit to provide in-phase and quadrature local oscillator (LO) signals. However, when implemented in an application specific integrated circuit (ASIC) , the silicon area of the 1C used by the 1 and 2 GHz VCOs has a significant upward impact on the cost of the ASIC. Also, there are significant problems with feedback to these VCOs since they operate at the same frequency as the transmitter signal. In one known previously-considered example, all of the required frequencies are generated using a single VCO combined with frequency divider circuits; for example the VCO could operate in the region of 4GHz and be divided by 2 or 4 as required to provide the lower frequencies. However, this is not a straightforward technique to use in an ASIC as the required tuning range of the VCO is large. Summary of the Present Invention According to the present invention, there is provided a reference frequency generator circuit for a radio frequency transmit and receive apparatus, the circuit comprising: a first voltage controlled oscillator which is operable to produce a first reference frequency signal, a second voltage controlled oscillator which is operable to produce a second reference frequency signal, a switchable set of dividers, connected to receive the first and second reference frequency signals, and operable to produce a set of output reference frequency signals therefrom, a first subset of the set of output reference frequencies being derived from the first reference frequency, and a second subset of the set of output reference frequencies being derived from the second reference frequency, wherein the first and second reference frequency signals are not equal in frequency to the output reference frequency signals in the set of output reference frequency signals. Brief Description of the Drawings Figure 1 illustrates a first embodiment of the present invention; Figure 2 illustrates a second embodiment of the present invention; Figure 3 illustrates a third embodiment of the present invention; and Figure 4 illustrates ranges of reference frequencies provided by VCOs used in embodiments of the present invention. Detailed Description of the Preferred Embodiments Figure 1 illustrates a first embodiment of the present invention, for providing transmitter and receiver signals suitable for use in a mobile station (MS) for use- in a mobile telecommunications network. The embodiment of Figure 1 comprises a phase lock loop circuit (PLL) comprising first and second voltage controlled oscillators (VCOA, VCOB) 2 and 4. The VCOs 2 and 4 provide output signals to an adder 6 which supplies a signal to a switchable divider 8. As will be explained in more detail below, the VCOs 2 and 4 are used independently, and so the output of the adder 6 is equivalent to the output of the chosen operating VCO. The switchable divider 8 is operable to divide the signal from the adder 6 by one or two. The output of the switchable divider 8 is supplied to a further divider 10, which is operable to divide the signal by 2. The output of the divider 10 is supplied to a programmable divider 12. The programmable divider 12 supplies an output to a phase detector 14 for comparison with a reference frequency 20. The output of the phase detector 14 is supplied to a loop filter 16, which in turn supplies a filtered control signal to each of the first and second VCOs 2 and 4. The PLL operates to stabilise the outputs of the VCOs 2 and 4, in known manner. In embodiments of the present invention the VCO is operated at 2x or 4x the desired frequency, and there is always a fixed division of 2 or 4 provided by the dividers 10 and 8. This means that the frequency provided to the input of the programmable divider is the same as if the VCO were operating at the required frequency and divider 10 and 8 were not present. The programmable divider 12 operates to lock the operating VCO to twice or four times the required output frequency of Npd*Fref, where Npd is the programmable divider modulus and Fref is the reference frequency. The fixed and programmable dividers provide a set of dividers which are used to tailor the output of the VCOs. The modulus (size) of the divider (eg. /2 or /4) can be fixed or varying. If varying appropriately, the VCOs can be frequency modulated. The varying modulus can be provided by a varying signal or by a suitable combination of varying and fixed signals. For example, the modulus may vary around a fixed point.1 The output of the second VCO 4 is also supplied to a divider 26, which is operable to divide the output of the VCO by 4. The output of the divider is supplied, via a buffer 28, to a power amplifier (not shown) of the mobile station and provides the low band transmitter signal frequency. In a similar manner, the output of the adder 6 is supplied to a divider 22 which operates to divide that summed signal by 2. The divided signal is supplied, via a buffer 24, to the power amplifier of the mobile station. This provides the high band transmitter signal frequency. In the example embodiment shown in Figure 1, the VCOs 2 and 4 are both tuned to output signals of around 4GHz, so that the high band transmitter signal frequency is 2GHz and the low band IGHz. The circuit is also operable to provide the local oscillator (LO) signals to the mobile station receiver (not shown) and this is achieved by supplying the output of the switchable divider 8 to a quadrature splitter and divider 30. The quadrature splitter and divider 30 is operable to produce a signal which is half the frequency of the input signal and has inphase and quadrature signals for supply to the receiver. In the examples given the divider 30 has a single output connection which carries the LO signal at eithei around IGHz or around 2GHz This is possible only if the receivers mixer has enough bandwidth to handle both these bands If this is not the case then respective receivers can be used for the bands with the LO signal split and routed to those receivers as required. It is a feature of the invention that the characteristics of the frequency modulation as measured at the input to the programmable divider and also at the output of the circuit (24 28) are dictated by Npd in exactly the same way as if the VCO was operated at the required final frequency and the fixed dividers 10 8 22 and 26 were omitted. Clearly the frequency modulation measured at the outputs of the VCOs will not be correct - peak deviations of the FM modulation will be twice or four times the required values. It is an advantage of an embodiment of the present invention that the modulated signal at input of programmable divider is defined by variations in Npd produces exactly the same result as for a conventional technique with the VCO equal to the final frequency. The allocation of bands of operation between VCOA and VCOB can be arranged so as to minimise the tuning range required of each VCO. Figure 4 illustrates that VCO A (2) is used for the reference frequencies for systems around 3600Mhz to 4000Mhz, and VCO B for the range around 3300Mhz to 3650Mhz. The loop dynamics of the PLL will be affected by the fixed divider in such a way as to reduce the open loop gain by 2 or 4. This is not usually significant though because the tuning sensitivity of the 4GHz VCO is usually approximately twice or A times that of a 2 or IGHz VCO respectively, so the overall loop gain with embodiments of the present invention is not changed significantly. Embodiments of the present invention can therefore provide two VCOs (2 and 4) that cover the entire required tuning range. The programmable divider of the phase locked loop circuit is presented with a signal at the same frequency as the required frequency (ie. nominally the centre frequency of the GSM channel concerned) so that the circuit behaves as if the VCO was operating at the required frequency instead of a multiple of 2 or 4 times. Figure 2 illustrates an alternative circuit layout, in which switchable divider 8 is provided by a fixed divider (2) 7 and gates 9 and 21. The gates operate to select an input signal to be transferred to the rest of the circuit. The signal routes from the VCOs 2 and 4 are determined by switching the gates 6 9 21 such that the correct VCO is used for the transmit/receive frequencies in use. The Figure 2 layout gives advantages in terms of circuit layout and size. Figure 3 shows a further enhancement where the PLL actually operates at the VCO frequency ie. 4GHz. In the case of a fractional-N PLL this allows the resolution of the divided down signals to be higher by a factor 2 or 4. By using this technique the tuning range of the VCOs is relatively small and easy to implementand the small size of 4GHz circuits allows significant cost saving relative to the IGHz VCOs. In addition the frequency of the VCO is different from the final output frequency which gives benefits in reducing the coupling effects between the output signal and the VCOs. This has the benefit of maintaining control compatibility between different architectures. CLAIMS 1. A phase lock loop circuit for a radio frequency transmit and receive apparatus, the circuit comprising: a first voltage controlled oscillator which is operable to produce a first reference frequency signal, • a second voltage controlled oscillator which is operable to produce a second reference frequency signal, a switchable set of dividers, connected to receive the first and second reference frequency signals, and operable to produce a set of output reference frequency signals therefrom, a first subset of the set of output reference frequencies being derived from the first reference "frequency, and a second subset of the set of output reference frequencies being derived from the second reference frequency, and a VCO control means connected to receive an external reference signal and a feedback signal, and operable to supply a control voltage to the first and second voltage controlled oscillators in dependence upon received external reference and feedback signals, so as to maintain desired first and second reference frequency signals, wherein the first and second reference frequency signals are not equal in frequency to the output reference frequency signals in the set of output reference frequency signals, and wherein the set of dividers comprises: a first divider for selectively receiving the first or second reference frequency signals, and for producing a high band output reference frequency signal for a transmitter, a second divider for receiving the second reference frequency signal and for producing a low band output reference frequency signal for the transmitter, a third divider for selectively receiving the first or second reference frequency signals and for producing local oscillator output reference frequency signals for a receiver, and for producing a feedback signal for supply to the VCO control means. 2. A circuit as claimed in claim 1, wherein the set of -output reference frequency signals have frequencies corresponding to frequencies required for GSM850, GSM900, DCS1800 and PCS1900 mobile telecommunications standards . . A circuit as claimed in claim 1 or 2 , wherein the first and second voltage controlled oscillators are selectively controlled by a phase locked loop. . A circuit as claimed in any one of the preceding claims, wherein the set of dividers is operable to vary a modulus value thereof, thereby causing the first and second voltage controlled oscillators to be frequency modulated. 5. A circuit as claimed in claim 4, wherein the modulus value has a fixed portion and a time-varying portion.

Full Text

The present invention relates to mobile telecommunications systems, and, in particular, to systems for generating reference frequency signals in mobile telecommunications systems.
Background of the Invention
In mobile telecommunications systems of the GSM type, it is necessary to be able to transmit and receive on four common frequency bands - 850, 900, 1800 and 1900MHz. This requires frequency sources in the region of 900MHz and 1800MHz.
Typically; current frequency sources use three different voltage controlled oscillators (VCOs), operating at about 1, 2 and 4GHz. The VCOs used for transmission operate on the same frequency as the required transmit channel and the VCOs used for reception operate at twice the required receive frequency to allow use of a well known digital divider circuit to provide in-phase and quadrature local oscillator (LO) signals.
However, when implemented in an application specific integrated circuit (ASIC) , the silicon area of the 1C used by the 1 and 2 GHz VCOs has a significant upward impact on the cost of the ASIC. Also, there are significant problems with feedback to these VCOs since they operate at the same frequency as the transmitter signal.
In one known previously-considered example, all of the required frequencies are generated using a single VCO combined with frequency divider circuits; for example the VCO could operate in the region of 4GHz and be
divided by 2 or 4 as required to provide the lower frequencies. However, this is not a straightforward technique to use in an ASIC as the required tuning range of the VCO is large.
Summary of the Present Invention
According to the present invention, there is provided a reference frequency generator circuit for a radio frequency transmit and receive apparatus, the circuit comprising: a first voltage controlled oscillator which is operable to produce a first reference frequency signal, a second voltage controlled oscillator which is operable to produce a second reference frequency signal, a switchable set of dividers, connected to receive the first and second reference frequency signals, and operable to produce a set of output reference frequency signals therefrom, a first subset of the set of output reference frequencies being derived from the first reference frequency, and a second subset of the set of output reference frequencies being derived from the second reference frequency, wherein the first and second reference frequency signals are not equal in frequency to the output reference frequency signals in the set of output reference frequency signals.
Brief Description of the Drawings
Figure 1 illustrates a first embodiment of the present invention;
Figure 2 illustrates a second embodiment of the present invention;
Figure 3 illustrates a third embodiment of the present invention; and
Figure 4 illustrates ranges of reference frequencies provided by VCOs used in embodiments of the present invention.
Detailed Description of the Preferred Embodiments
Figure 1 illustrates a first embodiment of the present invention, for providing transmitter and receiver signals suitable for use in a mobile station (MS) for use- in a mobile telecommunications network. The embodiment of Figure 1 comprises a phase lock loop circuit (PLL) comprising first and second voltage controlled oscillators (VCOA, VCOB) 2 and 4. The VCOs 2 and 4 provide output signals to an adder 6 which supplies a signal to a switchable divider 8. As will be explained in more detail below, the VCOs 2 and 4 are used independently, and so the output of the adder 6 is equivalent to the output of the chosen operating VCO. The switchable divider 8 is operable to divide the signal from the adder 6 by one or two. The output of the switchable divider 8 is supplied to a further divider 10, which is operable to divide the signal by 2. The output of the divider 10 is supplied to a programmable divider 12. The programmable divider 12 supplies an output to a phase detector 14 for comparison with a reference frequency 20. The output of the phase detector 14 is supplied to a loop filter 16, which in turn supplies a filtered control signal to each of the first and second VCOs 2 and 4. The PLL operates to stabilise the outputs of the VCOs 2 and 4, in known manner. In embodiments of the present invention the VCO is operated at 2x or 4x the desired frequency, and there is always a fixed division of 2 or 4 provided by the dividers 10 and 8. This means that the frequency provided to the input of the programmable divider is the same as if the VCO were operating at the
required frequency and divider 10 and 8 were not present.
The programmable divider 12 operates to lock the operating VCO to twice or four times the required output frequency of Npd*Fref, where Npd is the programmable divider modulus and Fref is the reference frequency.
The fixed and programmable dividers provide a set of dividers which are used to tailor the output of the VCOs. The modulus (size) of the divider (eg. /2 or /4) can be fixed or varying. If varying appropriately, the VCOs can be frequency modulated. The varying modulus can be provided by a varying signal or by a suitable combination of varying and fixed signals. For example, the modulus may vary around a fixed point.1
The output of the second VCO 4 is also supplied to a divider 26, which is operable to divide the output of the VCO by 4. The output of the divider is supplied, via a buffer 28, to a power amplifier (not shown) of the mobile station and provides the low band transmitter signal frequency. In a similar manner, the output of the adder 6 is supplied to a divider 22 which operates to divide that summed signal by 2. The divided signal is supplied, via a buffer 24, to the power amplifier of the mobile station. This provides the high band transmitter signal frequency.
In the example embodiment shown in Figure 1, the VCOs 2 and 4 are both tuned to output signals of around 4GHz, so that the high band transmitter signal frequency is 2GHz and the low band IGHz.
The circuit is also operable to provide the local oscillator (LO) signals to the mobile station receiver (not shown) and this is achieved by supplying the output of the switchable divider 8 to a quadrature splitter and divider 30. The quadrature splitter and divider 30 is operable to produce a signal which is half the frequency of the input signal and has inphase and quadrature signals for supply to the receiver.
In the examples given the divider 30 has a single output connection which carries the LO signal at eithei around IGHz or around 2GHz This is possible only if the receivers mixer has enough bandwidth to handle both these bands If this is not the case then respective receivers can be used for the bands with the LO signal split and routed to those receivers as required.
It is a feature of the invention that the characteristics of the frequency modulation as measured at the input to the programmable divider and also at the output of the circuit (24 28) are dictated by Npd in exactly the same way as if the VCO was operated at the required final frequency and the fixed dividers 10 8 22 and 26 were omitted. Clearly the frequency modulation measured at the outputs of the VCOs will not be correct - peak deviations of the FM modulation will be twice or four times the required values. It is an advantage of an embodiment of the present invention that the modulated signal at input of programmable divider is defined by variations in Npd produces exactly the same result as for a conventional technique with the VCO equal to the final frequency.
The allocation of bands of operation between VCOA and VCOB can be arranged so as to minimise the tuning range
required of each VCO. Figure 4 illustrates that VCO A (2) is used for the reference frequencies for systems around 3600Mhz to 4000Mhz, and VCO B for the range around 3300Mhz to 3650Mhz.
The loop dynamics of the PLL will be affected by the fixed divider in such a way as to reduce the open loop gain by 2 or 4. This is not usually significant though because the tuning sensitivity of the 4GHz VCO is usually approximately twice or A times that of a 2 or IGHz VCO respectively, so the overall loop gain with embodiments of the present invention is not changed significantly.
Embodiments of the present invention can therefore provide two VCOs (2 and 4) that cover the entire required tuning range. The programmable divider of the phase locked loop circuit is presented with a signal at the same frequency as the required frequency (ie. nominally the centre frequency of the GSM channel concerned) so that the circuit behaves as if the VCO was operating at the required frequency instead of a multiple of 2 or 4 times.
Figure 2 illustrates an alternative circuit layout, in which switchable divider 8 is provided by a fixed divider (2) 7 and gates 9 and 21. The gates operate to select an input signal to be transferred to the rest of the circuit. The signal routes from the VCOs 2 and 4 are determined by switching the gates 6 9 21 such that the correct VCO is used for the transmit/receive frequencies in use.
The Figure 2 layout gives advantages in terms of circuit layout and size.
Figure 3 shows a further enhancement where the PLL actually operates at the VCO frequency ie. 4GHz. In the case of a fractional-N PLL this allows the resolution of the divided down signals to be higher by a factor 2 or 4.
By using this technique the tuning range of the VCOs is relatively small and easy to implementand the small size of 4GHz circuits allows significant cost saving relative to the IGHz VCOs. In addition the frequency of the VCO is different from the final output frequency which gives benefits in reducing the coupling effects between the output signal and the VCOs. This has the benefit of maintaining control compatibility between different architectures.

CLAIMS
1. A phase lock loop circuit for a radio frequency transmit and receive apparatus, the circuit comprising:
a first voltage controlled oscillator which is operable to produce a first reference frequency signal, •
a second voltage controlled oscillator which is operable to produce a second reference frequency signal,
a switchable set of dividers, connected to receive the first and second reference frequency signals, and operable to produce a set of output reference frequency signals therefrom, a first subset of the set of output reference frequencies being derived from the first reference "frequency, and a second subset of the set of output reference frequencies being derived from the second reference frequency, and
a VCO control means connected to receive an external reference signal and a feedback signal, and operable to supply a control voltage to the first and second voltage controlled oscillators in dependence upon received external reference and feedback signals, so as to maintain desired first and second reference frequency signals,
wherein the first and second reference frequency signals are not equal in frequency to the output reference frequency signals in the set of output reference frequency signals, and
wherein the set of dividers comprises:
a first divider for selectively receiving the first or second reference frequency signals, and for producing a high band output reference frequency signal for a transmitter,
a second divider for receiving the second reference frequency signal and for producing a low band output reference frequency signal for the transmitter,
a third divider for selectively receiving the first or second reference frequency signals and for producing local oscillator output reference frequency signals for a receiver, and for producing a feedback signal for supply to the VCO control means.
2. A circuit as claimed in claim 1, wherein the set of -output reference frequency signals have frequencies corresponding to frequencies required for GSM850, GSM900, DCS1800 and PCS1900 mobile telecommunications standards .
. A circuit as claimed in claim 1 or 2 , wherein the
first and second voltage controlled oscillators are
selectively controlled by a phase locked loop.
. A circuit as claimed in any one of the preceding
claims, wherein the set of dividers is operable to vary
a modulus value thereof, thereby causing the first and
second voltage controlled oscillators to be frequency
modulated.
5. A circuit as claimed in claim 4, wherein the modulus value has a fixed portion and a time-varying portion.

Documents:

4714-delnp-2006-abstract.pdf

4714-delnp-2006-claims.pdf

4714-delnp-2006-Correspondance Others-(05-03-2015).pdf

4714-delnp-2006-Correspondence Others-(11-02-2013).pdf

4714-delnp-2006-Correspondence Others-(12-01-2015).pdf

4714-delnp-2006-Correspondence Others-(29-11-2013).pdf

4714-delnp-2006-Correspondence Others-(30-08-2012).pdf

4714-delnp-2006-Correspondence-Others-(19-06-2013).pdf

4714-delnp-2006-correspondence-others-1.pdf

4714-delnp-2006-correspondence-others.pdf

4714-DELNP-2006-Corresponence-Others-(06-07-2009).pdf

4714-delnp-2006-description (complete).pdf

4714-delnp-2006-drawings.pdf

4714-delnp-2006-form-1.pdf

4714-delnp-2006-form-18.pdf

4714-delnp-2006-form-2.pdf

4714-delnp-2006-form-26.pdf

4714-delnp-2006-Form-3-(12-01-2015).pdf

4714-delnp-2006-Form-3-(19-06-2013).pdf

4714-delnp-2006-Form-3-(29-11-2013).pdf

4714-delnp-2006-Form-3-(30-08-2012).pdf

4714-delnp-2006-form-3.pdf

4714-delnp-2006-form-5.pdf

4714-delnp-2006-GPA-(05-03-2015).pdf

4714-DELNP-2006-Others-Documents-(03-07-2009).pdf

4714-delnp-2006-pct-210.pdf

4714-delnp-2006-pct-220.pdf

4714-delnp-2006-pct-237.pdf

4714-delnp-2006-pct-311.pdf

4714-delnp-2006-pct-402.pdf

4714-delnp-2006-pct-409.pdf

4714-delnp-2006-pct-416.pdf

Abstract.pdf

Claims.pdf

Complete Specification.pdf

FER Reply.pdf

Others.pdf

Petition under rule 137 Section 8 (1).pdf

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Patent Number

265885

Indian Patent Application Number

4714/DELNP/2006

PG Journal Number

13/2015

Publication Date

27-Mar-2015

Grant Date

20-Mar-2015

Date of Filing

17-Aug-2006

Name of Patentee

TELEFONAKTIEBOLAGET L M ERICSSON (PUBL)

Applicant Address

SE-164 83 STOCKHOLM (SE)

Inventors:

#	Inventor's Name	Inventor's Address
1	BRISTOW, ROB	9 SONNING CLOSE, BASINGSTOKE RG22 5JJ (GB)
2	MATTSSON THOMAS	TEGNERGATAN 76, S-216 14 LIMHAMN (SE)
3	JONSSON, LARS	RAPSVAGEN 32, S-247 SODRA SANDBY (SE)

PCT International Classification Number

H03L

PCT International Application Number

PCT/GB2004/004923

PCT International Filing date

2004-11-23

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	60/553,096	2004-03-15	EUROPEAN UNION
2	04250308.6	2004-01-21	EUROPEAN UNION