The present invention relates in general to an integrated tuner circuit, e.g., for use in televisions and radios, and more particularly, to the tracking of a tuner filter with an arbitrary oscillator.
Tuner technology has evolved to the point where a tuner for a television signal receiver, radio, etc., can now be formed on a single integrated circuit. Currently available integrated tuners are generally application specific, i.e., the tuners are designed for operation using specific oscillator and intermediate (IF) frequencies. Thus, different integrated tuners may be required for different RF applications.
The present invention provides an integrated tuner circuit with an arbitrary IF output The tuner includes an integrated circuit (IC) control loop, and matched external variable capacitance Ct, to achieve tracking with an arbitrary oscillator.
These and other features of this invention will be more readily understood from the following detailed description of the various aspects of the invention taken in conjunction with the accompanying drawings in which:
It should be noted that the drawings are merely schematic representations, not intended to portray specific parameters of the invention. The drawings are intended to depict only typical aspects of the invention, and therefore should not be considered as limiting the scope of the invention.
A tuned LC band-pass filter 10 is illustrated in
ωtank=ωLO±ωIF (EQU. 1)
or:
ωtank2=1/LCt (EQU. 2)
This implies that:
ωtank2Ct=1/L=constant (EQU. 3)
which leads to:
Ct::ωtank−2=(ωLO±ωIF)−2 (EQU. 4)
which is the frequency-dependent relation that is needed for tracking.
In a frequency-synthesized tuner that includes such a band-pass tuner filter 10, the local oscillator frequency ωLO of the tuner, which is applied at a mixer, relates to a reference X-tal oscillator frequency ωxtal via:
ωLO=Ndiv/Mdivωxtal (EQU. 5)
where Mdiv is a fixed-frequency-divider ratio, and Ndiv is a programmable frequency divider. Given a fixed reference X-tal oscillator frequency ωxtal, then EQU. 5 implies that:
ωLO::Ndiv (EQU. 6)
which also implies from EQU. 1 that for zero- or low-IF:
ωtank=(ωLO±ωIF)::Ndiv (EQU. 7)
For a zero-IF tuner concept, the resonance frequency ωtank of the band-pass filter 10 equals the local oscillator frequency ωLO of the tuner for proper tracking. For a near-zero IF concept ωtank≈ωLO and consequently, from EQU. 4:
Ct::ωLO−2 (EQU. 8)
From EQU. 7, this leads to:
Ct::Ndiv−2 EQU. 9)
For a low-IF IC-concept (e.g., near-zero or zero-IF), the oscillator or divided oscillator frequency can, for example, be offered via a current source to an external load capacitor Ct, which is matched with the capacitance Ct in the band-pass filter 10. An integrated tuner circuit 20 including the band-pass filter 10 and an external load capacitor Ct is illustrated in
ut(t)=Ndiv2Utcosωxtalt (EQU. 10)
it follows that:
it(t)=−ωtalCtNdivUtsinωxtalt (EQU. 11)
By making it(t) amplitude independent of Ndiv and Ct, then:
Ct::Ndiv−2 (EQU. 12)
Thus, the capacitance the external load capacitor Ct and the capacitor Ct in the band-pass filter 10 are both proportional to Ndiv−2. As such, in case of tracking between an oscillator in a zero- or low-IF frequency concept and a varicap-tuned LC band-pass filter 10 with fixed L and variable Ct the integrated tuner circuit 20 can generate a very well defined oscillator-frequency related voltage across the matched load capacitor Ct. Conversely, in case of no tracking, the voltage will deviate from the predicted oscillator frequency dependent behavior. If, in that case the integrated tuner circuit 20 would generate a tuning voltage VTUN for the capacitor Ct of the band-pass filter 10 as well as the external load Ct, a control loop can be defined such that the (frequency divided) oscillator voltage across Ct behaves as needed for tracking. The control loop will ensure that the frequency-dependent behavior for the oscillator and band-pass filter 10 is the same, which means that band-pass filter 10 and the oscillator will de-tune with the same factor all the time.
In the above-described approach, it is assumed that the external load capacitor Ct is the only external load to the integrated tuner circuit 20. However, the integrated tuner circuit 20 will also add additional capacitive load, which will cause tracking errors especially at the higher end of the frequency band, where Ct becomes small. The added capacitance (i.e., parasitic capacitance Cp) is determined by the integrated tuner circuit 20 package as well as by on-chip capacitance. Since the value of Cp can be estimated beforehand during design of the integrated tuner circuit, compensation in the control loop 30 can be taken into account.
The present invention provides a fixed-frequency control loop 30 (
In view of the above analysis, the control loop 30 has been designed to produce a signal having a relevant component given by the expression:
1−(αωxtal2R2C)N2Ct (EQU. 13)
where α is a variable gain, ωxtal is the X-tal oscillator 32 frequency, R is a resistance, C is a capacitance, and N is a programmable value proportional to Ndiv for setting the value of ωLO. Ndiv has been converted into N, because Ndiv is usually a 15 bit number, which enables small oscillator steps, but the band-pass filter 10 steps are allowed to be much larger and consequently N can be limited to, e.g., a seven bit word proportional to Ndiv. From EQU. 7, therefore:
ωLO≈ωtankNdiv≈N (EQU. 14)
Both previous equations (ωLO::Ndiv (EQU. 6) and ωtank=(ωLO±ωIF)::N (EQU. 7)) are valid and implicitly an ωLO and ωIF dependent relation between N and Ndiv follows. By programming N and Ndiv accordingly, tracking is obtained. In case of zero- or low-IF, Ndiv≈N will be sufficient for tracking.
In EQU. 13, N and Ct are the only oscillator frequency dependent components. As such, as long as ωLO::Ndiv≈N, the capacitance Ct will be tuned such that:
1−(αωxtal2R2C)N2Ct→0 (EQU. 15)
to ensure that the band-pass filter 10 keeps tracking with the desired oscillator frequency.
In the control loop 30, the output U0 of oscillator 32 is passed through an analog multiplying circuit 34 of a type known in the art to produce a signal U0N2. For example, as illustrated in
−U0{1−αN2(jω0RC−ωxtal2R2CCp)} (EQU. 16)
A feedback stage 42 is provided to produce a signal 44 given by:
−αN2U0{jωxtalRC−ωxtal2R2C(Ct+Cp)} (EQU. 17)
In the block diagram, it is assumed that compensation for the parasitic capacitance Cp of the integrated circuit 20 has been provided during the integrated circuit design phase and, as such, Cp appears in stage 38 and in parallel to the external load capacitance Ct.
The circuit analysis for deriving the expressions presented in EQUS. 16 and 17 from stages 38 and 40, respectively, is assumed to be within the scope of those skilled in the art and will not be presented in detail herein. Also, it should be appreciated that the expressions presented in EQUS. 16 and 17 may be provided using analog and/or digital circuitry other than that disclosed herein and illustrated in
The signals 40, 44 presented in EQUS. 16 and 17, respectively, are combined in an adder 46, resulting in a signal 48 given by:
U0{1−(αωxtal2R2C)N2Ct} (EQU. 18)
After mixing 50 the signal 38 with the oscillator 32 signal, and integrating 52 to a 30 tuning voltage VTUN, Ct is controlled such that the expression presented in EQU. 13, namely, 1−(αωxtal2R2C)N2Ct→0, is realized. Consequently, Ct:: (ωLO±ωIF)−2, or Ct::ωLO−2 for zero- and low-IF, which are the frequency dependent relations needed for tracking.
In the present invention, the fixed-frequency control loop 30 uses the value N, which is approximately equal to the frequency division ratio Ndiv, for oscillator tuning without using the actual oscillator frequency WLO itself. In the high-IF case where the ratio N, used for tuning the band-pass filter IO tracking, does not correspond with Ndiv (i.e., Ndiv≠N), the band-pass filter 10 may be tuned to a frequency different from the than the desired oscillator frequency (ωLO. In this case, separate programming is required for Ndiv and N. However, after a single alignment, the frequency to which the band-pass filter 10 is tuned is accurately known for each value of N. The alignment may be accomplished via the variable gain α provided by the adjustable gain circuit 36, and/or by adjusting the fixed value of the inductor L in the band-pass filter 10. Alternately, or in addition, for a small frequency offset between the band-pass filter 10 and the oscillator frequency ωLO, some mismatch can be given to the external load capacitance Ct relative to the capacitance Ct in the band-pass filter 10. Consequently, by independently addressing the values for N, the band-pass filter 10 can be tuned to each wanted IF distance from the desired oscillator frequency ωLO. It should be noted that for non-zero concepts, a frequency offset may also be realized by adaptation of the voltage dependency of the external load capacitance Ct.
As stated above, the invention is not limited to zero- or low-IF applications. After the single frequency alignment by, e.g., adjusting the gain value α, with programmable N and ωxtal, the tuned LC band-pass filter 10 is tuned to each wanted frequency. Along this way, the band-pass filter 10 becomes a “frequency synthesized” filter, which is locked to “virtual oscillator frequency” Nωxtal, since this frequency need not be present in the IC.
The freedom to choose the value for N allows the present invention to provide a single integrated tuner circuit with arbitrary IF output. Supradyne, infradyne, zero-IF, up-conversion or one-oscillator applications can all be realized with tracking using the present invention. These applications may be provided “all-in-one” under software control using the same integrated tuner circuit.
Several other features provided by the present invention should also be noted. For example, the parasitic capacitance Cp, caused by the integrated circuit 20 itself, can be overcompensated inside the integrated circuit 20. As such, for proper tracking, a capacitor Cp, needs to be externally connected to the integrated circuit. Advantageously, the LC band-pass filter 10 can always be designed for minimum unwanted parallel capacitance and consequently maximum frequency range. Further, the fixed-frequency control loop 30 may use the X-tal oscillator frequency ωxtal in the loop. This minimizes the risk of interference, since no new frequencies are introduced.
The foregoing description of various aspects of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously, many modifications and variations are possible. Such modifications and variations that may be apparent to a person skilled in the art are intended to be included within the scope of the invention as defined by the accompanying claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB03/05503 | 11/27/2003 | WO | 6/13/2005 |
Number | Date | Country | |
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60433366 | Dec 2002 | US |