Pulse or digital communications – Receivers – Angle modulation
Reexamination Certificate
2000-03-30
2004-08-03
Chin, Stephen (Department: 2734)
Pulse or digital communications
Receivers
Angle modulation
C375S373000, C375S376000
Reexamination Certificate
active
06771715
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates in general to communication systems, and is particularly directed to a digital data demodulator architecture, that employs a cordic rotator-based, digital phase locked loop for carrier frequency acquisition and tracking.
BACKGROUND OF THE INVENTION
The radio frequency (RF) and intermediate frequency (IF) stages of conventional radio subsystems (including those which employ digital signal processing components), such as but not limited to modulator and demodulator stages, typically employ both fixed frequency and voltage controlled crystal oscillators as part of their frequency conversion stages (mixers) and phase locked loop circuits. A conventional phase locked loop for a demodulation stage of a conventional “digital” radio for demodulating a spread spectrum-modulated QPSK signal, as a non-limiting example, is diagrammatically illustrated in
FIG. 1
as having an input port
10
, to which an incoming signal to be demodulated is applied. Input port
10
is coupled to respective in-phase (I) and quadrature phase (Q) channel mixers
11
and
13
, which multiply the incoming signal by relative phase quadrature reference frequency signals generated by a voltage controlled local oscillator (VCO)
15
and an associated 90° phase shifter
17
, so as to produce down-converted (baseband) I and Q channel signals.
The down-converted (baseband) I and Q channel signals output by mixers
11
,
13
are digitized by an analog-to-digital converter
21
and then despread by a correlator
23
. The respective despread baseband I′ and Q′ channels output by the correlator
23
are coupled over respective multibit links
31
and
32
to digitally implemented phase error detection logic circuitry
33
, which outputs a digital vector (code) representative of the (carrier frequency offset associated) phase error in the downconverted signals. This phase error code is coupled through a digital loop filter
35
to a digital-to-analog converter (DAC)
37
, which converts the phase error code into an analog voltage for adjusting the output frequency of the VCO
15
.
Because oscillator circuits of the type used in the carrier tracking stage of
FIG. 1
employ analog components (VCO
15
), they suffer from a number of deficiencies. For example, their output frequencies will vary with environmental conditions, such as time (aging) and temperature, as well as with other less influential factors. In addition, component-to-component manufacturing tolerances of these parts are satisfactory only within a prescribed range—usually specified in the hundreds of parts per million (ppm). Further, compared to other components in the radio, oscillators are relatively expensive and prone to mechanical failure.
Due to the inherent inaccuracies in oscillator components of a radio receiver prevent data from being perfectly demodulated and delivered to downstream baseband processing circuitry with precise replication, compensation circuitry must be incorporated into the radio's timing recovery and data demodulation signal processing stages. These circuits traditionally utilize additional voltage controlled oscillator components, which are tuned to frequencies such that the inaccuracies of the crystal and voltage controlled oscillator components used in each of the transmitter and receiver portions of the radio can be effectively eliminated on a long term averaged basis. Unfortunately, employing a voltage controlled oscillator in the compensation circuit introduces yet another level of inaccuracy, and adds to the cost of the overall radio design.
SUMMARY OF THE INVENTION
In accordance with the present invention, the above described shortcomings of conventional analog voltage controlled oscillator-based radio systems are effectively obviated by a new and improved digital-based data demodulator architecture, that employs a cordic rotator-based digital phase locked loop for carrier frequency tracking, and thereby removes the voltage controlled oscillator and its associated problems from the phase locked loop. In a demodulator application, a received signal, such as a spread spectrum-modulated BPSK signal, is multiplied in respective in-phase (I) and quadrature phase (Q) channel mixers by relative phase quadrature reference frequency signals produced by a fixed frequency (e.g., crystal) oscillator and an associated 90° phase shifter to produce down-converted (baseband) I and Q channels.
The I and Q channels are digitized and then despread by a correlator. The respective despread baseband I and Q channels are coupled to respective inputs of a digital cordic rotator, which executes iterative phase-rotational adjustments of its digitized in-phase and quadrature inputs, in accordance with a phase angle vector code generated by digital phase error detection logic circuitry to which the rotated I and Q outputs of the cordic rotator are applied. The phase error representative code vector is coupled through a digital loop filter as a reference angle input to the cordic rotator. The cordic rotator iteratively rotates the I and Q channel values over a prescribed number of processing cycles.
Pursuant to a preferred embodiment, the cordic rotator includes a quadrant adjustment section upstream of respective I and Q channel rotation iteration loops, and a phase angle quadrant adjustment section upstream of a phase angle iteration loop. Each iteration through the pipeline signal processing paths for the respective I channel and Q channel rotation iteration loops and a phase angle iteration loop comprises four quarter cycles. The quadrant adjustment section is used at initialization to perform a quadrant adjustment of the I and Q input values, based upon the sign of the angle of rotation &thgr; supplied from the digital loop filter. In association with initialization of the I and Q channels, a phase angle quadrant adjustment section performs an offset correction of the vector code value of the angle of rotation &thgr;, in accordance with whether the phase angle code vector falls within a prescribed window.
During the first subportion (quarter cycle) of a respective iteration, quadrant-adjusted IP and QP values are latched into associated I and Q registers, an incremental angle control code associated with the arctan of an iteration-defined power of one-half is generated, and the current value of iterated phase angle value is latched in an updated phase angle or &bgr; register. During a second quarter cycle, the respective values of the I and Q vectors are divided by two, by associated right-shift logic circuits and the results are multiplied by the most significant bit of the phase angle code &bgr; to produce delta I and Q codes. Also a delta phase angle value based upon the incremental angle code is stored.
During the third quarter cycle, an updated phase angle value corresponding to the sum of the delta phase angle value and the updated phase angle &bgr; is generated and latched. Also the delta I and Q codes produced during the second quarter cycle are summed with the previous I and Q values to produce updated I and Q codes, respectively. In the fourth cycle, the updated I and Q codes are latched, thus completing one iteration.
This process is repeated for K iterations (with the exception of the initialization operations carried out by the quadrant adjustment section for the I and Q loops and the phase angle quadrant adjustment section for the phase angle loop). In the fourth quarter cycle of the Kth iteration, the adjusted values of the I and Q channel codes are latched into output registers to provide respective ‘cordic-rotated’ I and Q channel output values.
REFERENCES:
patent: 6151368 (2000-11-01), Cochran
Gann Matthew F.
Goodloe Anthony A.
Rives Eric M.
Adtran Inc.
Allen Dyer Doppelt Milbrath & Gilchrist, P.A.
Chin Stephen
Odom Curtis
LandOfFree
Demodulator using cordic rotator-based digital phase locked... does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Demodulator using cordic rotator-based digital phase locked..., we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Demodulator using cordic rotator-based digital phase locked... will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3324668