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* ;Priority Date(s): .-3.1.,/P.rS] ;Complete Specification Filed: ;Clasa: HQdM/OClyJUL... ;Pubiioation Date! ... ~l?. ,^P. 198$ ;P.O. Journal, No: . ml ;N. Z. NO. ;NEW ZEALAND ;Patents Act 1953 ;COMPLETE SPECIFICATION ;"SYNCHRONOUS ENVELOPE DETECTOR." ;f"r9 JUL 1982 ;I, LEONARD RICHARD KAHN, a citizen of the United States of America of 137 East 36 Street, New York, New-York 10016. United States of America do hereby declare the invention, for which I pray that a Patent may be granted to me , and the method by which it is to be performed, to be particularly described in and by the following statement:- ;- 1 - ;'Followed by lA.) ;lUUIU.U^- SYNCHRONOUS ENVELOPE DETECTOR ;EjU> ;BACKGROUND OF THE INVENTION ;I ;2 This invention relates to the reception of ;3 amplitude modulated radio freauency carrier waves and, ;4 more particularly, to envelope detectors for such ;5 carrier waves. ;6 In a typical receiver for monaural amplitude ;7 modulated (AM) radio freauency signals, the first ;8 stage is a superheterodyne circuit that converts the ;9 radio frequency signal to an intermediate freauency ;10 (I.F.) signal. The envelope of this signal, which ;11 represents the amplitude modulation, is then detected, ;12 i.e. a signal equivalent to the amplitude modulation ;13 is created from the I.F. signal. This envelope 1A detection may be accomplished by the series ;15 combination of a diode, which half-wave rectifies the ;16 signal, and a low pass filter. Alternatively, ;17 envelope detection can be achieved by an in-phase ;18 product demodulator wherein the I.F. signal is ;19 multiplied by a signal at the freauency of, and in ;20 phase with, the carrier. Higher order harmonics and ;21 high frequency noise are then filtered out by use of a ;22 low pass filter. ;-1 ;1 ;2 ;3 ;4 ;5 ;6 ;7 ;8 ;9 ;10 ;11 ;12 ;13 ;14 ;15 ;16 ;17 ;18 ;19 ;20 ;21 ;201230 ;One proposed system of AM stereo broadcasting amplitude modulates the carrier with a signal representing the sum of the left and right stereo audio signals (L+R) and phase modulates it with a signal representing difference (L-R). A receiver for such a broadcast signal is disclosed in the inventor's ;4sor? ,1*4 <br><br>
prior U. S. Patent No. 4>108l994. One embodiment of this receiver utilizes an in-phase product demodulator as an envelope detector to recover the L+R signal. <br><br>
Whether in a monaural or a stereo receiver, an envelope detector of the diode or in-phase product demodulator type is subject to fading and reduced selectivity problems. In particular, a diode detector cannot differentiate between the desired carrier and a stronger interfering carrier that falls in the I.F. passband. An in-phase product demodulator is subject to problems resulting from incidental phase modulation, which is a common occurrence with AM transmitters. <br><br>
It is, therefore, an object of the present invention to improve the selectivity and resistance to fading of AM receivers by providing an envelope detector which utilizes both in-phase and quadrature product demodulation. <br><br>
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SUMMARY OF THE INVENTION <br><br>
In an illustrative embodiment of the invention a received AM signal that has been translated into the I.F. band is applied to two product demodulators. The carrier of the I.F. signal is isolated, e.g. by a phase-locked loop, and a corresponding quadrature carrier, i.e. the isolated carrier phase-shifted by 90 degrees, is generated. The carrier is applied to one of the demodulators and the quadrature carrier is applied to the other. The outputs of the demodulators are separately squared and then added together. The square root of the resulting signal is taken in order to produce the final envelope-representative signal. By using product demodulators, i.e. synchronous detection, the rejection of strong interfering carriers is possible. Also, the use of both the in-phase and quadrature detected signal makes the envelope detection process insensitive to transmitter incidental phase modulation. <br><br>
For a better understanding of the present invention, together with other and further objects, reference is made to the following description, taken in conjunction with the accompanying drawing, and its scope will be pointed out in the appended claims. <br><br>
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BRIEF DESCRIPTION OF THE DRAWING <br><br>
Fig. 1 of the drawing shows a block diagram of a synchronous envelope detector according to the present invention. <br><br>
DESCRIPTION OF THE INVENTION <br><br>
In a stereo system such as that disclosed in <br><br>
U. S. Patent No. 4,018,994, pertinent portions of which are incorporated herein by reference, the broadcast signal has an amplitude modulation component representative of the L+R stereo information and a phase modulation component representative of the L-R <br><br>
stereo information. If the in-phase signal component is represented by a vertical vector, the quadrature phase component will be represented by a horizontal vector. Thus the envelope modulation of the broadcast signal may be represented by a vector varying in angle between 0 and 90 degrees and having an amplitude that is equivalent to the square root of the sum of the squares of the in-phase component (I) and the <br><br>
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quadrature component (Q), i.e. I + Q . The circuit of Fig. 1 accomplishes envelope detection by generating the in-phase component (I) in product demodulator 104 and the quadrature-phase component (Q) in product demodulator 108. In order produce the I.F. <br><br>
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signal needed for product demodulators 104 and 108, a composite amplitude and phase modulated R.F. signal is received by an antenna and processed by a conventional superheterodyne circuit (not shown) wherein the a corresponding I.F. signal is generated. This I.F. signal is not only applied to the product demodulators 104 and 108, but is also applied to a carrier isolation circuit 102. As stated in the above-cited patent, carrier isolation can be accomplished by means of a phase-locked loop arrangement. The isolated carrier is then applied to a phase shift circuit 106 wherein in-phase and quadrature-phase carrier signals are derived. Such signals, however, are already present in an AM stereo receiver such as that shown in the Patent 4,018,994. <br><br>
The output of product demodulator 104 is applied to low pass filter (LPF) 110 while the output of demodulator 108 is applied to low pass filter 112. It is necessary that the product demodulator 104 and low pass filter 110 pass the DC component which results from multiplying the I.F. signal by the carrier. It is also desirable for the DC component to be maintained in the quadrature path through product demodulator 108 and filter 112. However, there are some situations where this may be unnecessary. <br><br>
Filters 110 and 112 can provide improved selectivity, assuming the product demodulators 104 and 108 have <br><br>
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low distortion characteristics. For example, an active filter having five poles can be inexpensively constructed. Such a filter will provide 45db attenuation at IOKH2 and ldb attenuation at 5KHz. At 5.4KHz the signal would be down 6.6db. Although not always necessary, it is advantageous to include some selectivity in the I.F. circuitry in order to avoid overload of the product demodulators. The selectivity achieved by low pass filters 110 and 112 is symmetrical, which is an advantage in most AM reception situations, but the main advantage is that it allows the use of the two active low pass audio filters, which can be constructed using integrated circuit techniques, in place of a more difficult to make I.F. filter. <br><br>
From filters 110 and 112 the signals are coupled to squaring circuits 114 and 116, <br><br>
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respectively, in order to generate the I and Q signals. These signals are then combined in summing circuit 118 and the sum signal is coupled to a square root circuit 120 which produces the desired envelope detected output signal. <br><br>
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