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Receiver for receiving multiple frequencies transmitted simultaneously by a phase comparison navigational system
Receiver for receiving multiple frequencies transmitted simultaneously by a phase comparison navigational system
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机译:接收器,用于接收由相位比较导航系统同时发送的多个频率
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摘要
983,014. Radio navigation. DECCA Ltd. July 10, 1963 [July 17, 1962], No. 27479/62. Heading H4D. A receiver for a phase comparison navigation system, of the kind in which for lane identification purposes, signals of three or more different but harmonically related frequencies are radiated in fixed phase relationship simultaneously from one station and subsequently from another station such that the simultaneous radiations from each station in combination gives a pulse output signal at a frequency lower than that of any of the radiated signals, comprises means for receiving all the radiated frequencies, adding means for additively combining the received signals, adjustable phase shifting means for adjusting the relative phases of at least all but one of the various received signals fed to the adding means, an oscillator phase locked to a received signal or signals from one station to provide an output of said lower frequency locked in phase to one or more of the received signals, phase measuring means for determining the phase relationship between the output of said oscillator and the output of said adding means, and means for applying a reference signal having components of all said frequencies in fixed phase relationship to said receiving means in place of the received radiated signals. The invention is described as an improvement on the navigation system described in Specification 765,573, which is a system of the above defined kind, in that greater use is made of the received signals and greater reliability may be put on the lane identification signals in the presence of large sky wave distortion. In the arrangement of Fig. 3, the normal 6#, 5#, 9# and 8# signals are received from the master station, the purple, green and red slave stations respectively by aerial 10, and are passed via switch 11 to respective tuned amplifiers 12, 13, 14 and 15. The outputs of each of the amplifiers are frequency multiplied in the normal way such that three fine phase comparison measurements may be made, and the results shown as three line positions within a lane on indicators 19, 23 and 27. During the normal transmission period the 6# signal from the master station is fed via switch 30 and amplifier 31 to one input of a phase discriminator 32. The other input of the phase discriminator is fed via amplifier 34 with the output of an oscillator 33 operating at a frequency of 6# and controlled in frequency by means of the output of the discriminator 32 via switch 37 and control 38, the arrangement being such that the oscillator 33 is kept in synchronism with the master signal, even when the lane identification signals are being transmitted. The normal transmission from the stations are periodically terminated and after a brief pause the lane identification signals are transmitted. The phase discriminator 32 gives outputs proportional to the sine and cosine of the phase difference angle between the two input signals. They should normally be zero and a maximum respectively. At the termination of the normal transmission toward the cosine signal decreases and this is detected by a break detector 55. This in turn activates a switch relay 56 which closes switches 58 to 62, opens switch 37 and changes over switch 30. Other means of actuating switch 30 may be used, the frequency of one of the station transmissions may be altered slightly in frequency or the phase thereof may be reversed. The lane identification signals which are transmitted by each station in turn, comprise a simultaneous transmission of four phase locked signals at frequencies 6#, 5f, 9# and 8#. These are received by aerial 10 and the respective tuned amplifiers and are fed via variable phase shifters 46, 47 and 48 to a common junction at the input of pulse former 45. When the four signals are in their correct phase relationship, as will be explained later, the pulse former produces a train of phase locked pulses at a repetition rate of 1#. This train is converted to sinusoidal signals at frequencies of 1# and 6# respectively by multipliers 50 and 49. The 1# signal is applied, via amplifier 44 to one input of phase discriminator 43. The other input of the discriminator is fed with a 1# signal obtained by dividing down the output of oscillator 33 by means of a divider 41. The sine and cosine outputs of the discriminator are fed via switches 59 and 60 to an indicator assembly. The indicator assembly comprises an indicator 74 having two orthogonal stator coils and magnet rotor fastened to a section pointer 77, covering an angle of 60 degrees, and two capacitor stores 72 and 73 which store the outputs of the discriminator for the following normal transmission period. Since divider 41 is unnotched the pointer 77 can occupy any one of six angular positions. The discriminator 32 produces sine and cosine outputs indicative of the phase difference between the signal from oscillator 33 and that from multiplier 49. These outputs are fed to a further indicator assembly via switches 61 and 62. The pointer 85 of indicator 82 is driven through a six to one reduction gear and is formed with six arms. The pointers 77 and 85 are concentrically mounted on the same rotatable scale 78, the pointer 77 indicating which of the six arms of pointer 85 should be used for the lane identification. When the lane identification signals are being transmitted by the master station the scale 78 is rotated until the particular arm of pointer 85 reads zero. Subsequent lane identification transmissions by the slaves then give readings on scale 78 indicating the required lane. To ensure that the signals fed to the pulse former 45 are in the necessary phase relationship, a reference generator 70 is provided to transmit pulses of 1# repetition rate via changed over switch 11, to the four tuned amplifiers 12 to 15 where the corresponding harmonics in the pulse signal are selected and amplified. They are then passed via phase shifters 48, 47 and 46 to the pulse former 45 which has a second output, feeding the combined resultant of the four signals to a peak value indicator 66 via switch 58. The phase shifters are varied in turn until a maximum value is obtained for the amplitude of the resulting pulses. Divider 41 may alternatively be notched by the 1# pulse signals from former 45 arising from the master lane identification transmissions. Reduction of the reading of indicator 66 during operation indicates that skywave reflection interference is large and less reliability should be put on the phase comparisons on indicators 19, 23 and 27.
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