DE2402696A1 - Oscillatory signal generator - using phase locked loop techniques uses reference generator and comparator - Google Patents

Abstract

A signal generator may be formed so that the output signal is exactly equivalent to a reference frequency, or a multiple of it. Thus the technique may be used to a frequency synthesiser a signal, using a signal of much lower frequency as a reference. A reference oscillator is established and its output is connected to the input of a comparator. The output of the comparator is used to control the frequency of an oscillator, which provides the required output and is also fed to the other input of the comparator, after it has been divided by an appropriate number 'N'. Thus if the output frequency from the oscillator is 'NF', and the reference frequency is 'F', the output from the comparator will be at equilibrium, and no charge shall be required at the oscillator.

Description

Electronic alternating voltage generator The present invention relates to an electronic alternating voltage generator, in particular a frequency synthesizer, with a voltage controlled oscillator for generating an output signal with one of several predetermined frequencies, a reference frequency source and a Phase diffuser, which gives an error signal depending on the phase relationship between a signal obtained from the output signal of the voltage controlled oscillator and a signal obtained from the reference signal source to a control part of the voltage-controlled one Oscillator supplies.

Electronic alternating voltage generators working on the principle of frequency synthesis, especially so-called digital frequency synthesizers, are used in many electronic Facilities needed. A frequency synthesizer, for example, is very often used as a local Oscillator used in a communications device. In such applications, the Parameters of the alternating voltage generator, such as the spectral purity (freedom from harmonics) and frequency stability can be kept within specified tolerances to ensure that the associated device works properly. A high spectral For example, purity is essential to avoid co-channel interference and Intermodulation distortion to avoid. Furthermore, if the random frequency modulation exceeds a certain amount, there is a risk that perfect demodulation is no longer possible, especially- at high data input rates.

There are many causes for devices of the type mentioned above a random, unwanted frequency modulation which leads to difficulties regarding of spectral purity and short-term stability. These causes can electrical or mechanical in nature. For example, with certain institutions the mechanical vibrations caused by a fan motor are minor Movements of the frequency-determining components of the controlled oscillator of the Device have the consequence that result in an interference frequency modulation, which makes noticeable in the output of the frequency synthesizer. An interference frequency modulation can also arise from the fact that a remaining AC voltage component of the supply voltage is coupled into the phase synchronization loop of the frequency synthesizer.

The main problem is that it is distracting or accidental Frequency modulation largely outside the bandwidth of the control loop of the AC voltage generator or frequency synthesizer plays and therefore through the regulation itself is not covered. The occurrence of interference frequency modulation outside the bandwidth of the control loop also tends to reduce the short-term stability the facility, as the short-term stability is a measure of the sideband interference is in a predetermined frequency band offset from the carrier frequency.

Attempts have already been made in various ways to solve this interference frequency problem in precision AC voltage generators or frequency synthesizers will. A well-known measure is the synthesizer shield both electrically and mechanically from the environment. This is done Usually the voltage controlled oscillator (VCO) is encapsulated to the influences from vibration, and also, all utility lines become strong blocked in order to avoid the coupling of external signals if possible. This allows certain successes to be achieved, the voltage-controlled oscillator however, it is still very sensitive and in practice it is extremely difficult to if not impossible, such an oscillator completely against external mechanical and shield electrical interference.

The present invention is therefore based on the object of the above described difficulties with regard to spectral purity and stability to fix.

This task is performed by an alternating voltage generator of the frequency synthesizer of the type mentioned above, the one on the output signal of the voltage-controlled Oscillator contains responsive arrangement that returns a variable signal to the control part of the voltage controlled oscillator that supplies the undesired Compensated for frequency components in the output signal of the voltage controlled oscillator and very much reduced.

The measure indicated by the invention is simple, expedient and covers a fairly large part of the frequencies of interest. The correction the output signal of the voltage-controlled oscillator takes place in a frequency band, which has a much larger bandwidth than the phase locked loop.

In the following, an embodiment of the invention is referred to explained in more detail on the drawing; show it: Fig. 1 is a graph Representation of phase disturbances, on the basis of which the underlying of the invention Problem will be explained; 2 shows a block diagram of an exemplary embodiment the invention.

Single sideband phase disturbances are shown graphically in FIG. as in a typical electronic that works with frequency synthesis AC voltage generator with random or disruptive frequency modulation be correlated at different frequency spacings from the carrier frequency xC can. The dashed vertical line 10 represents the frequency spacing from the carrier frequency xC, up to which compensation by the phase locked loop of the generator is possible. The random disturbances, which are shown as peaks 12, 14, 16 and 18 are outside the bandwidth of the phase locked loop. This at 12.14, 16 and 18 illustrated disturbances and disturbances of a similar nature are intended by the invention be compensated and eliminated.

The circuit arrangement shown in Fig. 2 contains a voltage-controlled Oscillator 20, with which each one of several predetermined frequencies is generated can be. The oscillator 20 provides the output signal of the desired frequency via a line 22 to a device, not shown, in which this signal is needed. The output signal of the oscillator 20 is also on one line 24 available, which is connected to a first frequency divider 26 with the division ratio K works. The frequency divider 26 can be viewed as a prescaler will. Not all frequency synthesizers making use of the invention need to contain such a prescaler, however, it is here only for the sake of completeness mentioned for the sake of it. The signal processed by the frequency divider 26 is transmitted via a line 28 one second frequency divider 30 supplied with the division ratio N is working. The frequency divider 30 can in typical cases be programmable or adjustable be. The division ratio N is then adjustable to the output frequency of the voltage controlled oscillator to change. The output signal of the voltage controlled Oscillator 20 is thus divided by the numbers K and N and that by the division The signal obtained is then fed to a phase comparator 32 via a line 34.

The circuit arrangement according to FIG. 2 also contains a reference oscillator 36, which is usually of a stable, crystal-controlled type. The output signal of the reference oscillator 36 is via a line 40 of another Frequency divider circuit N supplied. The frequency divider circuit divides the frequency of the output signal of the reference oscillator 36 by the number R. The divided signal is from the frequency divider circuit 38 via a line 42 to the phase comparator 32 supplied.

The phase comparator 32 compares the phases of the lines 34 and 42 supplied signals and generates an error on a line 44 - or Control signal in the form of a direct voltage. The line 44 is connected to one input terminal a summing amplifier 46 is connected. The output of the summing amplifier 46 becomes a control part of the voltage-controlled oscillator via a line 48 20 supplied.

The circuit arrangement described so far with the voltage-controlled Oscillator and a phase locked loop is in conjunction with frequency synthesizers well known. It should be noted at this point that any phase deviations in the oscillator output signal on line 24 at the phase comparator by the factor 1 / KN. The gain bandwidth is therefore inversely proportional to KN and this reduced phase change at the input of the phase comparator cannot generate enough error correction voltage for disturbances that cause a significant Have a frequency spacing from the carrier frequency xC.

In addition to the phase locked loop just described, the circuit arrangement in accordance with FIG. 2, a second frequency control loop is also provided. The output signal of the oscillator 20 on the line 24 is via a line 52 of an additional Divider circuit 50 supplied, which has the division ratio M. That at the exit of the Divider circuit 50 occurring signal is via a line 56 to a frequency discriminator 54 supplied. The output signal of the frequency discriminator 54 is via a line 58 is fed to a second input terminal of the summing amplifier 46. With some Applications, it may be expedient to have the divider circuit 50 programmable or to make adjustable in order to change the absolute value of M. The divider circuit 50 is provided to convert the output signals of the oscillator 20 into a for processing by the frequency discriminator 54 to convert a suitable frequency band. The division ratio M is typically much smaller than the division ratios of KxN.

The frequency discriminator 54 detects the interference discussed above or random frequency modulation and results in the perceived signals as well a phase shift of 180 °. For the signals appearing on line 58 it is therefore a question of variable signals, while those appearing on line 44 Signals are generally DC correction signals. In some cases it can the correction signal on line 44 will also change over time. Such in time However, variable correction signals are then always limited to the bandwidth of the phase-locked loop limited. So you can use the control part of the voltage controlled oscillator 20th view the supplied signals as control or regulating DC voltage, which is a control or control AC voltage signal is superimposed.

The frequency synthesizer according to FIG. 2 thus practically contains two Control loops. Both loops essentially have a negative feedback effect the end. One loop is the known phase-locked loop, which is a DC voltage control signal or within the limits given by the bandwidth of the control loop modifying correction signal supplies, while the other loop a sinusoidal signal negative feedback loop which has a much larger bandwidth than the first-mentioned loop. the The function of the second loop can easily be seen as follows: Interference, such as interference frequency modulation in the output signal of the voltage-controlled Oscillator 20 can be viewed as if it were driven by a sinusoidal signal at the input of the control part of the oscillator 20 would have been caused. One can accordingly generate a suitable sinusoidal signal of opposite phase and this in phase opposition Signal to the input of the control part of the oscillator 20 for compensation or suppression of the perceived disturbances.

The circuit arrangement shown in Figure 2 is therefore a convenient one and economic measure to improve spectral purity and stability a frequency synthesizer or alternating voltage generator.

A closer examination of the frequency synthesizer according to FIG 2 shows that the falling of the phase-locked loop may be caused by the additional control loop can be delayed. You can therefore, if necessary, in the second control loop provide a switch, and this second control loop only switch on after phase synchronization has been carried out. Also, it can be desirable or may be required the gain factor in the second control loop to improve the work of the frequency discriminator.

Claims (8)

P a t e n t a n s p r ü c h e 1y) Electronic alternating voltage generator, especially for frequency synthesizer, with a voltage controlled oscillator for generating an output signal with one of several predetermined frequencies, furthermore with a reference frequency source and with a phase comparator which generates an error signal as a function of the phase relationship between one obtained from the output signal of the voltage controlled oscillator Signal and a signal obtained from the reference signal source to a control part of the voltage-controlled oscillator delivers, g e k e n n n z e i c h n e t d u r c h an arrangement (50,54), which is based on the output signal of the voltage-controlled Oscillator (20) responds and to the control part of this oscillator a changing Signal to compensate and significantly reduce interference frequency components (e.g. 12,14, 16,18) in the output signal of the voltage controlled oscillator. 2.) Device according to claim 1, d a d u r c h g e k e n n -z ei c h n e t that the on the output signal of the voltage controlled oscillator (20) attractive arrangement a device (50,54) for the perception of in one predetermined frequency band lying frequencies of the output signal and for shifting the phase of the signal components perceived in the given frequency band contains around 1800. 3.) Device according to claim 2, d a d u r c h ge k e n n -z e i c h n e t that the perceiving the frequencies in the given frequency band and the phase shifting device includes a frequency discriminator (54). 4.) Frequency synthesizer with a voltage controlled oscillator to generate an output signal with one of many given Frequencies as a function of control signals sent to a control part of the oscillator are fed, further with a frequency divider arrangement, which the output signal of the oscillator and which supplies a first signal whose frequency is in a predetermined relationship with respect to the output signal of the oscillator, furthermore with a device for generating a second predetermined signal Frequency and with a phase comparator that is determined by the first and second signals is controlled and a first control signal to the control part of the controlled oscillator provides that of the phase relationship between the first and second signals depends, not shown by an interference frequency correction loop (52,50,56,54,58), which responds to the output signal of the controllable oscillator (20) and a second Provides correction signal (on line 58) to the control section of the oscillator (20), which the size of interference signal components (12,14,16,18 in Figure 1) in the output signal of the oscillator seeks to reduce considerably. 5.) Device according to claim 4, d a d u r c h g e k e n n -z e i c h n e t that the frequency correction loop has a device (50,54) for perception of signal components in a given frequency band and to reverse the phase of these Contains components. 6.) Device according to claim 5, d a d u r c h g e k e n n -z e i c h n e t that the device for sensing and phase shifting a frequency discriminator (54) contains. 7.) Device according to claim 6, d a d u r c h g e k e n n -z e i c h n e t that the frequency correction loop also has a loop frequency divider circuit (50) to which the output signal of the oscillator (20) is fed, and the to the frequency discriminator (54) supplies a signal whose frequency has a predetermined relationship to the frequency of the output signal. 8.) Device according to claim 7, d a d u r c h ge k e n n -z e i c Note that the interference frequency correction loop contains an amplifier circuit (46). Blank page