DE3232519A1 - SIGNAL GENERATOR - Google Patents

Description

description

The present invention relates to a programmable signal generator, the oscillator frequency by a digital Control signal is controlled.

The use of programmable signal generators is growing, since such generators can be controlled directly, for example by computers, in order to generate a large number of signal shapes with different frequencies or repetition frequencies. In one type of programmable signal generator, a digital control signal is fed into a digital-to-analog converter which in turn supplies a control voltage for a voltage-controlled oscillator so that an output signal is generated at a frequency determined by the digital control signal. The digital control signal can be several bits wide in order to generate a highly accurate output signal frequency. However, the actual frequency can change due to gain ^and offset errors in the digital-to-analog converter and the voltage controlled oscillator. In addition, the output frequency can be quite unstable and drift due to temperature changes or other physical influences. Although the digital control signal is very stable and can be resolved to a high degree, the output frequency of the signal generator can still change by 5% or more.

The present invention is therefore based on the object of providing a signal generator with a more precise output signal frequency to be specified by self-adjustment to an exact and stable output frequency value.

In the case of a programmable signal generator of the type mentioned at the outset, this object is achieved according to the invention by the features of the characterizing part of claim 1 solved. ^

The programmable signal generator according to the invention has a feedback control system that controls the output frequency monitors and adjusts the digital control signal to a value which exactly gives the desired frequency. According to a particular embodiment of the invention the digital control signal is fed into a voltage-controlled oscillator via a digital-to-analog converter. The duration for at least one period of the output signal is measured by a period measuring stage, whose , Q output signal for adjusting the digital control signal serves to a suitable value.

Further refinements of the inventive concept are characterized in the subclaims.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the figures of the drawing explained. It shows:

Fig. 1 is a block diagram of a programmable signal generator with a feedback control system according to the invention;

2 shows a detailed block diagram of a voltage-controlled oscillator for use in the invention Signal generator; and

3 shows a detailed block diagram of a period measuring stage for use in the signal generator according to the invention.

1, a processor 10 provides a frequency control signal in the form of parallel digital data for a digital-to-analog converter 12 for conversion into an analog control voltage. The processor 10 can, for example, be a microprocessor system with a random access memory

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for intermediate storage and a read-only memory for storing program instructions. The digital Control data for setting the signal generator frequency can be sent via a (not keyboard shown). If the desired frequency is first entered via the keyboard, so the processor 10 calculates the appropriate value of the frequency control signal for the digital-to-analog converter 12 and thus its output control voltage, which is fed into a voltage-controlled oscillator 14. This The voltage-controlled oscillator 14 generates, as a function of the control voltage, an output signal whose frequency is the same or approximately the same (for example in a range of 5%) as the desired, predetermined by the digital control data programmed frequency. The output signal is available at an output 16 and is converted into a Period measuring stage 18 fed. The processor 10 then initiates the period measurement of a period of the output signal in the period measuring stage 18. This is generally done by counting fast pulses from a reference oscillator for the duration of one period of the output signal. The reference oscillator 20 can expediently be a crystal oscillator be that of a stable reference frequency signal with a significantly higher frequency than the frequency of the output signal from the voltage-controlled oscillator, so that precise period measurements can be carried out.

The resulting period information is fed into processor 10 which reads the data and the percentage the frequency error of the output signal of the voltage controlled Oscillator calculated with respect to the programmed value. The processor 10 then modifies the parallel ones Digital data for the digital-to-analog converter 12 by the inverse value of the frequency error, so that the output frequency is corrected to the desired value. This sequence is repeated until the output frequency of the voltage controlled oscillator 14 in a predetermined

Error band is around the programmed frequency. It should be noted that the above-mentioned operation is supported by the Program in processor 10 is controlled. In addition, the processor 10 and the period measuring stage 18 can Routinely monitor the output frequency on a periodic basis for long-term output frequency stability to ensure.

As follows from the above, the programmable signal generator according to the invention brings the output frequency within the limits of the digital-to-analog converter and the resolution of the period measurement as well as the Accuracy and the frequency of the reference oscillator signal as close as possible to the desired value. at Frequency accuracy became a practical embodiment corrected from an uncorrected value of 5% to a value of 0.1%.

The details of one embodiment of a voltage controlled Oscillators 14 are shown in FIG. A voltage source 22 and a current sink 2 4 are on an electronic switch circuit 26 is coupled, which has an output 28 as a function of the output pulse from a level detector 30 is coupled either to the current source 22 or the current sink 24. The current levels of circuits 22 and 24 change as a function of the analog control voltage coming from the digital-to-analog converter 12. A capacitor 32 lies between the output 28 and the switching circuit 26. A buffer amplifier 34 feeds the voltage at Capacitor 32 in level detector 30. The buffer amplifier 34 is expediently a source follower operated field effect transistor, so that the capacitor 32 sees a high impedance, through which a current decoupling for the output signal branch. The level detector 30 detects predetermined upper and lower levels of the output voltage of the buffer amplifier 34 in order to

gen impulse, which in the output 16 and in the electronic switch circuit 26 is fed. When the output 28 of the electronic switch 26 to the Current source 22 is coupled, current flows into the capacitor 32, whereby a sawtooth voltage is also applied to it positive slope is generated. When the sawtooth voltage reaches the predetermined upper level of the level detector 30, so its output signal is switched, whereby the new voltage level in the electronic switch 28

IQ is fed in, so that the output 28 is coupled to the current sink 24. In this state, current flows from the capacitor 32 into the current sink 24, as a result of which a sawtooth voltage with a negative slope is generated on the capacitor. If this sawtooth voltage decreases with a negative slope to a predetermined lower level, the level detector 30 switches again, whereby the new voltage level is fed into the electronic switch 28 in order to couple the output 28 to the current source 22, so that the process is repeated. According to this repeated process, a triangular voltage is generated across the capacitor 32, the level detector 30 generating a square pulse, the edges of which occur when the triangular voltage reaches the predetermined level set by the level detector 30. The output control voltage from the digital-to-analog converter 12 controls the values of the current source 22 and the current sink 24 and thus the slope of the triangular voltage on the capacitor 32, so that the output signal of the digital-to-analog converter 12 in effect the frequency of the square-wave pulse from the level detector 30 controls.

3 shows a detailed block diagram of an embodiment the period measuring stage 18. One can be set by a Programmable loop counter 36 formed by counters counts a predetermined number of output periods of the signal from the voltage controlled oscillator 14

to over multiple periods instead of just one period generate a time interval signal. The predetermined number is determined by the processor 10 as a function of the over the desired output frequency entered on the keypad. The specified number for the programmable Loop counter 36 changes proportionally with the desired output frequency so as to obtain the time interval signal the more periods are counted, the higher the desired frequency. By counting several periods for the generation of the time interval signal, the requirements for the accuracy of the frequency of the reference oscillator 20 be a little lower. The time interval signal from counter 36 is input to an AND gate 38 fed, which when activated by the time interval signal, a reference signal from the reference oscillator 20 to a reference counter 40 lets through. The counter 40 therefore counts one during the interval of the time interval signal Number of reference frequency periods from the reference oscillator 20, the resulting information from the counter 40 in the processor 10 is fed.

The signal generator according to the invention has advantages over an analog phase-locked loop in that not only long-term stability but also close to frequency accuracy when operated in an open control loop A closed control loop lying accuracy is achieved, since the processor 10 on a digital correction factor "remembers".

Modifications of the above are within the scope of the invention described embodiments possible. For example the voltage-controlled oscillator 14 contain a capacitance diode whose capacitance is determined by the analog control voltage is controlled by the digital-to-analog converter 12 to determine the output frequency. Furthermore can also other types of frequency counters can be used in the period measuring stage.

Claims (3)

Patent attorneys Dipl.-Ing. H. ^ / eick ^ ann,! DxpL-Thys. Ditf ο ο 3 9 c _} 1 Q Dipl.-Ing. FAWeickmann / 'Dtpl.-Chem. B. Huber Dr.-Ing. H. Liska 8000 MUNICH 86 < POST BOX 860 820 ' MOHLSTRASSE 22 TELEFON (0 89) 98 03 52 TELEX 522621 DXIIIA TELEGRAM PATENTWEICKMANN MUNICH Tektronix, Inc. S.W. Griffith Drive, P.O. Box 500, Beaverton, Oregon 97077, U.S.A. Signal generator Claims ^! 1 J Programmable signal generator, characterized by a generator (12, 14) for generating an output signal of a predetermined frequency as a function of a digital control signal, a measuring stage (18) for measuring the duration of at least one period of the output signal and a stage (10) for modifying the digital one Control signal as a function of the period measurement. 2. Signal generator according to claim 1, characterized in that the output signal generator (12, 14) has a converter (12) for transferring the digital control signal to a having an analog control voltage and an oscillator (14) controlled by the analog control voltage. 3. Signal generator according to claim 1 and 2, characterized in that that the converter (12) is a digital-to-analog converter and the oscillator (14) is a voltage controlled oscillator. Signal generator according to one of Claims 1 to 3, characterized in that the measuring stage (18) is a counter (40) for counting reference clock pulses during the Has period duration. Signal generator according to one of Claims 1 to 4, characterized in that the modification stage (10) is a digital control signal generating processor, the frequency as a function of the period measurement of the output signal and modified the digital control signal so that the output signal a has a predetermined frequency.