SU1029390A1 - Frequency divider - Google Patents

Abstract

WHAT DIVITER ": TOTS containing. the first; the first balaircHfetfl modulator, / the first filter and the first frequency division block; and so: the second frequency division block, the output of which is connected to the first input of the first balanced modulator at; . ; The first input t of the first balanced modulator is a frequency separation input JJ, characterized in that, in order to expand the range of the division factors, between the output of the first division unit, the frequency and exit of the second frequency division unit are entered in series by the second balance modulator and the second filter , while the second input of the second tower modulator is connected to the WTO {H1M input of the first balanced modulator.,. Ag

Description

The invention relates to radio engineering and can be used to receive signals with a divided simple and fractional frequency division factor in various radio engineering devices, including frequency synthesizers.

A frequency divider is known, comprising a first modulator connected in series, a first bandpass filter, a first amplifier, a second MSDuller, a second bandpass filter, a second amplifier whose output is connected to another modulator input, and a third bandpass filter that is connected between another output the second modulator and one of the inputs of the first modulator, with the first, second and third band-pass filters being tuned to frequencies.

. J 3fex

G 5

where Fg is the input frequency of the divider. The well-known frequency divider provides frequency division by a factor of 5.Г1.

The disadvantage of such a frequency divider is that any division factor cannot be obtained due to the fact that the stationary subharmonic mode is established only with a sufficiently large amplification factor in the feedback circuit, which makes its operational stability unreliable.

The closest to the present invention is a frequency divider, containing the first balanced modulator in series, the first filter and the first frequency dividing unit, and the second dividing unit is also partial, the output of which is connected to the first input of the first balancing modulator, while the first balanced modulator is the input of frequency divider 121.

In this frequency divider, it is possible to obtain fractional dividing coefficients, however, the range of possible dividing ratios is also limited due to the use in division units of the frequency of dividing steps by only 2 times limiting the possible number of series-connected dividing steps due to an increase connection.

The purpose of the invention is to expand the range of division factors.

The goal is achieved by the fact that the first balanced modulator, the first filter in the first frequency division unit, and the second frequency division unit, the output of which is connected to the first input. The first balanced modulator, the second input of the first balanced modulator VL4 with an input: a frequency divider, serially connected second balance modulator and a second filter are inserted between the output of the first frequency dividing unit and the input of the second frequency dividing unit, th second input of the second balanced modulator coupled to a second input of the first balanced modulator

The drawing shows the electrical circuit of the proposed frequency divider.

The frequency divider contains the first balanced modulator 1, the first filter 2, the first frequency dividing unit 3, the second balanced modulator 4, the second filter 5, the second frequency dividing unit 6.

The frequency splitter works as follows. {an example is considered of dividing the input frequency by 5 and 5/2).

The input signal of the divisible frequency is fed to the second input of the first balanced modulator 1, and its first input is a signal from the output of the second frequency dividing unit 6, having a division factor, for example, 2, and made in the form of a harmonic oscillator 2F

NII on frequency. &. working

5 in hard sync from

signal from the output of the second filter 5. Tuned to frequency. 9., sub-

Connected to the output of the balance modulator 4.

 4Fax

The frequency signal is t

. s ..

; but the frequency of the conversion of the second balanced modulator 4, since it receives the input signal divi «he frequency Fg and the output from the frequency division unit 3, for example, c, the division factor is three

GM:

The frequency division block 3 is made the same as the HarmoFex autogenerator

oscillations on frequency

working in the mode. hard synchronization from the signal from the output of the first f. 2, tuned to the frequency

. and connected to the output of the first

th balanced modulator 1. Signal

ZRoh frequency -§- is differential

the conversion frequency of the balanced modulator 1, since it receives the input signal often divisible

/ - you Fgj (H signal frequency- | output

frequency dividing unit b. The bandwidth of the filter 2 determines and ensures the capture and synchronization diapsoon of the autogenerator of the first frequency division block 3, the passband of the filter 5 determines and provides the capture and synchronization range of the autoheuer generator of the second frequency division block b. Since the balanced modulators 1 and 4 are given a large am- signal. the amplitudes from the outputs of the frequency blocks b and 3, then at the output of the balanced modulator 1, as well as at the output of the high-speed modulator 4, the value of the differential transformed hour 3F .x

tots -f and accordingly 4Fex frequencies

large in size and available

accurate for tight sync

frequency oscillator oscillator

3 and according to the block dividing hour

6f tots and differential amplifier often

conversions after modulators are not

are required.

The use of frequency division blocks 3 and b in the proposed frequency divider in the form of frequency division steps with division coefficients (in various combinations 2, 3, 5, and I also in the form of serially divided division steps with division factors 2, 3, 5, using two balanced cells and two-cross feedback circuits can significantly expand the range of division factor. Possible division factors Nl (2 /, | provided by the proposed frequency divider at the outputs of the first (second dividing unit tots are extracted with the formula

k, jj, tf

1 (2)

where K is the dividing factor of all, therefore included; steps for dividing the first bl; c dividing the frequency; K is the division factor of all Rof. Consequently, the start of dividing the second block of the frequency division is included.

The frequency divider allows you to simultaneously receive several coherent signals with distributed division factors from each frequency division unit and from each frequency division stage.

Claims (1)

A FREQUENCY SPLITTER containing the first 'balanced modulator, the first filter and the first frequency division unit, as well as the second frequency division unit, the output * of which is connected to the first input> of the first .balanced modulator at. <<. .This second input t of the first balanced modulator is an input of a frequency divider, characterized in that, in order to expand the range of division factors, a second balanced modulator and a second filter are connected in series between the output of the first frequency division unit and the input of the second frequency division unit, while the second the input of the second balanced modulator is connected to the second input of the first balanced modulator. boo woo