DE3405453A1 - Arrangement for calibrating radio-frequency circuits - Google Patents

Abstract

In an arrangement for calibrating radio-frequency circuits which can be (synchronously) tuned via direct-voltage-controlled reactance elements, particularly capacitance diodes, each of the radio-frequency circuits to be tuned is in each case connected to a separate operational amplifier (OP, OPn, n = 1 to m) with DC feedback. The inverting input of each operational amplifier (OP, OPn) is connected, on the one hand, via a resistor (R2, R2n) to a direct voltage (U1, U1n), which can be varied for a first calibration, and, on the other hand, via a trimming resistor (P2, P2n), which can be varied for a second calibration, to a fixed direct voltage (U2). Furthermore, the non-inverting input of each operational amplifier (OP, OPn) is applied directly to a variable tuning voltage (U3). In this case, the tuning voltage (U3) is selected for the calibration in such a manner that the condition U3 = U2 is met for the first calibration and the condition U3 NOTEQUAL U2 is met for the second calibration. <IMAGE>

Description

ARRANGEMENT FOR ALIGNMENT OF HIGH FREQUENCY CIRCUITS DESCRIPTION The invention relates to an arrangement for the adjustment of high frequency circuits, which are controlled by voltage Reactance elements, in particular capacitance diodes, (are synchronously tunable.

Increasingly, in selective high-frequency circuits, especially radio tuners, voltage-controlled variable reactance elements (capacitance diodes) used for voting. So that such multi-circuit circuits over their entire Frequency range have the best possible signal transmission curves, must be in their Tuning a very exact one Synchronization of the individual HF circuits to be guaranteed. Due to variations in the characteristic values of the used there Components, however, sufficient synchronization can only be achieved if the different HF circuits can be optimally matched to one another.

This is the case with electronically tunable tuners with digital tuning systems known for frequency synthesis, a tuning voltage curve for each circle to be tuned to generate the correction of the frequency-voltage curve of the corresponding Contains capacitance diode and its data is stored in memories and for each frequency to be set can be called up.

On the one hand, this method is relatively complex in terms of cost and technology and on the other hand only useful in connection with digital voting systems. In the simplest Form is the adjustment of the individual HF circuits in a known manner manually via the changeable circuit inductances as well as additionally inserted variable circuit capacitances to undertake. As a rule, this comparison is limited to two missing points of the frequency band that can be covered (e.g. upper and lower end of the band). Here will the individual circles of the circuit in question at the higher one Frequency by varying the additional available circular capacitance (trimming capacitor) and with the lower fruence by changing the corresponding coil inductance matched.

However, this adjustment method has the disadvantage that the mutually influence the adjustment steps to be carried out for the two frequency points. It is therefore necessary to do the iterative adjustment for both points alternately Repeat the sequence until a negligibly small adjustment error remains. The known manual method is therefore very time-consuming and requires automation difficult to access. In addition, there are certain adjustment tools when introducing or creating in or on the frequency-determining components there is a risk that the resonance frequency of the circle is changed undesirably, which inevitably leads to an incorrect adjustment leads.

The invention is based on the object of an arrangement for balancing to create electronically tunable high-frequency circles that provide a simple, easily automated two-point adjustment without iterative adjustment steps allowed. Furthermore, through the Arrangement adversely affecting the Adjustment by adjustment tools can be excluded.

This task is achieved with an arrangement of the type mentioned at the beginning according to the invention by those specified in the characterizing part of claim 1 Features solved. Advantageous further developments of the invention are set out in the subclaims marked.

With the help of the arrangement according to the invention, the tuning diodes tuning voltages that are separate from the individual circles and can be influenced by adjusting elements fed. Two frequency points are selected for the adjustment, at which the Settings required for the adjustment due to the advantageous design the arrangement according to the invention do not influence each other. Iterative, alternating Adjustment steps to be carried out can thus be dispensed with.

Since the adjustment is also carried out on control elements that are separate from the high-frequency circuits takes place and not, as in the known method, on the frequency-determining inductors and capacitances themselves can have an undesirable influence on the oscillating circuits Adjustment tools are avoided. Finally, the arrangement according to the invention offers good prerequisites for this, the few necessary for an optimal comparison Automate setting steps.

Embodiments of the invention are shown below with reference to drawings explained in more detail. 1 shows a basic circuit according to the invention for balancing an RF circuit, Fig. 2 shows a first extended arrangement according to the invention for Alignment of several RF circuits, FIG. 3 shows a second expanded arrangement according to the invention for balancing several HF circuits.

In the circuit according to FIG. 1, a potentiometer P1 and a resistor R3 existing voltage dividers from a fixed voltage source UF fed. The one outside tap of the potentiometer P1 is connected to the connection 1 of the fixed voltage source UF, while the other external tap via the resistor R3 is connected to ground. The variable voltage tap of the potentiometer P1 leads to the non-inverting input of a counter-coupled via a resistor R1 Operational amplifier OP.

In contrast, there is the fixed voltage tap between the potentiometer P1 and the resistor R3 via a Trim resistor P2 with the inverting input of the operational amplifier OP connected. The fixed voltage source UF also feeds another lying between connection point 1 and ground changeable voltage divider P3. Its variable tap is across from one the resistor R3 high-resistance resistor R2 also to the inverting Input of the operational amplifier OP connected, its output A with the tuning element (Capacitance diode) of a HF circuit to be tuned and matched in connection stands.

The alignment of the HF circuit with such an arrangement is expedient performed at the upper and lower end of the frequency range over which the HF circuit is to be tuned. The vote itself takes place on the non-inverting one Input of the operational amplifier OP lying potentiometer P1. To carry out of the two-point adjustment, this potentiometer is first in the end position a and then brought into the end position b.

The end position a corresponds to the first adjustment point, its The setting is made via the variable resistor P3 and the end position b is the second Adjustment point, the optimization of which is carried out with the trim resistor P2.

In the following it is initially assumed that the variable tap of the tuning potentiometer Pl is in the end position a (first adjustment point).

Depending on the circuit, the assumed potentiometer setting applies the relationship U2 = U3. Since the voltage UD is between inverting and non-inverting Input of the operational amplifier assumed to be ideal within its linear If the working range is always set to zero volts, the output voltage is for U2 = U3 UA of the operational amplifier regardless of the setting of the currentless Trim resistor P2. The voltage UA changes only when the voltage varies U1 and thus with the setting of the potentiometer P3, which is the only one responsible for the adjustment of the HF circuit at the first frequency point of the tuning range.

The variable tap is used to optimize the second adjustment point of the potentiometer P1 brought into the end position b. Since the voltage U2 by the unchanged voltage division between potentiometer P1 and resistor R3 is held at its original value, flows due to the resulting Potentiauintiffer a current across the trimming resistor P2. The tuning voltage UA at output A of the arrangement is now set in such a way that the differential input voltage UD of the operational amplifier in turn is zero volts. Consequently is the voltage UA for the second adjustment point by changing the setting of the trim resistor P2 can be influenced. After optimization, the comparison of the Circle completed. A new adjustment at the first frequency point is not necessary itself, since it also changes the setting of the trim resistor P2 preserved.

Fig. 2 shows an embodiment of the invention for the adjustment of several synchronously tunable high-frequency circuits. Each of the n circles has a separate, the Fig. 1 corresponding matching circuit assigned. Only the voltage divider P1, R3 represent a common component for all adjustment circuits those required for the adjustment and adjustment (second adjustment point) of each circuit variable and fixed input voltages U3 and U2. For this, the individual Infeed points of the balancing circuits for these voltages are connected to one another. The adjustment is carried out in the same way as already described for FIG. 1. Here, too, the tuning potentiometer is first brought into the end position a, which determines the first adjustment point of the n HF circuits. After the adjustment has been optimized of all individual circuits in this point via the potentiometers P31 to P3n, the variable Tapping of the tuning potentiometer P1 rotated into the end position b, which is the second Forms the adjustment point of the n HF circles. The comparison of the individual HF circuits via the trimming resistors P21 to P2n.

Fig. 3 finally shows an embodiment of the invention for Alignment of several HF circuits, which are synchronized via a frequency control system will. The arrangement differs from the circuit according to FIG. 2 in that that the tuning voltage U3 is not set via a potentiometer, but the Control output, for example the loop filter TP of a frequency or phase control system (PLL) is taken. This is analogous to the exemplary embodiment according to FIG. 2 as well here a fixed input voltage U2 at the corresponding feed points of the the potentiometer P1 is through a fixed resistor R4 replaced. The frequency or phase control system generates the voltage U3 from a certain input variable, for example the oscillator frequency of a frequency variable voltage controlled oscillator (VCO).

A phase discriminator PD compares the phase of the VCO output signal with the output signal phase of a frequency-stable reference oscillator REFO. The voltage is regulated so that the input variable of the system corresponds to a predetermined setpoint. If min becomes one of the n adjustment circuits between the output of the control system and the control input of the voltage controlled Switched oscillator, the HF circuits can be adjusted in a simple manner will.

At a first setpoint frequency (first adjustment point), that of the voltage U2 is assigned, the voltage Uln of the relevant balancing circuit must be above the associated potentiometer P3n can be set so that, due to the control behavior of the system, which sets the voltage U3 to U3 = U2. The index As a parameter (n = 1 to m), n stands for the number of the balancing circuit that starts with is connected to the frequency or phase control system (cf.

Fig. 3: n-1). Under the mentioned condition (U3 - U2) the trim resistance becomes P2n of the relevant balancing circuit de-energized, so that its setting does not Influences the associated output voltage UAn. The following applies depending on the circuit for all other connected balancing circuits also those for the first one Adjustment point necessary condition U3 = U2. This means that all other can also be synchronized HF circuits to be tuned can be adjusted. Then the frequency of the Control system to switch to a second specified setpoint frequency. It will themselves usually set a voltage U3 that is not assigned to the new setpoint frequency Voltage corresponds. Since now the condition U3 = U2 is no longer met, lets the output voltage UAn of the adjustment circuit connected to the control system with the trim resistor P2n belonging to this circuit so that the Voltage U3 corresponds to the specified target value. You can then use the appropriate Trimming resistors of the other circuits of the adjustment of the connected ones HF circles are carried out. Here, too, the alignment of the circles remains unchanged get the first frequency point, because there the respective settings of the trimming resistors P21 to P2n have no effect on the corresponding output voltages UAl to UAm to have.

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Claims (10)

ARRANGEMENT FOR ADJUSTMENT OF HIGH FREQUENCY CIRCUITS PATENT CLAIMS 1. Arrangement for the adjustment of high-frequency circuits, which are controlled by DC voltage Reactance elements, in particular capacitance diodes, are (synchronously) tunable, thereby characterized in that each of the och frequency circuits to be tuned each to one separate operational amplifier (OP, OPn, n = 1 to m) that the inverting input of each operational amplifier is connected (OP, ° Pn) on the one hand via a resistor (R2, R2n) with one for a first adjustment variable DC voltage (U1, Uln) and on the other hand via one for a second Adjustment of adjustable trimming resistor (P2, P2n) with a fixed DC voltage (U2) is connected that also the non-inverting input of each operational amplifier (OP, ° Pn) applied directly to a variable tuning voltage (U3) is, and that the tuning voltage (U3) is chosen for the adjustment so that for the condition U3 = U2 for the first adjustment and the condition for the second adjustment U3 d U2 is fulfilled. 2. Arrangement according to claim 1, characterized in that the changeable DC voltage (U1, Uln) via a potentiometer connected to a fixed voltage source (UF) (P3, P3n) can be set. 3. Arrangement according to claim 1 or 2, characterized in that the fixed DC voltage (U2) is taken from a voltage divider (P1, R3; R4, R3). 4. Arrangement according to one or more of claims 1 to 3, characterized characterized in that the tuning voltage (U3) is connected to a fixed voltage source (UF) lying potentiometer (P1) is adjustable, and that the potentiometer is a component of the voltage divider (P1, R3) for the direct voltage (U2). 5. Arrangement according to claim 4, characterized in that the end position (a) of the potentiometer (P1) the condition for the first adjustment and the end position (b) defines the condition for the second comparison. 6. Arrangement according to one or more of claims 1 to 3, characterized characterized in that the tuning voltage (U3) via a phase or frequency control system is adjustable. 7. Arrangement according to claim 6, characterized in that the phase or a frequency control system consisting of a reference oscillator (REFO), a voltage-controlled one Oscillator (VCO), a phase discriminator (PD) and a loop filter (TP) is constructed. Arrangement according to claim 6 or 7, characterized in that the voltage controlled oscillator (VCO) to one of the operational amplifier outputs (A1 to Am) is switched, and that the loop filter (TP) the tuning voltage (U3) is removed. 9. Arrangement according to claim 1 and one or more of the claims 6 to 8, characterized in that to define the first adjustment condition a first setpoint frequency of the phase or frequency control system for the voltage (U2) is assigned, and that to define the second matching condition a second Setpoint frequency is assigned to a voltage U3 J U2. 10 arrangement according to one or more of claims 1 to 9, characterized characterized in that the target frequencies selected for the adjustment at the upper and lower end of the band of the adjustable tuning range. Description: