Quadrature stepwave frequency converter

1. A quadrature stepwave frequence converter comprising a two-output device having a plurality of control inputs for changing the gains for the signals transmitted from its inputs to its outputs upon a change in the values of the binary signals at the control inputs, and a sequencer having its outputs connected to the control inputs of the two-output device for applying binary signals to said control inputs so as to vary the gain for the signal transmitted from the input of the two-output device to its one output according to a step variable function approximating a sine wave and to vary the gain for the signal transmitted from the input of the device to its other output according to a step variable function approximating a cosine wave, wherein the improvement comprises said two-output device comprising first and second variable-gain circuits, each having N control inputs forming a separate group of the control inputs of the device and respectively corresponding to the control inputs of the other variable-gain circuit for changing the absolute value of the gain for the signal transmitted from a first input of the device to a first output upon a change in the value of the binary signal applied to a control input of said first variable-gain circuit and the absolute value of the gain for the signal transmitted from a second input of the device to a second output upon a change in the value of the binary signal applied to a control input of the second variable-gain circuit so that a change in the value of the binary signal applied to a control input of a variable-gain circuit produces a change in the absolute value of the corresponding gain by a predetermined value corresponding to this control input and in a direction determined by the direction of the change in the binary signal and so that changes in the binary signals applied to the control inputs of one variable-gain circuit produce changes in the corresponding gain which are proportional to the changes in the other gain produced by changes in the binary signals at the corresponding control inputs of the other circuit;

• and first and second sign reversing circuits, said first sign reversing circuit being connected to said first variable-gain circuit and the second sign reversing circuit being connected to the second variable-gain circuit, each of the sign reversing circuits having a control input forming another control input of the two-output device for reversing upon a change in the value of the binary signal at the control input of the sign reversing circuit the sign of the gain, the absolute value of which is varied by means of the variable-gain circuit connected to this sign reversing circuit;
  
  wherein the sequencer has first and second sign control outputs, said first sign control output being connected to the control input of said first sign reversing circuit and the second sign control output being connected to the control input of the second sign reversing circuit for applying to said control inputs binary signals each changing its value at regular intervals and which are shifted in phase with respect to each other by 90°
  
  , and a plurality of gain value control outputs connected to the control inputs of the variable-gain circuits for changing the value of the binary signal applied to each of the control inputs of said first variable-gain circuit first in a direction providing an increase in the gain absolute value and then in a direction providing a decrease in the gain absolute value during each time period between two successive changes in the binary signal at the control input of the first sign reversing circuit connected to the first variable-gain circuit so that a change in the binary signal at each next-in-order control input of said first variable-gain circuit in a direction providing an increase in the gain absolute value occurs after a change in a similar direction in the binary signal at the preceding-in-order control input of said first variable-gain circuit (5), a change in the binary signal in a direction providing a decrease in the gain absolute value occurs before a change in a similar direction in the binary signal at the preceding-in-order control input of said first variable gain circuit, and for changing the binary signals applied to the control inputs of the second variable gain circuit so that the instant of change in the value of the binary signal at that control input of the second variable-gain circuit which corresponds to the "k"th-in-order control input of the first variable gain circuit in a direction providing a change in the gain absolute value in one sense coincides with the instant of change in the value of the binary signal at the (N-k+I)th-in-order control input of the first variable gain circuit in a direction providing a change in the gain absolute value in the opposite sense.