The present invention discloses a novel frequency converter.
Frequency converters are used in order to convert an electromagnetic signal at one frequency to another frequency. The frequency conversion can be either up-conversion or downconversion, i.e. a signal at a certain frequency can be shifted either to a higher or a lower frequency. Frequency converters are used in such systems as, for example, radio communications systems and radar systems.
A traditional frequency converter uses a mixer which has as its input signals the signal whose frequency it is desired to shift and a signal at another frequency, and provides as output the mixing product of the input signals. This product comprises so called sum and difference signals, i.e. signals at frequencies which are the sum and the difference of the frequencies of the input signals.
The parameter usually referred to as conversion gain, defined as the ratio of the power (or, alternatively, voltage) of the output signal to the power (or alternatively, voltage) of the input signal whose frequency is shifted in the frequency converter, is a parameter which it is naturally a desire to improve on in frequency converters.
It is an object to provide a frequency converter with improved conversion efficiency. This object is obtained by means of a frequency converter which comprises a first mixer arranged to receive a first and a second input signal, and to have as its output the sum and the difference of the first and second input signals.
The frequency converter also comprises generating means for generating the second input signal and for receiving the output signal of the first mixer and multiplying it by a signal at a frequency which is two times the frequency of the second input signal, thereby generating a product. In addition, the frequency converter also comprises adding means for obtaining the sum of said product and the output signal from the first mixer.
By means of this frequency converter, increased conversion efficiency can be obtained, as will be shown in the following detailed description.
In embodiments of the frequency converter, the generating means comprise a local oscillator and a second order sub-harmonic mixer, and the second order sub-harmonic mixer is arranged to receive as input signals the output signal from the local oscillator and the output from the first mixer.
In embodiments of the frequency converter, the generating means comprise a dual-band local oscillator which is arranged to output a signal at frequency fLO to the first mixer and a signal at frequency 2*fLOto a second mixer which is also comprised in the frequency converter and which is arranged to also receive as an input signal the output from the first mixer.
In embodiments of the frequency converter, the generating means comprise a local oscillator connected to a frequency multiplier with a multiplication factor of two, and a second mixer which is arranged to receive as input signals the output signal from the frequency multiplier and the product from the first mixer.
In embodiments of the frequency converter, the generating means is arranged to receive the output signal of the first mixer via a band-pass filter which is arranged to remove a sum or a difference component in the output from the first mixer.
In embodiments, the frequency converter also comprises a band-pass filter for removing the sum or the difference obtained in the adding means.
The invention will be described in more detail in the following, with reference to the appended drawings, in which
Embodiments of the present invention will be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown. The invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Like numbers in the drawings refer to like elements throughout.
The terminology used herein is for the purpose of describing particular embodiments only, and is not intended to limit the invention.
On the other hand, the frequency converter 100 can also be used in a transmitter in a radio or a radar system, so that the signal fin is a signal intended for transmission, in which case the frequency converter 100 is used for so called up-conversion of the signal fin, i.e. in order to “shift” the received signal fin to a higher frequency.
In short, the frequency converter 100 can be used either for up-conversion or for down-conversion of the frequency of the signal fin. In the following, down-conversion by means of the frequency converter 100 will be described, but those skilled in the art will realize how a corresponding up-conversion can be obtained by means of the frequency converter 100.
The first mixer 105 is arranged to have as its output signals(s) both a sum and a difference between the two input signals, i.e. the output signal(s) from the first mixer 105 can, as shown in
The signal fLO, a so called “local oscillator” signal, is supplied to the first mixer 105 from a means 120 for generating the signal fLO. The means 120 is also arranged, as shown in
The multiplication of (fin+fLO) and (fin−fLO) by *2fLO, yields as output signal(s) from the means 120 the following, as is also shown in
As shown in
Any of the components present in the output signal(s) from the adder 110 and thus in the output signal(s) from the frequency converter 100 can be “extracted” so that it is the sole component in the output signal from the frequency converter 100 by means of filtering the output signal(s) from the adder 110, for example by means of a band-pass filter, which will be shown in more detail in the embodiments shown in
The term “ordinary mixer” is here used in the sense of a mixer component that receives as inputs a first signal at a frequency f1 and a second signal at a frequency f2 and produces output signals at frequencies fout=(f1±f2). In the definition of the SHM2 above, the two frequencies f1 and f2 can be the LO and RF signals.
The output signal from the LO 305 is fed to both the first mixer 105 and to the SHM2 310.
As shown in
A more theoretical description of the function of the frequency converter 300 is as follows: Mathematically, the output from the first mixer 105 can be seen as follows if we use y(t) to denote the output from the mixer 105 and the symbol ω with respective indices to denote the frequencies involved and the letter A with indices to denote the amplitudes involved:
In a traditional frequency converter, in the case of down-conversion, only the difference term in equation 1, i.e. (ωin−ωLO) is used, and the conversion gain of such a frequency converter therefore becomes:
Similarly, if a second mixer is applied to mix the sum term (ωin+ωLO) in equation 1 with a signal at frequency 2*ωLO, i.e. ALO2 cos(2ωLOt), the following components will be obtained at the output of the second mixer:
To avoid generating the component 2·ωLO signal in the second mixer the second order SHM2 is chosen as the “second mixer”, i.e. the SHM2 310, as shown in
It can be observed that equation 3 also contains the desired difference frequency component (ωin−ωLO), i.e. the desired difference frequency component if the frequency converter 300 is to be used for down-conversion.
Now, combining constructively (i.e. in-phase) the difference frequency term from equation 1 and equation 3 results in a total output of the desired frequency component:
Therefore, the total conversion gain of the frequency converter 300 becomes:
Gv=Gv1(1+Gv2) (Equation 5)
Or, in decibel, dB:
Gv (dBv)=Gvi(dBv)+20log (1+Gv2) (Equation 6)
is the conversion gain of the “second mixer”, i.e. the SHM2 310 in
From equation 5, it is clear that the frequency converter 300 shown in
Another way of designing the generating means 120 is shown in an embodiment 600 in
In the drawings and specification, there have been disclosed exemplary embodiments of the invention. However, many variations and modifications can be made to these embodiments without substantially departing from the principles of the present invention. Accordingly, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation.
The invention is not limited to the examples of embodiments described above and shown in the drawings, but may be freely varied within the scope of the appended claims.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/065448 | 7/22/2013 | WO | 00 |