DE2547092B2 - Intermediate frequency converter - Google Patents

Description

The invention relates to an intermediate frequency converter for the intermediate frequency Transition from a message transmission system, in particular a radio relay system with a first predetermined one Intermediate frequency to one with a second predetermined dual frequency and vice versa.

For example, in the case of directional radios for TV transmission or TF occupancy up to 1800 voice channels the dual frequency 70 MHz, while directional radios for 2700 voice channels because of the larger bandwidth required here from an intermediate frequency of Make use of 140 MHz.

In the case of such directional radio links existing within a communications network, there is with regard to the best possible use of the wish, if necessary a signal with 1800 voice channels or a To lead television programs over a radio link, which is designed for 2700 voice channels, should in In such cases the principle of IF through-connection must be maintained by special

ίο Measures are taken to ensure that devices with the Intermediate frequency 70MHz and 140MHz can work together. It is possible to switch the signal through with 1800 Voice channels on the radio link with 2700

i-voice channels in the base frequency level with demodulation and perform modulation again. But this creates additional noise and distortion effective. The connection in the IF level is also particularly useful when transmitting TV programs attached to bypass the modem's pulse distortion.

In addition to the high requirements for freedom from harmonics and freedom from distortion, such a Intermediate frequency converter to ask for the most economical concept possible in order to to ensure a reasonable relationship between technical effort and benefits.

The invention is based on the object described in the introduction for an intermediate frequency converter Kind of specifying a solution that, if the quality requirements of a broadband implementation are high, the Possibility of an optional reversal of the conversion direction allows, without that for such Reversal of the conversion direction required conversion of the intermediate frequency converter of additional components or circuit parts required.

This object is achieved for an intermediate frequency converter according to the invention in that in Signal flow direction an up-converter forming a first assembly with a first conversion oscillator and a downconverter forming a second assembly with a second conversion oscillator in series are connected that also for an optional reversal of the conversion direction the assignment of Conversion oscillators, at least with regard to the frequencies of the vibrations that generate them, with one another interchangeable and the frequency characteristics of the intended ones which are dependent on such an interchange Selextion means of the two assemblies

are designed so indefinitely.

In the invention it is assumed that a direct implementation of a first predetermined Intermediate frequency to a second predetermined dual frequency is generally not possible because Harmonics of the fundamental frequencies would fall into the useful band. The same problems also arise when the direction of implementation is reversed. Due to the chosen double implementation over a high Dual frequency can overcome these difficulties. Furthermore, the invention lies in the knowledge based on the fact that a reversal of the conversion direction can then be achieved with simple means without additional components or circuit parts can be realized when the high dual frequency is independent of the direction of the Implementation is firmly specified, because then the conversion of the intermediate frequency converter is in the essentially on swapping the frequencies of the conversion oscillators with regard to the ones assigned to them

Implementers limited.

In a preferred embodiment of the intermediate frequency converter, each assembly is divided into two subassemblies, namely a converter subassembly and an oscillator subassembly. Both assemblies are combined back to back in a housing, separated by a metallic shield, to form a double assembly ₀ supply lines shielded from one another

In a preferred application of an intermediate frequency converter for the intermediate-frequency transition of a radio relay system with a Intermediate frequency from 70 MHz to one with an intermediate frequency of 140 MHz and vice versa the high intermediate frequency at the output of the up-converter 448 MHz. Hence the frequencies of the first conversion oscillator with an input signal of 70 or 140 MHz for 518 MHz and that of the second conversion oscillator set for 588 or 518MHz. The high intermediate frequency offers a good Freedom from interference and enables conventional components and construction principles to be used bring to. Since the lower sideband is used in both implementations, so the Reversal implementation carried out twice in a row the intermediate frequency signal on the output side is in the normal position again.

In order to achieve a high long-term frequency constancy of the conversion oscillators with relatively little effort ensure, they each consist of a crystal oscillator with a downstream frequency multiplier.

In the preferred embodiment of an intermediate frequency converter from 70 to 140 MHz and conversely, it makes sense if the frequency multiplier has the multiplication factor 5, because this means that In addition to the useful oscillation, the interference spectrum that occurs has a sufficient frequency spacing from the useful band Has.

On the basis of an embodiment shown in the drawing, the invention is intended in the following will be explained in more detail. In the drawing mean

Fi g. 1 the structure of an intermediate frequency converter according to the invention,

2 and 3 show the intermediate frequency converters according to FIG. 1 self-contained double assembly.

In Fig. 1, the input-side and the output-side assembly de- double assembly with BC X and BG 2 are designated. The input-side module BC 1 of the intermediate frequency converter, at the input of which the input-side signal with the intermediate frequency fz X is applied, in turn consists of two sub-modules, namely the up-converter AU \ and the first conversion oscillator UO 1. In the same way, the output-side module BC 2 consists of two sub-assemblies, namely the down converter AU2 and the second conversion oscillator UO 2. The input-side signal with the intermediate frequency fz 1 reaches the mixer M 1 via the attenuator D 1 and the input selection low-pass filter TP to the mixer M 1, to which the oscillation at the frequency via its second input f \ of the first conversion oscillator UOX is supplied. The attenuator DX has the task of attenuating the level of the input signal for the purpose of the weakest possible control of the mixer MX and in this way contributing to a reduction in the size of the undesired but unavoidable disruptive spectral lines when the minching process is carried out. The output of the mixer M 1 is followed by the amplifier V 1, which amplifies the oscillation generated in the mixer M 1 with the high intermediate frequency & 3 and then feeds it to the bandpass filter BPX. The bandpass filter BPX suppresses the undesired mixed products outside the useful band. On the output side, the up converter AUX consists of the attenuator D 2, which feeds the oscillation with the high intermediate frequency fz3 to the input of the down converter AU2 in a decoupled manner.

The downconverter AUI for its part consists of the mixer MI on the input side and its output is connected to the input of the bandpass filter BP2 , which is connected to the amplifier V2 at the second input of the mixer MT. the oscillation generated by the second conversion oscillator UO 2 lies with the frequency f2. The bandpass filter BP2 is used in the same way as the bandpass filter BP. also the suppression of the undesired mixed products occurring during the mixing process outside the useful band. The converted input-side signal is available at the output of the amplifier V2, which in this case represents the output of the intermediate frequency converter, with the intermediate frequency fz 2 .

The conversion oscillators UOX and UO2 each consist of a crystal oscillator OX or O 2 with a downstream frequency multiplier FV1 or FV2. Each of the two frequency multipliers consists in turn of a multiplier stage VS 1 or VS2, which operates on the output side on a selective amplifier SV 1 or SV2 .

With regard to a preferred embodiment of an intermediate frequency converter 70/140 MHz, the input-side intermediate frequency fz X 70 MHz, the high intermediate frequency fz3 448 MHz, the output-side intermediate frequency fz2 140 MHz, the frequency of the first conversion oscillator UOX 518 MHz and the frequency f2 of the second conversion oscillator UO 2 j88 MHz. Taking into account the multiplication factor η - 5 of the multiplier stages VSX and VS2 , the frequency of the crystal oscillator OX is 103.6 MHz and that of the crystal oscillator O2 is 117.6 MHz. If the intermediate frequency converter is to carry out the conversion in the opposite direction, i.e. if there is an intermediate frequency signal with the frequency fz2 = 140MHz on the input side and if the output-side signal is to have the intermediate frequency fz X = 70MHz, then this can be achieved in a simple manner by the oscillator subassemblies, i.e. the first conversion oscillator VJX and the second conversion oscillator UO2 are interchanged. Furthermore, in this case it is necessary to retune the low-pass filter TP of the up-converter AUX and the band- pass filter BP2 of the down- converter AU2 . The changeability of these selection criteria is shown in FIG. 1 indicated by an arrow at the specified location.

Instead of interchanging the conversion oscillator subassemblies, use can also be made of merely interchanging the quartz crystals of the quartz oscillators with one another. In this case, however, it is then necessary to also design the selection means of the selective amplifiers SVX and SV2 so that they can be tuned. This is indicated in Fig. 1 at the specified location by a broken line in each case.

indicated by an arrow.

With a view to a structural design that is as space-saving as possible while at the same time ensuring mutual decoupling, the two assemblies BG I and BG 2 according to FIG. I combined to form a back-to-back double assembly. As the housing sketch according to FIG. 2 shows, the assembly BG 1 is in the right half and the assembly BG 2 in the left half of the double assembly housing. The assemblies themselves are only indicated by the circuit boards LPi and /./'2 indicated in broken lines. The circuit boards LPi and /.P2 are separated from one another by the metallic shield AS . The frame of the Doppelbaugriippengehäuscs is designated with R and the removable cover with Dk 1 and Dk 2 . For the connection between the output of the Aufwärlsumset / crs ALIX to the input of the down converter ALl2 , aligned openings 0 are provided in the circuit boards /./'I and LP2 and in the metallic shielding AS. The line connection is denoted by 10. The input of the assembly BG I is realized through the coaxial socket KB I and the output of the assembly BG2 through the coaxial socket KB2 on the lower narrow side of the frame R.

As the section A / B shown in FIG. 3 of the double assembly according to FIG. 2 can further be seen. are the circuit boards LPi and LP2 according to FIG. I and divided according to the sub-assemblies. The longitudinal joint is denoted by F. In the area of the longitudinal joint F of both assemblies and in their extension, metallic partition walls ΓW1 and TW2 are provided on both sides. The partition walls each form a shaft which is used to accommodate the supply lines for the adjacent sub-assemblies. The connection lines for supplying the oscillator vibrations to the mixers

υ are labeled 11 and 12. The partitions 7 "1Vl and 7"H'2 go through the printed circuit boards LPi and I.P2 and are connected to one another in a conductive connection via the Fcdcrbleche FB. The

2 "partitions TWI and TW2 on the ropes of the cover DK 1 and DK 2 via spring seals FL I and FL 2 in good conductive connection with the frame R.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. ZwisenenfrequenzumseKer for the transition from a communication system, with a first predetermined intermediate frequency to one with a second predetermined intermediate frequency and vice versa, characterized in that a first assembly (BC 1) forming an upconverter (AUi) with a first conversion oscillator in the signal flow direction (UO t) and a second assembly (BG 2) forming down converter (Al) H) with a second conversion oscillator (UOI) are connected in series, so that the assignment of the conversion oscillators, at least with regard to the frequencies (f \, F2) of the vibrations they generate, interchangeable with one another and the frequency characteristics of the intended selection means (TP, BP2, SVi, SV2) of the two assemblies, which are dependent on such an interchange, are designed to be retunable. 2. Intermediate frequency converter according to claim 1, characterized in that each assembly (BG i, BG 2) is divided into two sub-assemblies, namely a converter (AUi, AU2) and an oscillator sub-assembly (UO 1, UO2) , that furthermore both assemblies are combined back to back in a housing, separated by a metallic shield (AS), to form a double assembly and that the two subassemblies of an assembly are each shielded from one another by a shaft i. '. r supply lines formed by metallic partition walls (TWi, TW2) . 3. Intermediate frequency conversion. ; r according to claim 1 or 2, for the intermediate frequency transition of a radio relay system with an intermediate frequency of 70 MHz to one with an intermediate frequency of! 40 MHz and vice versa, characterized in that the high intermediate frequency (7z3) at the output of the up-converter is 448 MHz and consequently the frequencies (f \, (2) of the first conversion oscillator; (UO 1) for an input-side signal of 70 or 140MHz for 518 or 588 MH ;: and those of the second conversion oscillator (UO 2) for 588 or 518 MHz are specified. 4. Intermediate frequency converter according to one of the preceding claims, characterized in that the conversion oscillators (UOX, UO 2) each consist of a crystal oscillator (O 1, O2) with a downstream frequency multiplier (FVl, FV2) .