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Microelectronic active RC channel bandpass filters in the frequency range 60-108 kHz for FDM SSB telephone systems

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3 Author(s)

The paper describes the development of microelectronic active-RC4-kHz-spaced channel bandpass filters (CBFls) for the frequency range 60-108 kHz, suitable for the formation and decomposition of the 12-channel bank (primary group) in direct-modulation-type FDM SSB telephone systems. The active filters are designed by simulation (essentially by Gorski-Popiel's method) of low-sensitivityLCfilters which are the duals of someLCCBF's currently used in FDM systems in the U.K. Our circuit development is firmly based on the microelectronic technology adopted by us, in which naked-chip dual- or quad-operational amplifiers, laser-adjustable thick- or thin-film resistors, and NPO ceramic-chip capa- th p citors are used. In order to minimize cost, the circuits are designed to accept, as far as possible, capacitors with preferred (and preferably also equal) nominal values, and a resistor adjustment procedure has been developed which permits wide capacitor manufacturing tolerances ofpm10 percent. This adjustment procedure also provides compensation for the nonideal characteristics of the amplifiers, leading to near-perfect simulation of the nominal dissipationlessLCprototype filters. Microelectronic models of channel 12 CBF (60-64 kHz) and channel 1 CBF (104-108 kHz) have been built (size of each filter:50 mm times 30mm times 5mm; dc power 400 mW). Channel 12 CBF meets the loss-frequency specification over the required temperature range 10-40°C. For channel 1 CBF the specification is met at ambient temperature (25°C) but not at 10°C or 4O°C; this will be remedied when amplifiers with higherf_{T}'s and/or lowerf_T-temperature coefficients become available. Neither filter requires a channel equalizer (whereas theirLCcounterparts do), and preliminary nonlinearity, noise, and intermodulation tests had promising results.

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Circuits and Systems, IEEE Transactions on  (Volume:25 ,  Issue: 12 )