| No High-End without professional filter technique |
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The major aim of DSS is to enable the listener
to enjoy his high-end components in his hours of relaxation at an utmost
level of sound perfection which has never been achieved before, and
to make this offer regardless of the cost and work involved, i.e. without
any compromise. The strong electronic demand of our modern age produces
strong pollution, both in the atmosphere as well as in power equipments
(by computers, radio etc.). This implies that anybody who appreciates
a perfect sound may not renounce on applying a solid power line filter
technique for the use of his components. Your high-end equipment will
benefit from DSS power line filter technique by its low factor of distortion
and jetter. DSS offers a new line of power line filter technique which
not only cleans your current but also stabilises it, makes it become
calmer and thus adds significantly more quietness, transparency, homogeneity |
| DSS Power Line Filter Technology |
| A general circuit is often distorted by interference
frequencies with strong amplitudes up to 300 MHZ. Apart from short-term
interferences (cracking), there are also permanent interference in the
net that persist. A permanent interference always occurs if the impulse
of interference lasts longer than 200 ms (DIN VDE 0875). These permanent
interferences are not only caused by household appliance, dimmers etc.
but also to a large extent by TV, HIFI- and digital equipments such as
CD-players. Here, the impulses of net interference are in particular modulated
by the control elements of semiconductors . Such permanent impulses of interference are spread at ungrounded sources of interference as well as at sources of interference at protective conductors. DSS-Power Line filters are conceived in a manner that they are able to filter push-pull interference as well as push-push interference without any loss of dynamics. . Unfortunately, the originally purely sine-shaped Sine of 50 Hz as received by power plants is being strongly deformed by numerous households and consumers. Interfering currents enter into the net by control circuits of these numerous different consumers. In addition, our electric circuit reacts like a huge aerial which picks up and transmits many different kinds of electro-magnetic radiation. This results in a broadband spectrum of interference which can only be fought off by freeing still existing sine of 5O HZ from the overlapping pollutions. For HIFI usage it is of utmost importance to develop a filter system that is characterised by a very low reactance. At this stage, DSS employs its own cost-intensive technology which is not being used with traditional HIFI-power line systems. Already at 50 HZ, a soft filtering procedure enters into action which slows down and softens the sine of 5o Hz which interferes with the circuit in acute waves. By means of this procedure alone, the sound is improved in a considerable manner, and the factor of cracking noise and jetter of the source appliance is reduced to a large extent. A symmetrically arranged overload protective device is integrated at the entrance of the filter system, which protects the subsequent power line electronic and off-end appliance against enormous peak currents. Further filter stations provide effective cleansing off low and high frequencies to prevent these from entering the components which are to be put in operation. At the exit of the filter system, a separate module provides a high-quality retroactive damping effect for filtering the interference voltage produced by the off-end appliance itself. This measure prevents push-pull interference between the individual components. HIFI components require a clean supply of electricity as a basis for precise processing of signals. High-quality equipments, in particular, react in a very sensitive manner upon any interference of the circuit which impedes to make most out of the large potential of the expensive equipment. Only optimal conditions of operation can guarantee a relief of work in all appliances. Very important: |
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