Behringer T1953 manual Dynamic range capabilities of various devices

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TUBE ULTRAGAIN T1953

without components. Even if special low-noise components are used, a certain degree of basic noise cannot be avoided.

This effect is similar when replaying a tape. The non-directional magnetic particles passing the replay head can also cause uncontrolled currents and voltages. The resulting sound of the various frequencies is heard as noise. Even the best possible tape biasing can “only” provide signal-to-noise ratios of about 70 dB, which is not acceptable today since the demands of listeners have increased. Due to the laws of physics, improving the design of the magnetic carrier is impossible using conventional means.

4.1.2 What are audio dynamics?

The human ear can detect the most wide ranging amplitude changes—from the slightest whisper to the deafening roar of a jet-plane. If one tried to record or reproduce this wide spectrum of sound with the help of amplifiers, cassette recorders, records or even digital recorders (CD, DAT etc.), one would immediately be restricted by the physical limitations of electronic and acoustic sound reproduction technology.

The usable dynamic range of electroacoustic equipment is limited as much at the low end as at the high end. The thermal noise of the electrons in the components results in an audible basic noise floor and thus represents the bottom limit of the transmission range. The upper limit is determined by the levels of the internal operating voltages; if they are exceeded, audible signal distortion is the result. Although in theory, the usable dynamic range sits between these two limits, it is considerably smaller in practice, since a certain reserve must be maintained to avoid distortion of the audio signal if sudden level peaks occur. Technically speaking, we refer to this reserve as “headroom”—usually this is about 10 - 20 dB. A reduction of the operating level would allow for greater headroom, i.e. the risk of signal distortion due to level peaks would be reduced. However, at the same time, the basic noise floor of the program material would be increased considerably.

P/dB

 

 

 

 

 

140

 

 

 

 

 

120

 

 

 

 

 

100

 

 

 

 

 

80

MicrophoneAmplifier

 

 

 

 

60

PowerAmplifier

TapeRecorder

 

 

40

Radio

Cassette Recorder

Ear

Fig. 4.2: The dynamic range capabilities of various devices

It is therefore useful to keep the operating level as high as possible without risking signal distortion in order to achieve optimum transmission quality.

It is possible to further improve the transmission quality by constantly monitoring the program material with the aid of a volume fader, which manually levels the material. During low passages the gain is increased, during loud passages the gain is reduced. Of course it is fairly obvious that this kind of manual control is rather restrictive; it is difficult to detect signal peaks and it is almost impossible to level them out. Manual control is simply not fast enough to be satisfactory.

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4. TECHNICAL BACKGROUND

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Contents Tube Ultragain Safety Instructions Detailed Safety InstructionsForeword Dear CustomerTube Ultragain Table of Contents Introduction ConceptBefore you get started Control elementsControl elements on the front panel Tube section of the Tube Ultragain Tab .1 Basic setup of the Tube Ultragain OperationApplications Tube Ultragain as a microphone preampTube Ultragain as a direct injection box Technical BackgroundTube Ultragain as a level converter Tube Ultragain as tube interfaceAudio dynamics LevelDynamic range capabilities of various devices Tubes used in the Tube Ultragain Tube historyDesign and functional principle of tubes DiodeProperties of tubes Formula for calculating partial harmonic distortionStudio applications Best of both worldsUTC circuit Phantom power Dynamic range of various mediaMains connection InstallationRack mounting Audio connections Transformer-balanced output optionSpecifications XLRWarranty § 1 Warranty CARD/ONLINE Registration § 2 Warranty