ATOS amplifier E-RI-LEB-N-NP-01H in stock
$378.59
The working principle of the Italian ATOS amplifier: The high-frequency power amplifier is used as the final stage of the transmitter. Its function is to amplify the high-frequency modulated wave signal to meet the transmission power requirements. Then, it is radiated into space through the antenna to ensure that the receiver in a certain area can receive a satisfactory signal level without interfering with the communication of adjacent channels.
Brand
ATOS/Italian Atos
Origin Category
Imported
Application Fields
Chemical, Petroleum, Mining, Energy, Comprehensive
ATOS Piston Pumps, ATOS Gear Pumps, ATOS Axial Piston Pumps, ATOS Vane Pumps, ATOS Hydraulic Cylinders, ATOS Relief Valves
ATOS Amplifiers, including electronic amplifiers, hydraulic amplifiers, and pneumatic amplifiers, are widely used, with electronic amplifiers being the most common. With the promotion of jet technology (see Jet Components), the application of hydraulic or pneumatic amplifiers is also gradually increasing. Electronic amplifiers are further classified according to the active devices used: vacuum tube amplifiers, transistor amplifiers, solid-state amplifiers, and magnetic amplifiers, with transistor amplifiers being the most widely used. In automated instrumentation, transistor amplifiers are commonly used for voltage and current amplification of signals, mainly in single-ended and push-pull forms. They are also frequently used for impedance matching, isolation, current-to-voltage conversion, charge-to-voltage conversion (such as charge amplifiers), and to realize a certain functional relationship between output and input (such as operational amplifiers).
ATOS amplifiers are important components of transmitting devices in communication systems. High-frequency power amplifiers are classified into two types based on their operating frequency band: narrowband and wideband. Narrowband high-frequency power amplifiers typically use a frequency-selective circuit with frequency filtering capabilities as their output circuit, hence they are also called tuned power amplifiers or resonant power amplifiers. Wideband high-frequency power amplifiers use a transmission line transformer or other wideband matching circuits as their output circuit, therefore they are also called untuned power amplifiers. A high-frequency power amplifier is an energy conversion device that converts DC energy supplied by a power source into high-frequency AC output. As known in the course "Low-Frequency Electronic Circuits," amplifiers can be classified into three classes (A, B, and C) based on their current conduction angle. Class A amplifiers have a current conduction angle of 360°, suitable for small-signal, low-power amplification. Class B amplifiers have a current conduction angle of approximately 180°; Class C amplifiers have a current conduction angle less than 180°. Both Class B and Class C are suitable for high-power operation. Class C has the highest output power and efficiency among the three operating classes. Most high-frequency power amplifiers operate in Class C. However, Class C amplifiers suffer from excessive current waveform distortion, making them unsuitable for low-frequency power amplification. They are only suitable for resonant power amplification using a tuned circuit as the load. Because the tuned circuit has filtering capabilities, the circuit current and voltage remain very close to a sinusoidal waveform, resulting in minimal distortion.
The main working principle of an ATOS amplifier:
The lock-in amplifier in an ATOS amplifier is essentially an analog Fourier transform. The output of the lock-in amplifier is a DC voltage, proportional to the amplitude of the input signal at a specific frequency (the parameter input frequency). Other frequency components in the input signal contribute nothing to the output voltage.
Two sinusoidal signals, both 1Hz and 90 degrees out of phase, multiplied together, result in a sinusoidal signal with a DC bias.
Multiplying a 1Hz signal and a 1.1Hz signal results in a modulated signal with a sinusoidal profile and a DC bias of 0.
Only signals with the same frequency as the reference signal will produce a DC bias at the multiplier output; other signals will produce AC signals at the output. If a low-pass filter is added to the output of a multiplier, all AC signal components are filtered out, leaving only the DC component whose amplitude is proportional to the amplitude of the specific frequency signal component in the input signal.
Main applications of ATOS amplifiers:
ATOS amplifiers are primarily used to detect weak signals with very low signal-to-noise ratios. Even if the useful signal is submerged in noise, or even if the noise signal is much larger than the useful signal, as long as the frequency of the useful signal is known, its amplitude can be accurately measured.
Basic introduction to ATOS amplifiers:
ATOS amplifiers are devices that increase signal amplitude or power. They are important components in signal processing tools in automation technology. The amplification effect of the amplifier is achieved by controlling the energy source with the input signal; the power consumption required for amplification is provided by the energy source. For linear amplifiers, the output is a reproduction and enhancement of the input signal. For nonlinear amplifiers, the output has a certain functional relationship with the input signal. Amplifiers are classified according to the physical quantity of the signal they process into mechanical amplifiers and electromechanical amplifiers.
E-ME-L-01H 40 /LQ32SA
E-ME-L-01H 40/DL27SB
E-ME-L-01H 40/PCNNSA
E-ME-L-01H/DL27SB
E-ME-L-01H/I 40 /LQ32SA
E-ME-T-01H 40 /DH04SA
E-ME-T-01H 40 /DH05SA
E-ME-T-01H 40 /DK14SC
E-ME-T-01H 40 /DK15SB
E-ME-T-01H 40 /QV0NSA
E-ME-T-01H 40 /TK14AA
E-ME-T-01H 40 /TK14SC E-ME-T-01H 40/TQ25SA
E-ME-T-01H 40/TQ32SA
E-ME-T-01H 40/TQ42SA
E-ME-T-01H 40/DK14SC
E-ME-T-01H 40/DK15SB
E-ME-T-01H 40/QV1NSB
E-ME-T-01H 40/TQ25SA
E-ME-T-01H/I 40 /DH04SA
E-ME-T-01H/I 40/DK14SC
E-ME-T-01H/I 40 /DP25SB
E-ME-T-01H/I 40 /DP25SC
E-ME-T-01H/I 40 /QV0NSA
E-ME-T-01H/I 40/TQ25SA
E-ME-T-01H/I 40/DK15SB
E-ME-T-01H/I 40/QVONSA
E-ME-T-01H/I 40/TQ25SA
E-ME-T-05H 40/DH07SA
E-ME-T-05H 40/DK17SA
E-ME-T-05H 40/DK17SB
E-ME-T-05H 40/DP27SB
E-ME-T-05H 40/DH07SA
E-ME-T-05H 40/DK17SB
E-ME-T-05H 40/DP27SB
E-ME-T-05H/I 40 /DK17SB
E-ME-T-05H/I 40 /DP27SB E-ME-T-05H/I 40/DH07SA
E-ME-T-05H/I 40/DK17SB
E-ME-T-05H/I 40/DP27SB
E-MI-AC-01F 11 /1
E-MI-AC-01F 11 /2
E-MI-AC-01F 11 /3
E-MI-AC-01F 11 /4
E-MI-AC-01F 11 /6
E-MI-AC-01F/7 11 /3
E-MI-AC-01F/7 11 /4
E-MI-AC-01F/RR 11 /1
E-MI-AC-01F/RR 11 /2
E-MI-AC-01F/RR 11 /3
E-RACK3HE21TE
E-RACK3HE28TE E-RACK3HE42TE
E-RACK3HE49TE
E-RACK3HE56TE
E-RACK3HE84TE
E-RI-TE-01H 40 /DH04SA
E-RI-TE-01H/I 40 /DH04SA
E-RI-TE-05H 40 /DK17SB
E-RP-AC-01F/I 10 /2
The company mainly deals with European and American brands. We can source brands from any European country, including leading German brands such as: BURKERT, DEMAG, HAWE, REXROTH, HYDAC, PILZ relays, FESTO, IFM sensors, E+H, HEIDENHAIN, P+F sensors, SICK, TURCK, and HIRSCHMANN industrial switches. German brands: Hengstler, Murr, Schmersal, Samson, EPRO (Emerson's subsidiary), MOOG (USA), ASCO (USA), MAC (USA), NUMATICS (USA), PARKER (USA), VICKERS (USA), ROSS (USA), Norgren (UK), OMAL (Italy), ATOS (Italy), CAMOZZI (Italy), UNIVER (Italy), and Camozzi (Italy).
