Ph 77 — ADVANCED PHYSICS LABORATORY
... and 60/120-Hz signals coming from ambient lights, provided these sources don’t swamp either the detector or the lock-in (both will have limited dynamic range). You could always carefully shield your detector from ambient light, of course, but in practice it’s usually much less effort to use a lock-i ...
... and 60/120-Hz signals coming from ambient lights, provided these sources don’t swamp either the detector or the lock-in (both will have limited dynamic range). You could always carefully shield your detector from ambient light, of course, but in practice it’s usually much less effort to use a lock-i ...
Owner`s Manual
... Please check the fuses , If they are blown, please replace with new one. Please check whether speakers work well, you can test speakers by connecting to another amplifier PROTECTION Please check overload, overheat ( thermal ), short and voltage, DC offset. Digital monoblock amplifiers ( APK-2500, AP ...
... Please check the fuses , If they are blown, please replace with new one. Please check whether speakers work well, you can test speakers by connecting to another amplifier PROTECTION Please check overload, overheat ( thermal ), short and voltage, DC offset. Digital monoblock amplifiers ( APK-2500, AP ...
modified_version_3
... experiment are the temperature of the sample, the voltage waveform applied on the sample, the capacitance of the sample and its loss factor. Through analyzing these parameters, the sample could be determined its failure. The voltage waveform and temperature signal are monitored online. The pulse vol ...
... experiment are the temperature of the sample, the voltage waveform applied on the sample, the capacitance of the sample and its loss factor. Through analyzing these parameters, the sample could be determined its failure. The voltage waveform and temperature signal are monitored online. The pulse vol ...
OPA365 - Texas Instruments
... One technique for increasing the capacitive load drive capability of the amplifier operating in unity gain is to insert a small resistor, typically 10Ω to 20Ω, in series with the output; see Figure 6. This resistor significantly reduces the overshoot and ringing associated with large capacitive load ...
... One technique for increasing the capacitive load drive capability of the amplifier operating in unity gain is to insert a small resistor, typically 10Ω to 20Ω, in series with the output; see Figure 6. This resistor significantly reduces the overshoot and ringing associated with large capacitive load ...
chapter2 - e-LEARNING
... The amount of noise in the signal is reduced because SSB occupy narrower bandwidth. Less fading over a long distances. ...
... The amount of noise in the signal is reduced because SSB occupy narrower bandwidth. Less fading over a long distances. ...
Page 43, Foundation Electronics, Kemp
... For each of the specifications below draw out the Karnaugh map and produce a circuit using NAND gates only to satisfy requirements. 30. The shuttle has a voting system whereby 3 computers vote on what to do. The final decision always goes with the majority so that if one computer goes down the other ...
... For each of the specifications below draw out the Karnaugh map and produce a circuit using NAND gates only to satisfy requirements. 30. The shuttle has a voting system whereby 3 computers vote on what to do. The final decision always goes with the majority so that if one computer goes down the other ...
Analog Input Buffer Architectures
... C is the value of the capacitor (in Farads) In the input buffer shown in Figure 2, R = 10 kΩ and C = 10 µF. This places the 3 dB corner at approximately 1.59 Hz. Typically, this corner should be at least one decade below the bandwidth of interest in order to prevent a significant droop in the freque ...
... C is the value of the capacitor (in Farads) In the input buffer shown in Figure 2, R = 10 kΩ and C = 10 µF. This places the 3 dB corner at approximately 1.59 Hz. Typically, this corner should be at least one decade below the bandwidth of interest in order to prevent a significant droop in the freque ...
MAX1178/MAX1188 16-Bit, 135ksps, Single-Supply ADCs with Bipolar Analog Input Range General Description
... The MAX1178/MAX1188 have an input scaler, which allows conversion of true bipolar input voltages and input voltages greater than the power supply, while operating from a single +5V analog supply. The input scaler attenuates and shifts the analog input to match the input range of the internal digital ...
... The MAX1178/MAX1188 have an input scaler, which allows conversion of true bipolar input voltages and input voltages greater than the power supply, while operating from a single +5V analog supply. The input scaler attenuates and shifts the analog input to match the input range of the internal digital ...
Seven Segment Displays
... Resistor Values for SSD • The resistor value determines the amount of current that is flowing through the LED in the SSD. • This is why they are sometimes called current limiting resistors. • The amount of current determines how luminous (bright) the LED will be. • If the resistor is too large, the ...
... Resistor Values for SSD • The resistor value determines the amount of current that is flowing through the LED in the SSD. • This is why they are sometimes called current limiting resistors. • The amount of current determines how luminous (bright) the LED will be. • If the resistor is too large, the ...
MAX1182 Dual 10-Bit, 65Msps, 3V, Low-Power ADC General Description
... The MAX1182 is a 3V, dual 10-bit analog-to-digital converter (ADC) featuring fully-differential wideband trackand-hold (T/H) inputs, driving two pipelined, 9-stage ADCs. The MAX1182 is optimized for low-power, highdynamic performance applications in imaging, instrumentation and digital communication ...
... The MAX1182 is a 3V, dual 10-bit analog-to-digital converter (ADC) featuring fully-differential wideband trackand-hold (T/H) inputs, driving two pipelined, 9-stage ADCs. The MAX1182 is optimized for low-power, highdynamic performance applications in imaging, instrumentation and digital communication ...
TDA8358J Full bridge vertical deflection output circuit in LVDMOS
... voltage VFB. The principle of two supply voltages (class G) allows to use an optimum supply voltage VP for scan and an optimum flyback supply voltage VFB for flyback, thus very high efficiency is achieved. The available flyback output voltage across the coil is almost equal to VFB, due to the absenc ...
... voltage VFB. The principle of two supply voltages (class G) allows to use an optimum supply voltage VP for scan and an optimum flyback supply voltage VFB for flyback, thus very high efficiency is achieved. The available flyback output voltage across the coil is almost equal to VFB, due to the absenc ...
Electrotest-EIS-W - capacitively coupled resistivity meter
... • input capacity: ≤ 10 pF • input signal range: 0,5 mV to 2V • bandwidth: not more then 15 Hz • resolution of the meter: 0.1 mV • measurement accuracy: 1 2 % • built-in microcontroller with LCD or LED character indicators indicator 16x2 • operating temperature range: - 40...+70C • dimensions: 305x ...
... • input capacity: ≤ 10 pF • input signal range: 0,5 mV to 2V • bandwidth: not more then 15 Hz • resolution of the meter: 0.1 mV • measurement accuracy: 1 2 % • built-in microcontroller with LCD or LED character indicators indicator 16x2 • operating temperature range: - 40...+70C • dimensions: 305x ...
LT1711/LT1712 - Single/Dual 4.5ns, 3V/5V/±5V, Rail-to-Rail Comparators
... latch when a flow-through condition is desired. The latch pin is designed to be driven with either a TTL or CMOS output. It has built-in hysteresis of approximately 100mV, so that slow moving or noisy input signals do not impact latch performance. For the LT1712, if only one of the comparators is be ...
... latch when a flow-through condition is desired. The latch pin is designed to be driven with either a TTL or CMOS output. It has built-in hysteresis of approximately 100mV, so that slow moving or noisy input signals do not impact latch performance. For the LT1712, if only one of the comparators is be ...
circuit models of sensory transduction in the cochlea
... The resonance peak of the chip response decreases for large-amplitude sinusoids, because the feedback amplifier A3 in the second-order sections saturates. The resonance peak in a physiological cochlea also decreases for largeamplitude inputs (Rhode, 1971). The silicon and physiological cochleas may ...
... The resonance peak of the chip response decreases for large-amplitude sinusoids, because the feedback amplifier A3 in the second-order sections saturates. The resonance peak in a physiological cochlea also decreases for largeamplitude inputs (Rhode, 1971). The silicon and physiological cochleas may ...
The Boston University Demo Database
... most popular demonstrations are marked with a double asterisk ** next to their names. Also, some demos must be requested at least a day in advance because they need to be tested and set up so they work properly. These demos are marked with a double caret ^^ next to their names. If a demo has a video ...
... most popular demonstrations are marked with a double asterisk ** next to their names. Also, some demos must be requested at least a day in advance because they need to be tested and set up so they work properly. These demos are marked with a double caret ^^ next to their names. If a demo has a video ...
V OUT - Faculty
... This determines the value of the voltage difference between nodes (connections) A and B. These nodes are wired to the diff amp, the output of which is proportional to the difference voltage. That voltage then drives the display on the scale where a number corresponding to the temperature ...
... This determines the value of the voltage difference between nodes (connections) A and B. These nodes are wired to the diff amp, the output of which is proportional to the difference voltage. That voltage then drives the display on the scale where a number corresponding to the temperature ...
PDF file, 712KB - College of Engineering and Computer Science
... pass corner frequency of the internal offset compensation loop according to the formula fHP (kHz) = 2/CC (µF), where CC is the total capacitance from OFSA or OFSB to ground, including the internal 10 pF (AD8302 data sheet 2002). In this application, CC ≈ 47 µF, so fHP ≈ 43 Hz, which means that theor ...
... pass corner frequency of the internal offset compensation loop according to the formula fHP (kHz) = 2/CC (µF), where CC is the total capacitance from OFSA or OFSB to ground, including the internal 10 pF (AD8302 data sheet 2002). In this application, CC ≈ 47 µF, so fHP ≈ 43 Hz, which means that theor ...
Oscilloscope history
This article discusses the history and development of oscilloscope technology.