P10
... of which is usually connected to the ground node.) In a linear amplifier, the output signal = A X input signal, where A is the amplification factor or “gain.” Depending on the nature of the input and output signals, one can single out four general types of amplifier gain: voltage gain (voltage out / ...
... of which is usually connected to the ground node.) In a linear amplifier, the output signal = A X input signal, where A is the amplification factor or “gain.” Depending on the nature of the input and output signals, one can single out four general types of amplifier gain: voltage gain (voltage out / ...
NTUST-EE-2013S
... The purpose of the circuit is to store the maximum positive value of a voltage on a capacitor and hold the value for a certain time. The op-amp is set up as a comparator. If Vin > VC , the diode is forward biased and charges to the peak of Vin. For example if a 1.0 Vpp sine wave is the input, the ou ...
... The purpose of the circuit is to store the maximum positive value of a voltage on a capacitor and hold the value for a certain time. The op-amp is set up as a comparator. If Vin > VC , the diode is forward biased and charges to the peak of Vin. For example if a 1.0 Vpp sine wave is the input, the ou ...
ULTRA SLIMPAK G448-0002 ® Bridge Input Field Configurable Isolator
... systems from ground faults and provides filtering for noise reduction which can be a significant problem with small, millivolt, bridge signals. Wide ranging flexibility allows the user to easily zero out dead-loads in weighing systems or configure bipolar input ranges for expansion-compression or va ...
... systems from ground faults and provides filtering for noise reduction which can be a significant problem with small, millivolt, bridge signals. Wide ranging flexibility allows the user to easily zero out dead-loads in weighing systems or configure bipolar input ranges for expansion-compression or va ...
HI200-1.pdf
... The switch operation of the HI-200/201 is dependent upon an internally generated switching threshold voltage optimized for ±15V power supplies. The HI-200/201 does not provide the necessary internal switching threshold in a single supply system. Therefore, if single supply operation is required, the ...
... The switch operation of the HI-200/201 is dependent upon an internally generated switching threshold voltage optimized for ±15V power supplies. The HI-200/201 does not provide the necessary internal switching threshold in a single supply system. Therefore, if single supply operation is required, the ...
ADS5204-Q1 数据资料 dataSheet 下载
... D Digital Communications (Baseband Sampling) D Portable Instrumentation D Video Processing ...
... D Digital Communications (Baseband Sampling) D Portable Instrumentation D Video Processing ...
EFL series datasheet
... do not respond to changes in their inputs. The voltage level at the mode pin must not exceed +5.0V at any time. Please contact UltraVolt's customer service department for an analysis of your requirements. Note: If a voltage >0.8V is applied to the mode pin, it must source less than 400uA. Specificat ...
... do not respond to changes in their inputs. The voltage level at the mode pin must not exceed +5.0V at any time. Please contact UltraVolt's customer service department for an analysis of your requirements. Note: If a voltage >0.8V is applied to the mode pin, it must source less than 400uA. Specificat ...
Voltage-to-Frequency and Frequency-to
... output. A pull-up resistor is usually connected to a 5V logic supply to create standard logic-level pulses. It can, however, be connected to any power supply up to +VCC. Output pulses have a constant duration and positive-going during the oneshot period. Current flowing in the open-collector output ...
... output. A pull-up resistor is usually connected to a 5V logic supply to create standard logic-level pulses. It can, however, be connected to any power supply up to +VCC. Output pulses have a constant duration and positive-going during the oneshot period. Current flowing in the open-collector output ...
Bridge-Type Sensor Measurements are Enhanced
... supply. The full-scale output span of the bridge will be anywhere in the range of 14.7 mV to 18.7 mV. Its offset will be between –2 mV and +2 mV. Matching the 5-V full-scale input span of the A/D converter requires gain settings from 134 to 170. With the offset set to 2.5 V, the amplifier output w ...
... supply. The full-scale output span of the bridge will be anywhere in the range of 14.7 mV to 18.7 mV. Its offset will be between –2 mV and +2 mV. Matching the 5-V full-scale input span of the A/D converter requires gain settings from 134 to 170. With the offset set to 2.5 V, the amplifier output w ...
AD571 - TU Chemnitz
... DAC—plus about 0.3%—when a full-scale analog input voltage of 9.990 volts (10 volts—1 LSB) is applied at the input. The input resistor is trimmed in this way so that if a fine trimming potentiometer is inserted in series with the input signal, the input current at the full-scale input voltage can be ...
... DAC—plus about 0.3%—when a full-scale analog input voltage of 9.990 volts (10 volts—1 LSB) is applied at the input. The input resistor is trimmed in this way so that if a fine trimming potentiometer is inserted in series with the input signal, the input current at the full-scale input voltage can be ...
AT84AD001B and AT84AD004B Dual ADC Application Note
... For port E, pins PE3 and PE2 can be left unused (open) but have to be internally configured with pull-ups. Pins PE7, PE6, PE5 and PE4 have to be pulled up to 3.3V via a 3.3 kΩ (or 1 kΩ if the power consumption is not critical) resistor in order to inhibit external interrupts. PE1 and PE0 can be used ...
... For port E, pins PE3 and PE2 can be left unused (open) but have to be internally configured with pull-ups. Pins PE7, PE6, PE5 and PE4 have to be pulled up to 3.3V via a 3.3 kΩ (or 1 kΩ if the power consumption is not critical) resistor in order to inhibit external interrupts. PE1 and PE0 can be used ...
g Accelerometers ADXL278 i
... The signal may saturate anywhere before the filter. For example, if the resonant frequency of the sensor is low, the displacement per unit acceleration is high. The sensor may reach the mechanical limit of travel if the applied acceleration is high enough. This can be remedied by locating the accele ...
... The signal may saturate anywhere before the filter. For example, if the resonant frequency of the sensor is low, the displacement per unit acceleration is high. The sensor may reach the mechanical limit of travel if the applied acceleration is high enough. This can be remedied by locating the accele ...
doc
... Introducing a filter in the system does not only affect the gain, it also affects the phase, introducing sometimes a very significant phase-shift. This phase shift depends also on the order of the filter. A very efficient class of filters in limiting phase shift is Bessel filters (linear relationshi ...
... Introducing a filter in the system does not only affect the gain, it also affects the phase, introducing sometimes a very significant phase-shift. This phase shift depends also on the order of the filter. A very efficient class of filters in limiting phase shift is Bessel filters (linear relationshi ...
Analog-to-digital converter
An analog-to-digital converter (ADC, A/D, or A to D) is a device that converts a continuous physical quantity (usually voltage) to a digital number that represents the quantity's amplitude.The conversion involves quantization of the input, so it necessarily introduces a small amount of error. Furthermore, instead of continuously performing the conversion, an ADC does the conversion periodically, sampling the input. The result is a sequence of digital values that have been converted from a continuous-time and continuous-amplitude analog signal to a discrete-time and discrete-amplitude digital signal.An ADC is defined by its bandwidth (the range of frequencies it can measure) and its signal to noise ratio (how accurately it can measure a signal relative to the noise it introduces). The actual bandwidth of an ADC is characterized primarily by its sampling rate, and to a lesser extent by how it handles errors such as aliasing. The dynamic range of an ADC is influenced by many factors, including the resolution (the number of output levels it can quantize a signal to), linearity and accuracy (how well the quantization levels match the true analog signal) and jitter (small timing errors that introduce additional noise). The dynamic range of an ADC is often summarized in terms of its effective number of bits (ENOB), the number of bits of each measure it returns that are on average not noise. An ideal ADC has an ENOB equal to its resolution. ADCs are chosen to match the bandwidth and required signal to noise ratio of the signal to be quantized. If an ADC operates at a sampling rate greater than twice the bandwidth of the signal, then perfect reconstruction is possible given an ideal ADC and neglecting quantization error. The presence of quantization error limits the dynamic range of even an ideal ADC, however, if the dynamic range of the ADC exceeds that of the input signal, its effects may be neglected resulting in an essentially perfect digital representation of the input signal.An ADC may also provide an isolated measurement such as an electronic device that converts an input analog voltage or current to a digital number proportional to the magnitude of the voltage or current. However, some non-electronic or only partially electronic devices, such as rotary encoders, can also be considered ADCs. The digital output may use different coding schemes. Typically the digital output will be a two's complement binary number that is proportional to the input, but there are other possibilities. An encoder, for example, might output a Gray code.The inverse operation is performed by a digital-to-analog converter (DAC).