Diode Logic

Lab 4 - Simple Op

AD9762 Data Sheet

... Differential current outputs are provided to support singleended or differential applications. Matching between the two current outputs ensures enhanced dynamic performance in a differential output configuration. The current outputs may be tied directly to an output resistor to provide two complemen ...

FXL2TD245

... FXL translators offer an advantage in that either VCC may be powered up first. This benefit derives from the chip design. When either VCC is at 0 volts, outputs are in a HIGH-Impedance state. The control inputs (T/Rn and OE) are designed to track the VCCA supply. A pull-up resistor tying OE to VCCA ...

A Current-Feedback Instrumentation Amplifier With 5 V Offset for

... many electronic systems, and the applicable techniques are as diverse as the applications themselves. Typical applications include: over-current protection, programmable current sources and current integration, or so-called Coulomb counting circuits used to monitor the charge level of a battery. In ...

Mono2Stereo - DaySequerra

INA12x-HT Precision, Low-Power Instrumentation Amplifiers (Rev. F)

The ZEUS MVD Clock and Control System

MAX5889 12-Bit, 600Msps, High-Dynamic-Performance DAC with LVDS Inputs General Description

... The MAX5889 advanced 12-bit, 600Msps, digital-toanalog converter (DAC) meets the demanding performance requirements of signal synthesis applications found in wireless base stations and other communications applications. Operating from 3.3V and 1.8V supplies, the MAX5889 DAC supports update rates of ...

MAX710EVKIT

... The MAX710 evaluation kit (EV kit) is a step-up DC-DC converter with a linear-regulator output. The MAX710 accepts a +1.8V to +11V input and converts it to a 3.3V or 5V output for up to 250mA currents. The EV kit is optimized for battery applications where the input varies above and below the regula ...

ADP1612 数据手册DataSheet 下载

... To prevent input inrush current at startup, connect a capacitor from SS to GND to set the soft start period. When the ADP1612 is in shutdown (SHDN is at GND) or the input voltage is below the 1.65V undervoltage lockout voltage, SS is internally shorted to GND to discharge the soft start capacitor. O ...

1. Digital I/O Types of Digital I/O Boards / Common Applications 3

Feb 2000 Tiny SOT-23 Step-Down Regulator Switches at 1MHz for

WT210/WT230 Digital Power Meters

... Add the accuracy's reading tolerance (three months after calibration) × 0.5 to the accuracy three months after calibration. ...

NEMA

... CN-L15 . . . . . . . . Connector: Dual Row, 30 Pin Edge Conn., 0.156" ctr . . . . . . . . $4 CN-PUSH/UM . . . Connector: Push-on Terminal Block, 120V AC Pwr . . . . . . . . . . $18 CN-PUSH/UM01 . Connector: Push-on Terminal Block, 200-240V AC Pwr . . . . . . $18 CN-PUSH/UM02 . Connector: Push-on Ter ...

Lionel E-Unit 00-0103-00 Theory of Operation

A high-frequency CMOS multi-modulus divider for PLL frequency

Digital Electronics

MAX5877 14-Bit, 250Msps, High-Dynamic-Performance, Dual DAC with LVDS Inputs General Description

... Nominal full-scale current IOUTFS = 32 x IREF. This parameter does not include update-rate-dependent effects of sin(x)/x filtering inherent in the MAX5877. Parameter measured single-ended into a 50Ω termination resistor. Not production tested. Guaranteed by design. No termination resistance between ...

Adjusting and Calibrating Out Offset and Gain Error in a Precision DAC

... At code 0, the output voltage is never exactly what it should be. The deviation from the ideal code 0 voltage is the offset error. Offset errors are normally bipolar and often expressed in a DAC data sheet in terms of millivolts. The gain of a DAC is the slope of the output characteristic. Gain is g ...

MAX3645 +2.97V to +5.5V, 125Mbps to 200Mbps Limiting Amplifier with Loss-of-Signal Detector

... The data inputs have a single-ended input resistance of 4.8kΩ and are internally DC-biased to VCC - 0.87V (see Figure 3). External capacitors are required to AC-couple the data signals. Pattern-dependent jitter is minimized by using coupling capacitor values large enough to pass the lowest frequenci ...

A Compact Low Voltage CMOS Four-Quadrant Analog Multiplier

... using saturated MOSFET in strong inversion is more practical than any other means. Recently, based on a square-law relation of saturated MOSFET, various compact multiplier architectures which are constituted by a circuit cell called a “flipped voltage follower: FVF” [4], have been chronologically pr ...

Precision Full-Wave Rectifier, Dual-Supply

EXERCISES RESONAT CIRCUITS 5.21 The resonant circuit of the

... The instantaneous value of the current, i(t), when the frequency is increased 0,5% with respect the resonant frequency  0. ...

NCP5080 Xenon Photoflash Capacitor Charge with Photo Sense

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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).

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Analog-to-digital converter