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Controlled-Current Coulometry: Overview01:27

Controlled-Current Coulometry: Overview

168
Controlled current coulometry, also known as amperostatic coulometry, is a technique used in electrochemical analysis to measure the quantity of a substance through the controlled passage of current. It involves the application of a constant current to an electrochemical cell containing the analyte of interest. As the current flows through the cell, the analyte undergoes a redox reaction at the electrode surface, resulting in a charge transfer. By monitoring the time required for a certain...
168
Non-ohmic Devices00:51

Non-ohmic Devices

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In most substances, the current flow is proportional to the voltage applied to it. A simple relationship between the values of current, voltage, and resistance is known as Ohm's law. Nonohmic devices do not exhibit a linear relationship between voltage and current. One such device is the semiconducting circuit element known as a diode. A diode is a circuit device that allows current flow in only one direction.
Consider a simple circuit consisting of a battery, a diode, and a resistor. A...
1.0K
Clipper Circuit01:18

Clipper Circuit

354
A clipper circuit is a fundamental wave-shaping device that harnesses the unique properties of diodes to alter and control waveform characteristics. This technology is widely used in electronic devices, especially in television and radar communication systems, where it enhances waveform modulation in both transmitters and receivers.
The operation of a clipper circuit can be exemplified by analyzing a dual-clipper configuration setup that integrates two ideal diodes, each paired with a biasing...
354
Diode: Forward bias01:20

Diode: Forward bias

897
In semiconductor devices, diodes play a crucial role in directing current flow, and its operation is primarily categorized into forward bias and reverse bias. A diode is said to be forward-biased when its p-type region is connected to the positive terminal of a battery and its n-type region is linked to the negative terminal. This configuration reduces the potential barrier within the diode, allowing current to flow easily from the p to the n-type region.
The behavior of a diode in forward bias...
897
Small-signal Diode Model01:18

Small-signal Diode Model

745
In analyzing the behavior of diodes in circuits, the relationship between the current through a diode and the voltage across it is of particular interest, especially when considering the effect of a direct current (DC) bias voltage. When applied, this DC bias influences the diode's operating point, known as the Q point, around which the current-voltage (I-V) characteristic of the diode exhibits exponential behavior. Introducing a small, time-varying signal on top of this bias aids in...
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Ammeter01:11

Ammeter

2.1K
An ammeter is a current measuring instrument. In the circuit, it is represented by the symbol A. The ammeter is placed in series with the device or component to measure the current. A series connection is used because objects in series have the same current passing through them. If a circuit has multiple resistors and the current needs to be measured in each resistor, the number of ammeters required depends on whether the circuit is in series or parallel.
When an ammeter is used to measure the...
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Sensing of Barrier Tissue Disruption with an Organic Electrochemical Transistor
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直流到数字转换器 (DIDC):一个电流传感器.

Saeid Karimpour1, Michael Sekyere1, Isaac Bruce1

  • 1Department of Electrical and Computer Engineering (ECpE), Iowa State University, Ames, IA 50011, USA.

Sensors (Basel, Switzerland)
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概括

本研究介绍了一种用于系统芯片 (SoC) 设计的新型直流数字转换器 (DIDC). 它提供精确,节能的电流测量,减少电力消耗和面积.

关键词:
这是一个ADCADC ADC.这是一个CMOS系统.DIDC DIDC 是一个字符串.这就是为什么SAR SAR SAR.这就是VLSIVLSI.测量过程中的测量.可靠性的可靠性

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科学领域:

  • 电气工程 电气工程
  • 集成电路设计 集成电路设计
  • 半导体技术 半导体技术

背景情况:

  • 系统芯片 (SoC) 设计中的传统电流测量面临的局限性包括高功耗,大面积和依赖中间模拟信号.
  • 现有的方法通常需要复杂的校准,并且没有针对现代,紧的半导体技术进行优化.

研究的目的:

  • 引入一个系统的设计直流到数字转换器 (DIDC),克服了 SoC 中传统电流测量技术的局限性.
  • 为了实现先进的半导体应用,精确,节能和面积优化的电流传感.

主要方法:

  • 拟议的DIDC使用cascode拓中的当前镜子来进行当前管理.
  • 连续近似注册 (SAR) 逻辑用于控制多个二进制大小的电流分支,以进行精确的测量.
  • 整合了一个简单的比较器和隔离电路,以实现准确的传感.

主要成果:

  • 制造出来的DIDC (TSMC 180nm) 在没有非线性校准的情况下达到8位精度.
  • 显示出显著的能量效率,每次转换1.52 pJ的能量和117 μW的功耗.
  • 实现了0.016mm2的紧芯片面积,显著减少了足迹.

结论:

  • 开发的DIDC为下一代半导体技术的当前测量提供了可扩展和高效的解决方案.
  • 在标准操作和现场条件下实现在线测量,提高SoC的性能和可靠性.
  • 代表了在集成电流传感解决方案中减少功率和面积的有希望的进步.