This module continues the exploration of transistor applications, offering deeper insights into their use in advanced circuits. Key areas include:
Students will enhance their understanding of how transistors can be integrated into sophisticated designs for improved functionality.
This module focuses on the principles of transistor amplifiers, discussing their operation, configurations, and applications. Students will learn about:
By the end of this module, students will have a solid understanding of how to design and analyze transistor amplifier circuits.
This module delves into transistor operational amplifiers (op-amps) and voltage regulators. Key topics include:
Students will learn to design robust voltage regulators using op-amps, enhancing their understanding of linear circuit applications.
This module presents various applications of transistors, focusing on their role in circuit design. Topics covered include:
Students will gain insights into the versatility of transistors and how they can be applied in innovative ways.
This module continues the exploration of transistor applications, offering deeper insights into their use in advanced circuits. Key areas include:
Students will enhance their understanding of how transistors can be integrated into sophisticated designs for improved functionality.
This module focuses on transformer design and heat sink design, essential for managing power in circuits. Key topics include:
Students will learn to design transformers and heat sinks, ensuring efficient power management in their projects.
This module covers op-amp based linear voltage regulators, emphasizing their design and application. Key points include:
Students will learn how to implement op-amp based voltage regulators in various applications.
This module addresses short circuit protection in linear power supplies, a critical aspect of circuit design. Topics include:
Students will learn to design robust circuits that safeguard against short circuit conditions.
This module explores the design of temperature indicator circuits using op-amps. Key concepts include:
Students will learn to design effective temperature indicator circuits for various applications.
This module covers the design of on/off temperature controllers. Topics include:
Students will learn how to implement on/off temperature control systems effectively.
This module focuses on the design of proportional temperature controllers. Key areas include:
Students will gain insights into effectively designing proportional temperature control systems.
This module covers the design of PID (Proportional-Integral-Derivative) temperature controllers, emphasizing their advantages. Topics include:
Students will learn to design and implement effective PID controllers for precise temperature control.
This module examines heater drive circuits for various temperature controllers. Key topics include:
Students will learn to design heater drive circuits that effectively respond to temperature control requirements.
This module focuses on short circuit protection of power MOSFETs, an essential aspect of power management. Key topics include:
Students will learn to design robust circuits that protect MOSFETs from short circuit conditions.
This module covers error budgeting for temperature indicators, emphasizing the importance of accuracy. Topics include:
Students will learn to implement effective error budgeting techniques for accurate temperature indicators.
This module addresses PID temperature controllers with a focus on error budgeting. Key areas include:
Students will learn to design effective PID controllers that incorporate error management techniques.
This module focuses on error budgeting for constant current sources, emphasizing their significance in circuit design. Topics include:
Students will learn how to implement effective error budgeting in constant current source designs.
This module addresses error budgeting for thermocouple amplifiers, emphasizing their role in accurate temperature measurement. Key topics include:
Students will learn to design thermocouple amplifiers with effective error budgeting techniques.
This module focuses on error budgeting for op-amp circuits, crucial for circuit accuracy. Topics include:
Students will learn to implement effective error budgeting strategies for op-amp circuit designs.
This module addresses gain error calculation in op-amp circuits, a vital aspect of circuit design. Key topics include:
Students will learn how to effectively calculate and manage gain errors in op-amp circuits.
This module focuses on input resistance calculations for op-amps, essential for circuit analysis. Key areas include:
Students will learn to accurately calculate input resistance and understand its significance in op-amp designs.
This module addresses output resistance calculations for op-amps, crucial for understanding circuit behavior. Topics include:
Students will learn to calculate output resistance and assess its effects on circuit performance.
This module covers error budgeting for different circuits, emphasizing the importance of accuracy in circuit design. Key topics include:
Students will learn to implement error budgeting techniques tailored to different circuit types.
This module focuses on the design of a 4-20 mA current transmitter, crucial for industrial applications. Key concepts include:
Students will learn to design effective current transmitters for accurate measurement in industrial settings.
This module covers error budgeting for 4-20 mA current transmitters, emphasizing accuracy in industrial applications. Key areas include:
Students will learn effective techniques for implementing error budgeting in current transmitter designs.
This module explores LVDT (Linear Variable Differential Transformer) based current transmitters, focusing on their design and application. Key topics include:
Students will learn to design LVDT based current transmitters for precise measurement applications.
This module focuses on the design of constant current sources, essential for various applications in electronics. Key concepts include:
Students will learn to design robust constant current sources for diverse electronic applications.
This module covers the design of a 4-20 mA based temperature transmitter, crucial for accurate temperature measurement in industrial settings. Key topics include:
Students will learn to design effective temperature transmitters for reliable industrial applications.
This module explores the design of 3-wire current transmitters, emphasizing their application in temperature measurement. Key areas include:
Students will learn to design robust 3-wire current transmitters for accurate temperature measurements.
This module focuses on various resistance measurement techniques, essential for accurate electrical measurements. Key topics include:
Students will learn effective resistance measurement techniques applicable in a variety of electronic contexts.
This module covers the ratio transformer technique for measuring resistance and capacitance, emphasizing its applications. Key areas include:
Students will learn how to implement ratio transformer techniques for effective measurement in electronic systems.
This module discusses capacitive sensor circuit design examples, emphasizing practical implementations. Key topics include:
Students will learn to design effective capacitive sensor circuits suitable for various applications.
This module focuses on capacitive sensor circuits with high impedance amplifiers, essential for accurate measurements. Key areas include:
Students will learn to design high impedance capacitive sensor circuits for precise measurement applications.
This module covers AC applications of op-amps and the design of lock-in amplifiers, focusing on their use in signal processing. Key topics include:
Students will learn to design effective lock-in amplifiers for accurate signal processing in AC applications.
This module discusses the design of lock-in amplifier circuits, providing hands-on examples and practical insights. Key areas include:
Students will learn to design and implement lock-in amplifiers for precise measurement applications.
This module focuses on dual slope ADC design examples, emphasizing their application in data conversion. Key topics include:
Students will learn to design effective dual slope ADCs for accurate data conversion.
This module discusses dual slope ADC and successive approximation ADC principles, comparing their performance and applications. Key areas include:
Students will learn to choose and design appropriate ADCs based on application requirements.
This module focuses on MC-based ADCs, emphasizing their design and applications in modern electronics. Key topics include:
Students will learn to design effective MC-based ADCs for various electronic applications.
This module explores digital-to-analog converter (DAC) design and operation, emphasizing their crucial role in signal processing. Key areas include:
Students will learn to design effective DACs for diverse electronic applications.
This module covers flash ADC design and the associated errors, focusing on their applications in high-speed data conversion. Key topics include:
Students will learn to design effective flash ADCs that minimize errors for accurate data conversion.
This module explores sigma-delta ADC working principles, focusing on their advantages in data conversion. Key topics include:
Students will learn to design effective sigma-delta ADCs for various applications requiring high precision.