Lab 2 Ohms Law
... 1. Connect the experiment as shown. Do not turn on the power for the power supply. 2. Have the instructor or lab supervisor verify your experimental setup. Note the orientation of the resistor – the text should not be upside down. 3. Turn on the power supply and set the current dial straight up. 4. ...
... 1. Connect the experiment as shown. Do not turn on the power for the power supply. 2. Have the instructor or lab supervisor verify your experimental setup. Note the orientation of the resistor – the text should not be upside down. 3. Turn on the power supply and set the current dial straight up. 4. ...
Document
... peak output voltage, vo across the load, R ii. Sketch the output voltage, vo and label its peak value. ...
... peak output voltage, vo across the load, R ii. Sketch the output voltage, vo and label its peak value. ...
A 93% efficiency reconfigurable switched-capacitor DC-
... Figure 21.7.1 shows the top level architecture of the whole power management IC. It consists of reconfigurable switched capacitor DC-DC converter split in four modules (M1-M4) that are interleaved for output voltage ripple reduction [3,4], pulse frequency modulation (PFM) regulation logic, clock gen ...
... Figure 21.7.1 shows the top level architecture of the whole power management IC. It consists of reconfigurable switched capacitor DC-DC converter split in four modules (M1-M4) that are interleaved for output voltage ripple reduction [3,4], pulse frequency modulation (PFM) regulation logic, clock gen ...
instructions for authors - Electrical and Computer Engineering
... successfully used for previous investigations into direct-current saturation [4] and load loss unbalance [5]. The magnetic circuit representing the 5-legged core type is shown in Figure 1. Sources of flux represent primary and secondary windings. Each section of the core is represented by a nonlinea ...
... successfully used for previous investigations into direct-current saturation [4] and load loss unbalance [5]. The magnetic circuit representing the 5-legged core type is shown in Figure 1. Sources of flux represent primary and secondary windings. Each section of the core is represented by a nonlinea ...
Solution Derivations for Capa #7
... This time the total voltage supplied by the EMF is used since we are taking into account that there is internal resistance. In the previous problem, we used the remaining voltage available after the voltage drop across the internal resistor. 4) The picture shows a battery connected to two cylindrica ...
... This time the total voltage supplied by the EMF is used since we are taking into account that there is internal resistance. In the previous problem, we used the remaining voltage available after the voltage drop across the internal resistor. 4) The picture shows a battery connected to two cylindrica ...
Evaluate: MAX1973/MAX1974 MAX1973/MAX1974 Evaluation Kit General Description Features
... or 1.8V, or can be adjusted from 1.25V to VIN by adding external feedback resistors. The output of the MAX1974 circuit (OUT2) is a selectable preset of 1.5V or 1V, or can be adjusted from 0.75V to VIN by adding external feedback resistors. Each output can deliver 1A. The MAX1973 circuit also feature ...
... or 1.8V, or can be adjusted from 1.25V to VIN by adding external feedback resistors. The output of the MAX1974 circuit (OUT2) is a selectable preset of 1.5V or 1V, or can be adjusted from 0.75V to VIN by adding external feedback resistors. Each output can deliver 1A. The MAX1973 circuit also feature ...
FEATURES PIN CONFIGURATION
... output voltage is completely independent of the input common mode voltage. ...
... output voltage is completely independent of the input common mode voltage. ...
FIN1025 3.3V LVDS 2-Bit High Speed Differential Driver
... This dual driver is designed for high speed interconnects utilizing Low Voltage Differential Signaling (LVDS) technology. The driver translates LVTTL signal levels to LVDS levels with a typical differential output swing of 350mV which provides low EMI at ultra low power dissipation even at high freq ...
... This dual driver is designed for high speed interconnects utilizing Low Voltage Differential Signaling (LVDS) technology. The driver translates LVTTL signal levels to LVDS levels with a typical differential output swing of 350mV which provides low EMI at ultra low power dissipation even at high freq ...
Results
... In the first part of this lab, the objective was to study the response of the voltage across a capacitor in an RLC circuit as a function of input. It was shown that the response consisted of a transient and steady state part. The type of transient response was dependent on the resistor used. It was ...
... In the first part of this lab, the objective was to study the response of the voltage across a capacitor in an RLC circuit as a function of input. It was shown that the response consisted of a transient and steady state part. The type of transient response was dependent on the resistor used. It was ...
ENT163 02-08 - UniMAP Portal
... • A circuit – network providing one/ more closed paths. • Branch represents a single elements such as a voltage source or resistor. A branch represents any two-terminal element. • Node is the point of connection between two or more branches. • It usually indicated by a dot in a circuit. • Loop is an ...
... • A circuit – network providing one/ more closed paths. • Branch represents a single elements such as a voltage source or resistor. A branch represents any two-terminal element. • Node is the point of connection between two or more branches. • It usually indicated by a dot in a circuit. • Loop is an ...
EXPERIMENT #2: DC Circuits and Tools
... it delivers power for some amount of time). You will be using the HP3631A to maintain a constant voltage for any circuit connected between the terminals. It is up to you to “dial in” the desired voltage level. We know this is not really an ideal source. If you connect a wire from the positive to the ...
... it delivers power for some amount of time). You will be using the HP3631A to maintain a constant voltage for any circuit connected between the terminals. It is up to you to “dial in” the desired voltage level. We know this is not really an ideal source. If you connect a wire from the positive to the ...
EXPERIMENT #2: DC Circuits and Tools
... it delivers power for some amount of time). You will be using the HP3631A to maintain a constant voltage for any circuit connected between the terminals. It is up to you to “dial in” the desired voltage level. We know this is not really an ideal source. If you connect a wire from the positive to the ...
... it delivers power for some amount of time). You will be using the HP3631A to maintain a constant voltage for any circuit connected between the terminals. It is up to you to “dial in” the desired voltage level. We know this is not really an ideal source. If you connect a wire from the positive to the ...
Combination of Resistors Lab
... 9. Record the voltage drop across each resistor by highlighting each resistor individually, and using the voltage meter selection. Determine the sum of the voltage drops, and compare this with the battery output. 10. Calculate the equivalent resistance, and compare this value to the one that is meas ...
... 9. Record the voltage drop across each resistor by highlighting each resistor individually, and using the voltage meter selection. Determine the sum of the voltage drops, and compare this with the battery output. 10. Calculate the equivalent resistance, and compare this value to the one that is meas ...
Capacitors and Current
... This voltage difference across the capacitor opposes the battery voltage, decreasing the current flow. Once the voltage difference across the capacitor reaches the battery potential, current flow stops. So the increase in potential across the capacitor is proportional to the difference between the b ...
... This voltage difference across the capacitor opposes the battery voltage, decreasing the current flow. Once the voltage difference across the capacitor reaches the battery potential, current flow stops. So the increase in potential across the capacitor is proportional to the difference between the b ...
Mechatronics I Laboratory Exercise 5
... Thus, in order to decrease the impact of the low pass filter on output amplitude, we set the cut-off frequency as high as possible. The trade-off of using a high cutoff frequency is that more noise is permitted to pass the filter. Thus, as a rule of thumb, set the cutoff frequency to at least twice ...
... Thus, in order to decrease the impact of the low pass filter on output amplitude, we set the cut-off frequency as high as possible. The trade-off of using a high cutoff frequency is that more noise is permitted to pass the filter. Thus, as a rule of thumb, set the cutoff frequency to at least twice ...
Design Solutions 10 - Active Voltage Positioning Reduces Output Capacitors
... The transient performance has been improved, while using fewer output capacitors. The optimal amount of AVP offset is equal to ∆I • ESR. Figure 1b exhibits this condition. In instances where the static regulation does not allow this much offset, the result will look like Figure 12. Voltage Mode Cont ...
... The transient performance has been improved, while using fewer output capacitors. The optimal amount of AVP offset is equal to ∆I • ESR. Figure 1b exhibits this condition. In instances where the static regulation does not allow this much offset, the result will look like Figure 12. Voltage Mode Cont ...
Control of Voltage Source Inverter with an LCL Filter without Voltage
... In the wind power system, voltage source inverter (VSI) with an LCL filter (LCL-VSI) is used for better filtering of the grid current [1]-[3]. The resonance of LCL filter often makes the control system unstable. As a solution of this problem, passive damping (PD) or active damping (AD) methods are g ...
... In the wind power system, voltage source inverter (VSI) with an LCL filter (LCL-VSI) is used for better filtering of the grid current [1]-[3]. The resonance of LCL filter often makes the control system unstable. As a solution of this problem, passive damping (PD) or active damping (AD) methods are g ...
Circuit_Concept_Tests
... 1W resistor with current I1 flowing. Then we go through the middle battery (but from + to – !), which gives –4V. Finally, there is a drop through a 2W resistor with current I2. ...
... 1W resistor with current I1 flowing. Then we go through the middle battery (but from + to – !), which gives –4V. Finally, there is a drop through a 2W resistor with current I2. ...
NEW: Read important application notes on page 4 ff.
... Our polycrystalline UV photodiodes are designed for photovoltaic operation. This operation mode is necessary to minimize the dark current of large area photo detectors which otherwise needs to be considered in the commonly used photoconductive mode. First we want to show the implementation of photov ...
... Our polycrystalline UV photodiodes are designed for photovoltaic operation. This operation mode is necessary to minimize the dark current of large area photo detectors which otherwise needs to be considered in the commonly used photoconductive mode. First we want to show the implementation of photov ...
Josephson voltage standard
A Josephson voltage standard is a complex system that uses a superconductive integrated circuit chip operating at 4 K to generate stable voltages that depend only on an applied frequency and fundamental constants. It is an intrinsic standard in the sense that it does not depend on any physical artifact. It is the most accurate method to generate or measure voltage and, by international agreement, is the basis for voltage standards around the World.