Hall Effect
... 5. Turn on the magnet power supply. Increase voltage to 20v. The current has been set to protect the magnet. Do not use the current controls. Turn the voltage to zero before turning off magnet power supply. Each time you turn on the magnet power supply set the voltage to 20v. Insert probe tip betwee ...
... 5. Turn on the magnet power supply. Increase voltage to 20v. The current has been set to protect the magnet. Do not use the current controls. Turn the voltage to zero before turning off magnet power supply. Each time you turn on the magnet power supply set the voltage to 20v. Insert probe tip betwee ...
Electricity
... the circuit from question five and six from the parallel circuit work sheet. Measure the voltage, resistance, and current in the circuit. Compare the worksheet values to the simulations values and summarize your findings using academic vocabulary (measuring devices, voltage, resistance, current, ...
... the circuit from question five and six from the parallel circuit work sheet. Measure the voltage, resistance, and current in the circuit. Compare the worksheet values to the simulations values and summarize your findings using academic vocabulary (measuring devices, voltage, resistance, current, ...
Electronics Lab Intro (Lab#0) Introduction Procedure Part I. Ohm`s
... Electronics Lab Intro (Lab#0) Introduction The main purpose of this lab is to familiarize you with some of the equipment used for the electronics labs, while investigating Ohm’s Law and Resistive-Capacitive (RC) circuits. Recall that Ohm’s Law states that the electrical current through a circuit com ...
... Electronics Lab Intro (Lab#0) Introduction The main purpose of this lab is to familiarize you with some of the equipment used for the electronics labs, while investigating Ohm’s Law and Resistive-Capacitive (RC) circuits. Recall that Ohm’s Law states that the electrical current through a circuit com ...
AP_Physics_C_-_ohmslaw_Lab
... -Make sure your red wire is inserted into the VmA port at the moment. 5. Measure and record the voltage ACROSS the 2 resistor springs and record this value. The red probe should be use to measure the voltage coming from the POSITIVE end of the battery. The black probe is for the NEGATIVE end. 6. Se ...
... -Make sure your red wire is inserted into the VmA port at the moment. 5. Measure and record the voltage ACROSS the 2 resistor springs and record this value. The red probe should be use to measure the voltage coming from the POSITIVE end of the battery. The black probe is for the NEGATIVE end. 6. Se ...
ECE 323L Basic Electronics Circuits Laboratory
... a) Measure source voltage on oscilloscope with probes between A and B. Measure load voltage with probes between C and D. Do not attempt to measure both signals on the oscilloscope at the same time, the oscilloscope channels share a common ground and trying to make simultaneous measurements will intr ...
... a) Measure source voltage on oscilloscope with probes between A and B. Measure load voltage with probes between C and D. Do not attempt to measure both signals on the oscilloscope at the same time, the oscilloscope channels share a common ground and trying to make simultaneous measurements will intr ...
Elecrtonics_L1
... 2. Relay Electrically operated switch Coil of wire and a metal lever which changes the position of the switch. Advantage - permits a low voltage DC circuit to control a completely separate high-power circuit ...
... 2. Relay Electrically operated switch Coil of wire and a metal lever which changes the position of the switch. Advantage - permits a low voltage DC circuit to control a completely separate high-power circuit ...
25-Supercond
... probe actually has 6 wires). First connect the red and blue thermocouple leads to a digital voltmeter set on the mV scale and check that the digital voltmeter is giving a reading. [The table in the back of this lab will let you convert between the potential difference across the thermocouple and the ...
... probe actually has 6 wires). First connect the red and blue thermocouple leads to a digital voltmeter set on the mV scale and check that the digital voltmeter is giving a reading. [The table in the back of this lab will let you convert between the potential difference across the thermocouple and the ...
AP_Physics_C_-_ohmslaw_Lab_II
... 3. Measure and record the voltage ACROSS R1 and the current THROUGH R1. 4. Repeat step #3 by lowering the voltage on the power supply by 3 volts. Note: You still need to measure the voltage ACROSS R1. Repeat #4 for a range of 20V – 5 V. Make a graph with voltage on the y-axis and current on the x-ax ...
... 3. Measure and record the voltage ACROSS R1 and the current THROUGH R1. 4. Repeat step #3 by lowering the voltage on the power supply by 3 volts. Note: You still need to measure the voltage ACROSS R1. Repeat #4 for a range of 20V – 5 V. Make a graph with voltage on the y-axis and current on the x-ax ...
Written - Rose
... So v4 : v3 2 : 1 , which is consistent with the specification given before. Also we can verify the result using the current divider, which is a parallel-connected resistance circuit. The two resistors can be combine into a since they are in series. For the parallel circuit, the current through one ...
... So v4 : v3 2 : 1 , which is consistent with the specification given before. Also we can verify the result using the current divider, which is a parallel-connected resistance circuit. The two resistors can be combine into a since they are in series. For the parallel circuit, the current through one ...
Home Work Solutions 11
... impedance Z of the circuit versus the driving angular frequency ωd; the curve reaches an asymptote of 500 Ω, and the horizontal scale is set by ωds = 300 rad/s. The figure also gives the reactance XC for the capacitor versus ωd. What are (a) R and (b) C? ...
... impedance Z of the circuit versus the driving angular frequency ωd; the curve reaches an asymptote of 500 Ω, and the horizontal scale is set by ωds = 300 rad/s. The figure also gives the reactance XC for the capacitor versus ωd. What are (a) R and (b) C? ...
44407DesignProject
... 1. Mathematica Design File: A file including all steps of the design procedure used, i.e. starting from a set of design specifications, and using, in a logical sequence, design equations, assumptions, approximations and calculations leading to the choises made of all transistor and capacitor W/L rat ...
... 1. Mathematica Design File: A file including all steps of the design procedure used, i.e. starting from a set of design specifications, and using, in a logical sequence, design equations, assumptions, approximations and calculations leading to the choises made of all transistor and capacitor W/L rat ...
Equations - Humble ISD
... An AC transmission line transfers energy at the rate Pavg = 5.0 MW from a generating plant to a factory. a) What current irms is present in the line if the transmission voltage Vrms is 120 V? b) If Vrms = 80 kV? c) What is the ratio of the thermal (Joule) energy losses in the line for these two case ...
... An AC transmission line transfers energy at the rate Pavg = 5.0 MW from a generating plant to a factory. a) What current irms is present in the line if the transmission voltage Vrms is 120 V? b) If Vrms = 80 kV? c) What is the ratio of the thermal (Joule) energy losses in the line for these two case ...
Building Curcuits From Schematics
... Optoelectronic Diodes or Light Emitting Diodes (LEDs) – emit photons ...
... Optoelectronic Diodes or Light Emitting Diodes (LEDs) – emit photons ...
Capacitors and RC circuits
... fully charged flip the switch so that it discharges. Let it (almost) fully discharge and stop the simulation. Expand the oscilloscope and adjust the time base and number of volts per division so that most of the charging curve can be seen as shown below. Adjust the cyan (1) and yellow (2) cursors su ...
... fully charged flip the switch so that it discharges. Let it (almost) fully discharge and stop the simulation. Expand the oscilloscope and adjust the time base and number of volts per division so that most of the charging curve can be seen as shown below. Adjust the cyan (1) and yellow (2) cursors su ...
Summary of Series and Parallel Circuits
... to a series circuit is equal to the total number of individual voltage drops in the series circuit. VT = sum of all voltage drops. ...
... to a series circuit is equal to the total number of individual voltage drops in the series circuit. VT = sum of all voltage drops. ...
Test probe
A test probe (test lead, test prod, or scope probe) is a physical device used to connect electronic test equipment to a device under test (DUT). They range from very simple, robust devices to complex probes that are sophisticated, expensive, and fragile.