Electricity ppt 2 File
... The conventional current direction is from + to – and describes the flow f positive charge. This was before the electron was discovered and scientists realised that positive charge did not flow round circuits • Defined as a flow of charge (Q) • Measured in Amperes/Amps • Current measured using an am ...
... The conventional current direction is from + to – and describes the flow f positive charge. This was before the electron was discovered and scientists realised that positive charge did not flow round circuits • Defined as a flow of charge (Q) • Measured in Amperes/Amps • Current measured using an am ...
Addendum to kWh Meter Installation Instructions For Use - E-Mon
... the 0~5 amp signal, the Current Sensors are installed on the CT secondary lead. A set of 25 amp sensors is used in this application. These sensors have the high voltage CT secondary lead passed through them five (5) times by looping the wire as shown in the drawing. This allows a direct conversion o ...
... the 0~5 amp signal, the Current Sensors are installed on the CT secondary lead. A set of 25 amp sensors is used in this application. These sensors have the high voltage CT secondary lead passed through them five (5) times by looping the wire as shown in the drawing. This allows a direct conversion o ...
FINAL_PROJECT_PRESENTATION
... [1] Woogeun Rhee, “Design of High – Performance CMOS Charge Pumps in Phase – locked loops.” [2] Dong – Keon Lee, Jeong – Kwang Lee, and Hang – Geun Jeong, “A Dual – Compensated Charge Pump with Reduced Current Mismatch” [3] M.-S. Hwang, J. Kim and D.-K. Jeong, “Reduction of pump current mismatch in ...
... [1] Woogeun Rhee, “Design of High – Performance CMOS Charge Pumps in Phase – locked loops.” [2] Dong – Keon Lee, Jeong – Kwang Lee, and Hang – Geun Jeong, “A Dual – Compensated Charge Pump with Reduced Current Mismatch” [3] M.-S. Hwang, J. Kim and D.-K. Jeong, “Reduction of pump current mismatch in ...
electronic devices and circuits
... respect to the emitter and _____ with respect to the collector. 30. A transistor amplifier has a voltage gain of 100. If the input voltage is 75 mV, the output voltage is: 31. A 35 mV signal is applied to the base of a properly biased transistor with an r'e = 8 Ω and RC = 1 kΩ. The output signal vol ...
... respect to the emitter and _____ with respect to the collector. 30. A transistor amplifier has a voltage gain of 100. If the input voltage is 75 mV, the output voltage is: 31. A 35 mV signal is applied to the base of a properly biased transistor with an r'e = 8 Ω and RC = 1 kΩ. The output signal vol ...
living with the lab - Louisiana Tech University
... Any procedures demonstrated here are potentially dangerous and could result in injury or damage. Louisiana Tech University and the State of Louisiana, their officers, employees, agents or volunteers, are not liable or responsible for any injuries, illness, damage or losses which may result from your ...
... Any procedures demonstrated here are potentially dangerous and could result in injury or damage. Louisiana Tech University and the State of Louisiana, their officers, employees, agents or volunteers, are not liable or responsible for any injuries, illness, damage or losses which may result from your ...
Using equivalence resistance to calculate current
... A motor is connected in series with a 10 Ω resistor and a 12 V power supply as shown above. If the current in the circuit is 0.5 A, find the power consumed by the motor. A. ...
... A motor is connected in series with a 10 Ω resistor and a 12 V power supply as shown above. If the current in the circuit is 0.5 A, find the power consumed by the motor. A. ...
1. What is the voltage across the 20Ω resistor? a. 0 V b. 2 V c. 3 V d
... photodiode operates in which quadrant of the IV characteristic curve (shown at the bottom of the page)? Assume that the reverse bias current is less than 100 O and the turn on voltage is less than 1 V. a. Quadrant A delivering (sourcing) power. b. Quadrant B delivering (sourcing) power. c. Quadrant ...
... photodiode operates in which quadrant of the IV characteristic curve (shown at the bottom of the page)? Assume that the reverse bias current is less than 100 O and the turn on voltage is less than 1 V. a. Quadrant A delivering (sourcing) power. b. Quadrant B delivering (sourcing) power. c. Quadrant ...
Assignemnts
... 9. A resistance R=10Ω and inductive reactance XL=5Ω are connected in series across 100V, 50Hz supply. Find Z, I, pf, P, Q, apparent power and complex power. Z=10+j5Ω (11.8Ω, angle 26.560) I=8-j4A Pf=0.894 lag P=800W, Q=400VAr, S=894VA, complex power = (800+j400) VA 10. Impedances of two parallel bra ...
... 9. A resistance R=10Ω and inductive reactance XL=5Ω are connected in series across 100V, 50Hz supply. Find Z, I, pf, P, Q, apparent power and complex power. Z=10+j5Ω (11.8Ω, angle 26.560) I=8-j4A Pf=0.894 lag P=800W, Q=400VAr, S=894VA, complex power = (800+j400) VA 10. Impedances of two parallel bra ...
A Novel Bi-directional Series Parallel Resonant Converter for Power
... hard-switching DC/DC converters. However, it seems the limits of this technique have been reached. Switching frequencies of few kilohertz for high power applications are possible. For further increase of switching frequency up to 100 KHz and reduction of electro magnetic interference, resonant conve ...
... hard-switching DC/DC converters. However, it seems the limits of this technique have been reached. Switching frequencies of few kilohertz for high power applications are possible. For further increase of switching frequency up to 100 KHz and reduction of electro magnetic interference, resonant conve ...
Electricity2
... Sometimes you need a kind of resistor, but you don't have it on hand and it doesn't exist. Fortunately, it's possible to use several different resistors in combination to get virtually any level of resistance, for example if you have 2 resistor of 20 Ohm and you need a resistor of 40 Ohm, just add b ...
... Sometimes you need a kind of resistor, but you don't have it on hand and it doesn't exist. Fortunately, it's possible to use several different resistors in combination to get virtually any level of resistance, for example if you have 2 resistor of 20 Ohm and you need a resistor of 40 Ohm, just add b ...
G:\respcare\gen_care
... resistance are used as insulation. Electrical resistance is measured in ohms. List and discuss the 3 factors that determine the effect of an electrical shock on the body. Identify the most important one. a. Current is the most important factor b. Voltage is the amount of current applied to the body ...
... resistance are used as insulation. Electrical resistance is measured in ohms. List and discuss the 3 factors that determine the effect of an electrical shock on the body. Identify the most important one. a. Current is the most important factor b. Voltage is the amount of current applied to the body ...
CURRENT, RESISTANCE, AND ELECTROMOTIVE FORCE
... (For comparison, the internal resistance of a commercial 12-V lead storage battery is only a few thousandths of an ohm). The wires to the left of a and to the right of the ammeter A are not connected to anything. Determine the readings of the idealized voltmeter V and the idealized ammeter A. ...
... (For comparison, the internal resistance of a commercial 12-V lead storage battery is only a few thousandths of an ohm). The wires to the left of a and to the right of the ammeter A are not connected to anything. Determine the readings of the idealized voltmeter V and the idealized ammeter A. ...
electronics electronics
... material, this can mean that electrons are flowing from a negatively charged area to a positively charged one, such as in a metal, or that positively charge ions are flowing from a positively charged area to a negatively charged one, or that both positively and negatively charged particles are flowi ...
... material, this can mean that electrons are flowing from a negatively charged area to a positively charged one, such as in a metal, or that positively charge ions are flowing from a positively charged area to a negatively charged one, or that both positively and negatively charged particles are flowi ...
Hewitt/Lyons/Suchocki/Yeh, Conceptual Integrated Science
... You are a resistor!! • The human body has a resistance, which depends on the exact path through your body, and whether your hands are wet or dry. • If your hands are moist, the resistance between them can be as low as 500 Ω • So if there is a voltage of 120 V between your hands, this will set up a ...
... You are a resistor!! • The human body has a resistance, which depends on the exact path through your body, and whether your hands are wet or dry. • If your hands are moist, the resistance between them can be as low as 500 Ω • So if there is a voltage of 120 V between your hands, this will set up a ...
MAX218 1.8V to 4.25V-Powered, True RS-232 Dual Transceiver _______________General Description
... CMOS receiver outputs swing rail-to-rail. When EN is high, ———–the receivers are active regardless of the state of SHDN. When EN is low, the receiver outputs are put into a high-impedance state. This allows two RS-232 ports (or two ports of different types) to be wired-ORed at the UART. ...
... CMOS receiver outputs swing rail-to-rail. When EN is high, ———–the receivers are active regardless of the state of SHDN. When EN is low, the receiver outputs are put into a high-impedance state. This allows two RS-232 ports (or two ports of different types) to be wired-ORed at the UART. ...
CMOS
Complementary metal–oxide–semiconductor (CMOS) /ˈsiːmɒs/ is a technology for constructing integrated circuits. CMOS technology is used in microprocessors, microcontrollers, static RAM, and other digital logic circuits. CMOS technology is also used for several analog circuits such as image sensors (CMOS sensor), data converters, and highly integrated transceivers for many types of communication. In 1963, while working for Fairchild Semiconductor, Frank Wanlass patented CMOS (US patent 3,356,858).CMOS is also sometimes referred to as complementary-symmetry metal–oxide–semiconductor (or COS-MOS).The words ""complementary-symmetry"" refer to the fact that the typical design style with CMOS uses complementary and symmetrical pairs of p-type and n-type metal oxide semiconductor field effect transistors (MOSFETs) for logic functions.Two important characteristics of CMOS devices are high noise immunity and low static power consumption.Since one transistor of the pair is always off, the series combination draws significant power only momentarily during switching between on and off states. Consequently, CMOS devices do not produce as much waste heat as other forms of logic, for example transistor–transistor logic (TTL) or NMOS logic, which normally have some standing current even when not changing state. CMOS also allows a high density of logic functions on a chip. It was primarily for this reason that CMOS became the most used technology to be implemented in VLSI chips.The phrase ""metal–oxide–semiconductor"" is a reference to the physical structure of certain field-effect transistors, having a metal gate electrode placed on top of an oxide insulator, which in turn is on top of a semiconductor material. Aluminium was once used but now the material is polysilicon. Other metal gates have made a comeback with the advent of high-k dielectric materials in the CMOS process, as announced by IBM and Intel for the 45 nanometer node and beyond.