July 26 - cloudfront.net
... Ground wire (third wire) is for ____________ (provides path of less resistance) DC and AC current—DC is single ________ and AC alternates direction 60/sec. AC current is the primary type of current used to transfer ___________ from one place to another. _________current is the primary type of curren ...
... Ground wire (third wire) is for ____________ (provides path of less resistance) DC and AC current—DC is single ________ and AC alternates direction 60/sec. AC current is the primary type of current used to transfer ___________ from one place to another. _________current is the primary type of curren ...
Bus-Hold Circuit - Texas Instruments
... If a drift away from the logic level of a maximum of 1 V is permitted, so that the supply current of the affected input stage has not yet risen too sharply (see Figure 2), the bus may remain in an inactive state (3-state) for a maximum of 2 µs. Usually, more than one device is connected to a bus. Wh ...
... If a drift away from the logic level of a maximum of 1 V is permitted, so that the supply current of the affected input stage has not yet risen too sharply (see Figure 2), the bus may remain in an inactive state (3-state) for a maximum of 2 µs. Usually, more than one device is connected to a bus. Wh ...
Zero Transfer Time Ferroresonant UPS
... The PZM9500 Series Zero Transfer Time (ZTT) Ferroresonant UPS is the premier Uninterruptible Power Supplies (UPS) for Cable TV and Broadband communication networks in two-way digital transmission. The PZM9500 Series’ advanced C.V.T. Ferroresonant technology provides the high efficiency regulated AC ...
... The PZM9500 Series Zero Transfer Time (ZTT) Ferroresonant UPS is the premier Uninterruptible Power Supplies (UPS) for Cable TV and Broadband communication networks in two-way digital transmission. The PZM9500 Series’ advanced C.V.T. Ferroresonant technology provides the high efficiency regulated AC ...
DESIGN OF A “7490-LIKE” DECADE
... ahead in performance, if compared with either HCMOS or ALSTTL. The most significant GaAs device is the MESFET (MEtal-Semiconductor Field-Effect Transistor). The full-custom IC design, described in this work, was approached with a bottom-up methodology [2], efficient for low-complexity designs (less ...
... ahead in performance, if compared with either HCMOS or ALSTTL. The most significant GaAs device is the MESFET (MEtal-Semiconductor Field-Effect Transistor). The full-custom IC design, described in this work, was approached with a bottom-up methodology [2], efficient for low-complexity designs (less ...
Section H4: High-Frequency Transistor Models
... So far, we’ve been concentrating on the capacitors that are external to the transistor in an amplifier circuit and provide coupling or bypass functions. These components are treated as series capacitances and determine the low frequency response of the amplifier, which may be found by the method of ...
... So far, we’ve been concentrating on the capacitors that are external to the transistor in an amplifier circuit and provide coupling or bypass functions. These components are treated as series capacitances and determine the low frequency response of the amplifier, which may be found by the method of ...
× 64 pixel dot matrix microdisplay
... driving NMOS device does not exceed the allowable limits as gate oxide breakdown may occur at the overlap of the drain diffusion and the gate conductor. The ratio of the pþ n junction reverse leakage current to the NMOS drain junction reverse leakage currents is therefore important to ensure that th ...
... driving NMOS device does not exceed the allowable limits as gate oxide breakdown may occur at the overlap of the drain diffusion and the gate conductor. The ratio of the pþ n junction reverse leakage current to the NMOS drain junction reverse leakage currents is therefore important to ensure that th ...
Ohm`s law report Sogi_Fuentes
... 3. Construct a graph for each circuit plotting every V(I) point. Look for obvious linear relationships and calculate the slopes of these lines. ...
... 3. Construct a graph for each circuit plotting every V(I) point. Look for obvious linear relationships and calculate the slopes of these lines. ...
1 (Vahid 4.1) Given a timer ... frequency of 10 MHz: (a)Determine ...
... is added, what is the minimum division needed to measure an interval of 100 ms? (Divisions should be in powers of 2). Determine this design’s range and resolution. (d) If instead of a prescaler a second 16-bit up-counter is cascaded as in Figure 4.1 (d), what is the range and resolution of this desi ...
... is added, what is the minimum division needed to measure an interval of 100 ms? (Divisions should be in powers of 2). Determine this design’s range and resolution. (d) If instead of a prescaler a second 16-bit up-counter is cascaded as in Figure 4.1 (d), what is the range and resolution of this desi ...
Op Amp Drives SAR ADCs to True Zero on a Single 5V Supply
... gain stable, allowing it to be used as a buffer to achieve the lowest output noise. The output is designed to drive a series 10Ω resistor and 330pF capacitor filter network, although larger load capacitances can be driven. The LTC6360 is available in MSOP and 3mm x 3mm DFN 8-pin packages, and is ful ...
... gain stable, allowing it to be used as a buffer to achieve the lowest output noise. The output is designed to drive a series 10Ω resistor and 330pF capacitor filter network, although larger load capacitances can be driven. The LTC6360 is available in MSOP and 3mm x 3mm DFN 8-pin packages, and is ful ...
network theorems module
... When zeroing a voltage source, it becomes a short circuit. When zeroing a current source, it becomes an open circuit. We can find the Thévenin resistance by zeroing the sources in the original network and then computing the resistance between the terminals. ...
... When zeroing a voltage source, it becomes a short circuit. When zeroing a current source, it becomes an open circuit. We can find the Thévenin resistance by zeroing the sources in the original network and then computing the resistance between the terminals. ...
Worksheet for Exploration 31.5
... Worksheet for Exploration 31.5: RL Circuits and Phasors Assume an ideal power supply. The graph shows the voltage as a function of time across the source (red), the resistor (blue), and the inductor (green) (voltage is given in volts and time is given in seconds). Restart. To analyze the currents an ...
... Worksheet for Exploration 31.5: RL Circuits and Phasors Assume an ideal power supply. The graph shows the voltage as a function of time across the source (red), the resistor (blue), and the inductor (green) (voltage is given in volts and time is given in seconds). Restart. To analyze the currents an ...
Batteries are made of conducting material and thus have resistance
... lights in your house do not get brighter or dimmer. If one light goes out the others remain lit. ...
... lights in your house do not get brighter or dimmer. If one light goes out the others remain lit. ...
June 2005 - Vicphysics
... and the 100 resistor will decrease, but the 1kwill not be affected. 9i unchanged There will be a smaller current through the resistor, so the circuit moves up the zener line. (1) 9ii reduced same voltage, more resistance, less current. (1) 10 removes thermal energy (1) from devices whose perfor ...
... and the 100 resistor will decrease, but the 1kwill not be affected. 9i unchanged There will be a smaller current through the resistor, so the circuit moves up the zener line. (1) 9ii reduced same voltage, more resistance, less current. (1) 10 removes thermal energy (1) from devices whose perfor ...
Superposition and
... terminal of the op-amp is zero, the voltage v+ is likewise zero. Thus, the circuit above is simply an inverting amplifier, where: ...
... terminal of the op-amp is zero, the voltage v+ is likewise zero. Thus, the circuit above is simply an inverting amplifier, where: ...
DM74ALS245A Octal 3-STATE Bus Transceiver
... This advanced low power Schottky device contains 8 pairs of 3-STATE logic elements configured as octal bus transceivers. These circuits are designed for use in memory, microprocessor systems and in asynchronous bidirectional data buses. Two way communication between buses is controlled by the (DIR) ...
... This advanced low power Schottky device contains 8 pairs of 3-STATE logic elements configured as octal bus transceivers. These circuits are designed for use in memory, microprocessor systems and in asynchronous bidirectional data buses. Two way communication between buses is controlled by the (DIR) ...
Year 9 Revision checklist EoY19.73 KB
... Describe how current changes in a series or parallel circuit, be able to use this knowledge to calculate the current in different parts of the circuits Describe how voltage changes in a series or parallel circuit; be able to use this knowledge to calculate the voltage in different parts of the circu ...
... Describe how current changes in a series or parallel circuit, be able to use this knowledge to calculate the current in different parts of the circuits Describe how voltage changes in a series or parallel circuit; be able to use this knowledge to calculate the voltage in different parts of the circu ...
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.