parallel connection - meaning and definition. What is parallel connection
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What (who) is parallel connection - definition

THE TWO BASIC WAYS OF CONNECTING THE COMPONENTS OF AN ELECTRICAL CIRCUIT
Series circuit; Parallel circuit; Series and parallel curcuits; Parallel (electronics); Parallel curcuit; Series connection; Parallel connection; Parallel wiring; Series wiring; Parallel circuits; Series circuits; Series curcuit; Series curcuits; Series and parallel circuit; Series (circuit); In series; In parallel; Series resistance; Series-coupled cell; Parallel-coupled cell; Capacitors in series; Capacitors in parallel; Inductors in series; Inductors in parallel; Series & parallel circuits; Series circuits information; Resistances in Parallel; In Parallel; R1 series R2; R₁ series R₂; R1 + R2; R₁ + R₂; R1+R2; R₁+R₂; L1 series L2; L₁ series L₂; L1 + L2; L₁ + L₂; L1+L2; L₁+L₂; Z1 series Z2; Z₁ series Z₂; Z1 + Z2; Z₁ + Z₂; Z1+Z2; Z₁+Z₂; C1 series C2; C₁ series C₂; C1 parallel C2; C₁ parallel C₂; C1 ∥ C2; C₁ ∥ C₂; C1∥C2; C₁∥C₂; C1 + C2; C₁ + C₂; C1+C2; C₁+C₂; G1 series G2; G₁ series G₂; G1 + G2; G₁ + G₂; G1+G2; G₁+G₂; G1 parallel G2; G₁ parallel G₂; G1 ∥ G2; G₁ ∥ G₂; G1∥G2; G₁∥G₂; B1 series B2; B₁ series B₂; B1 + B2; B₁ + B₂; B1+B2; B₁+B₂; X1 series X2; X₁ series X₂; X1 + X2; X₁ + X₂; X1+X2; X₁+X₂; Y1 series Y2; Y₁ series Y₂; Y1 + Y2; Y₁ + Y₂; Y1+Y2; Y₁+Y₂; B1 parallel B2; B₁ parallel B₂; B1 ∥ B2; B₁ ∥ B₂; B1∥B2; B₁∥B₂; Y1 parallel Y2; Y₁ parallel Y₂; Y1 ∥ Y2; Y₁ ∥ Y₂; Y1∥Y2; Y₁∥Y₂; Parallel and series circuits; Series (electronics)
  • A diagram of several capacitors, side by side, both leads of each connected to the same wires.
  • A diagram of several capacitors, connected end to end, with the same amount of current going through each.
  • A diagram of several inductors, side by side, both leads of each connected to the same wires.
  • A diagram of several inductors, connected end to end, with the same amount of current going through each.
  • A diagram of several resistors, side by side, both leads of each connected to the same wires.
  • This is a diagram of several resistors, connected end to end, with the same amount of current through each.
  • A series circuit with a [[voltage source]] (such as a battery, or in this case a cell) and three resistance units

Connection pool         
CACHE OF DATABASE CONNECTIONS MAINTAINED BY THE DATABASE
Connection pooling; Connection Pool
In software engineering, a connection pool is a cache of database connections maintained so that the connections can be reused when future requests to the database are required.
Connection (vector bundle)         
  • A section of a bundle may be viewed as a generalized function from the base into the fibers of the vector bundle. This can be visualized by the graph of the section, as in the figure above.
  • How to recover the covariant derivative of a connection from its parallel transport. The values <math>s(\gamma(t))</math> of a section <math>s\in \Gamma(E)</math> are parallel transported along the path <math>\gamma</math> back to <math>\gamma(0)=x</math>, and then the covariant derivative is taken in the fixed vector space, the fibre <math>E_x</math> over <math>x</math>.
LINEAR CONNECTION ON A VECTOR BUNDLE
Koszul connection; Vector bundle connection; Connection on a vector bundle
In mathematics, and especially differential geometry and gauge theory, a connection on a fiber bundle is a device that defines a notion of parallel transport on the bundle; that is, a way to "connect" or identify fibers over nearby points. The most common case is that of a linear connection on a vector bundle, for which the notion of parallel transport must be linear.
parallel processor         
  • A graphical representation of [[Amdahl's law]]. The speedup of a program from parallelization is limited by how much of the program can be parallelized. For example, if 90% of the program can be parallelized, the theoretical maximum speedup using parallel computing would be 10 times no matter how many processors are used.
  • Beowulf cluster]]
  • Blue Gene/L]] massively parallel [[supercomputer]]
  • The [[Cray-1]] is a vector processor
  • 1=IPC = 1}}).
  • A graphical representation of [[Gustafson's law]]
  • [[ILLIAC IV]], "the most infamous of supercomputers"<ref name="infamous"/>
  • 1=IPC = 0.2 < 1}}).
  • A logical view of a [[non-uniform memory access]] (NUMA) architecture. Processors in one directory can access that directory's memory with less latency than they can access memory in the other directory's memory.
  • Tesla GPGPU card]]
  • 1=IPC = 2 > 1}}).
  • Taiwania 3 of [[Taiwan]], a parallel supercomputing device that joined [[COVID-19]] research.
PROGRAMMING PARADIGM IN WHICH MANY CALCULATIONS OR THE EXECUTION OF PROCESSES ARE CARRIED OUT SIMULTANEOUSLY
Parallel computer; Parallel processor; Parallel computation; Parallel programming; Parallel Programming; Parallel computers; Concurrent language; Concurrent event; Computer Parallelism; Parallel machine; Concurrent (programming); Parallel architecture; Parallel Computing; Parallelisation; Parallelization; Parallelized; Multicomputer; Parallelism (computing); Parellel computing; Superword Level Parallelism; Parallel programming language; Message-driven parallel programming; Parallel computer hardware; Parallel program; Parallel code; Parallel language; Parallel processing (computing); Multiple processing elements; Parallel execution units; History of parallel computing; Parallel hardware; Parallel processing computer
<parallel> A computer with more than one {central processing unit}, used for parallel processing. (1996-04-23)

Wikipedia

Series and parallel circuits

Two-terminal components and electrical networks can be connected in series or parallel. The resulting electrical network will have two terminals, and itself can participate in a series or parallel topology. Whether a two-terminal "object" is an electrical component (e.g. a resistor) or an electrical network (e.g. resistors in series) is a matter of perspective. This article will use "component" to refer to a two-terminal "object" that participate in the series/parallel networks.

Components connected in series are connected along a single "electrical path", and each component has the same electric current through it, equal to the current through the network. The voltage across the network is equal to the sum of the voltages across each component.

Components connected in parallel are connected along multiple paths, and each component has the same voltage across it, equal to the voltage across the network. The current through the network is equal to the sum of the currents through each component.

The two preceding statements are equivalent, except for exchanging the role of voltage and current.

A circuit composed solely of components connected in series is known as a series circuit; likewise, one connected completely in parallel is known as a parallel circuit. Many circuits can be analyzed as a combination of series and parallel circuits, along with other configurations.

In a series circuit, the current that flows through each of the components is the same, and the voltage across the circuit is the sum of the individual voltage drops across each component. In a parallel circuit, the voltage across each of the components is the same, and the total current is the sum of the currents flowing through each component.

Consider a very simple circuit consisting of four light bulbs and a 12-volt automotive battery. If a wire joins the battery to one bulb, to the next bulb, to the next bulb, to the next bulb, then back to the battery in one continuous loop, the bulbs are said to be in series. If each bulb is wired to the battery in a separate loop, the bulbs are said to be in parallel. If the four light bulbs are connected in series, the same current flows through all of them and the voltage drop is 3 volts across each bulb, which may not be sufficient to make them glow. If the light bulbs are connected in parallel, the currents through the light bulbs combine to form the current in the battery, while the voltage drop is 12 volts across each bulb and they all glow.

In a series circuit, every device must function for the circuit to be complete. If one bulb burns out in a series circuit, the entire circuit is broken. In parallel circuits, each light bulb has its own circuit, so all but one light could be burned out, and the last one will still function.

Examples of use of parallel connection
1. As painful and tortuous as it may be, the disengagement from the Gaza Strip must be accompanied by a parallel connection.