PE

(redirected from Potential Electrode)
AcronymDefinition
PEPeru
PEPhysical Education
PEProfessional Engineer
PEPrice to Earnings (ratio)
PEPerformance Evaluation
PEPer Esempio (Italian: For Example)
PEProbable Error
PEPress Enterprise (newspaper)
PEProfessional Engineer (National Council of Examiners for Engineering and Surveying)
PEPort Elizabeth (South Africa)
PEProvider Edge (IETF RFC 2547)
PEPractice Expense (Medicare/Medicaid payments)
PEPrivate Equity
PEPortable Executable
PEProject Engineer
PEProgram Element (Army financial)
PEPremature Ejaculation (male condition)
PEPublic Enemy
PEPotential Energy
PEPrince Edward Island (Canada)
PEProfessional Edition (usually describing software)
PEPor Ejemplo (Spanish: For Example)
PEPernambuco (Brazil)
PEPersonal Edition
PEPhysical Examination
PEProcessing Element
PEPublic Education
PEPolyethylene
PEPor Exemplo (Portuguese: For Example)
PEPlain Edge
PEPlanet Earth
PEPlatinum Edition
PEProcess Equipment
PEPeterborough (postcode, United Kingdom)
PEPerkinElmer (Massachusetts)
PEPhosphatidylethanolamine (lipid)
PEPellet
PEPreliminary Engineering
PEPhoto-Etched
PEParlamento Europeo (Italian: European Parliament)
PEPrincipal Engineer
PEPermanent Establishment
PEProcess Engineer
PEPerjantai (Finnish: Friday)
PEProgram Evaluation
PEPhiladelphia Eagles
PEPersonal Effects (US DoD)
PEPulmonary Embolism
PEProduction Engineering
PEProgramming Environment (computer programming)
PEProfessional Ethics
PEPhenylephrine
PEPrinciples and Practice of Engineering
PEProfesseur des Écoles (French: School Teacher)
PEPotential Evapotranspiration (ecology)
PEPulmonary Edema
PEParasite Eve (video game)
PEPlant and Equipment
PEParse Error
PEPenis Erection
PEPreinstallation Environment (Microsoft Windows)
PEPersonalentwicklung
PEPleural Effusion (excess pleural cavity fluid)
PEPlans Examiner
PEProduct Engineer
PEProtestant Episcopal
PEPhysical Exertion
PEPrimavera Estate (Fashion, Italy)
PEPericardial Effusion
PEPelvic Exam
PEPetroleum Engineer
PEPreliminary Evaluation (EPA)
PEPoint Estimate
PEPower Engineer
PEPeripheral Equipment
PEPeace Enforcement (US DoD)
PEPharmacoeconomics (cost management analytical tool)
PEProcessing Engine
PEParity Error
PEPescara, Abruzzo (Italian province)
PEProbability of Error
PEProstate Enlargement
PEPin Electronics (various companies)
PEProject Executive
PEPlasma Exchange
PEProtective Earth (electrical units safety measure)
PEPeriodic Inspection
PEPulse Engineering (various locations)
PEPerformance Efficiency
PEProjet d'Établissement (French: School Project)
PEProject Entropia (game)
PEPlain End
PEPeer Educators
PEPhosphoethanolamine
PEPresumptive Eligibility
PEPlayboy Enterprises
PEPilot Error (aircraft)
PEPunctuated Equilibrium
PEPeclet Number
PEPost Entry
PEPhysical Entity
PEPancreatic Enzyme
PEPractical Exercise
PEPermanent Employee
PEPopulation Equivalent
PEPacific Electric Railway
PEPhase Encoding
PEProject Estimator
PEProblem of Evil (philosophy)
PEPrinter's Error
PEParabolic Equation
PEProcessor Elements
PEPouvoir Executif (French)
PEProtein Explorer
PEProgram Engineer
PEParticulate Emission
PEPartial Evaluation (computer languages)
PEProcurement Executive
PEPrecision Engagement (time sensitive targeting)
PEPrivate Exchange
PEPrimitive Equation
PEPolicy Element
PEPeacetime Establishment (US DoD)
PEParallax Error
PEPort Engineer
PEPeking Express
PEPush Enteroscopy
PEPremier Executive
PEPermian Extinction (geological event)
PEProbability of Exceedance (seismic risk analysis)
PEProbability of Exceedance (earthquake
PEPrice Exception (various companies)
PEPropulsion Equipment
PEProtocol Elements (ITU-T)
PEPeace Establishment
PEPenerase (Hyper Logo command)
PEPermanent Echo (radar)
PEPlanning Estimate
PEProject Ego (game)
PEPreceding Event
PEPotential Excess
PEProbability of Bit Error
PEPipeline Execution
PEPreço de Exercício (Portuguese: Exercise Price)
PEPotential Earth (earth Ground point in an electrical circuit)
PEParasite Energy
PEPhycoerytherin
PEPressure Equalizer
PEPure Enantiomer (crystals)
PEProtective Entrance
PEPTF in Error
PEPair Equipment
PEPotential Electrode
PEPolychromatic Erythroblast
PEProbability Equivalence
PEPrecision Echo
PEPeoples' Elbow (wrestling finishing move)
PEPhase Estimator
PEPerceptual Energy
PEPyetlyakov (Soviet aircraft designer)
PEPermitted Explosive (mining)
PEPreferred Elite (insurance)
PEPlant Emulator
PEPreliminary Exploitation
PEPhysical Inventory, Ending
PEPAMRI Emulator HWCI
PEParity Even/Enable
PEPedal Exungulation (the clipping of toenails)
PEProving-Period Emergency
PEPervasive Expression
PEProgressiewe Enkefalopatie
References in periodicals archive ?
4) further, moving the potential electrode away from the GD, the potential is measured through the selected distance (for example, after 5 m, 10 m, 15 m, etc.);
However, in practice, the most widespread, due to its simplicity, is the one-beam circuit by the <<62% method>>, when the potential electrode P is immediately set at a distance from the GD, which is 62% of the removal of the current electrode C.
In this arrangement, four electrodes are spread along a straight line on the ground surface, and current (I) is conducted through the soil surface governed by the measurement of potential difference (IV) across the potential electrode. For any linear, symmetric array of AMNB electrodes, resistivity I can be written as equation (1):
Where IV is the potential difference across the potential electrodes and I is the current applied and k is the Geometric Factor and is given by equation (2).
For each model the minimum electrode distance was fixed at 1 m and apparent resistivity measures were calculated considering that order n varied between 1 and 10 and that the potential electrode distance MN was equal to 1, 2, and 3 m.
b) first the current ground electrode and the potential electrode are mounted and the connecting wires are connected to them.
The values of m and Am were determined by calculation, proceeding from the geometrical dimensions of the MT and the dielectric characteristics of the fluoroplastic-4: a structural insulating element that fixes the potential electrode of the MT and determines the value of the <<blind>> capacitance of the MT [9],
where [[alpha].sub.pp] is the own potential coefficient of the GD of the potential electrode.
The Schlumberger array uses a four-electrode system, two current electrodes (C1 and C2) and two potential electrodes (P1 and P2).
The IQ400 has a BNC connector for conventional glass pH and oxidation-reduction potential electrodes, as well a connector for ion-sensitive field effect transistor (ISFET) non-glass pH electrodes.
This configuration made use of four electrodes (two potential and two current electrodes) with potential electrodes remain fixed for first few readings whereas current electrodes are kept moving.
The value of the spacing of the current and potential electrodes is caused by the type of installation and the required depth sensing.