DE

(redirected from Density Evolution)
AcronymDefinition
DEGermany (Deutschland; Internet top level domain)
DEDelaware (US postal abbreviation)
DEDesktop Environment
DEDeutsch (German)
DEDeutschland (German: Germany)
DEDead End
DEData Engineering
DEDark Energy
DEDriver Education
DEDesert Eagle
DEData Entry
DEDiesel Engine
DEDiesel-Electric
DEDirector of Education
DEDigital Electronics
DEDerby (postcode, UK)
DEDevelopment Engineer
DEDesign Engineer
DEData Element
DEDouble Ended (metal halide lamps)
DEDeus Ex (game)
DEDefensive End (football)
DEDistance Education (course; various schools)
DEDestroyer Escort
DEDifferential Equation(s)
DEDepartment of Education (US)
DEDigital Environment
DEDiscrete Event (program specification)
DEDirected Energy
DEDouble Edge (shaving)
DEDale Earnhardt
DEDark Elf
DEDiesel Exhaust
DEDetonation
DEThis is / From (Amateur Radio logging abbreviation)
DEDrive End
DEDetection Efficiency
DEDigital Engineering
DEDensity Evolution
DEDistinguished Engineer (various organizations)
DEDiplôme d'Etat (French: state diploma)
DEDail Eireann (Irish National Parliament)
DEDonor Egg (infertility; refers to IVF)
DEDiatomaceous Earth (filter)
DEDistrict Engineer
DEDose Equivalent
DEDonee (IRB)
DEDistrict Executive
DEDaily Egyptian (student newspaper; Carbondale, IL)
DEDirected Evolution
DEDragon Empires (game)
DEDelayed Extraction
DEDesign Estimate
DEDeath Eater (Harry Potter)
DEDisenchant (gaming, World of Warcraft)
DEDelay Equalizer (US DoD)
DEDepth Electrode
DEDark Eldar
DEDeveloper Evangelist (Microsoft)
DEDomain Engineering
DEDisplay Element
DEData Exclusivity
DEDistinguished Editor (Institute of Professional Editors)
DEDigital Empire
DEDigital Encoder
DEDoctor of Engineering
DEDistant End (satellite communications)
DEDecentralized Execution (US DoD)
DEDedicated Equipment
DEDefense Emergency
DEDelegated Examining
DEDistribution Engineering
DEDry End
DEDebugging Extension (computing)
DEDestruction Efficiency
DEData Encoder
DEDictation Equipment
DEDevice End
DEDefense Enterprise (GIG)
DEDivisional Engineer
DEDeep Etch
DEDiscard Eligibility (ATM)
DEDarkness Eternal (website)
DEDiethylene Glycol Monoethyl Ether
DEDynamics Explorer
DEDevelopment Ephemeris (Jet Propulsion Laboratory)
DEdegree of esterification
DEDesignated Examiner
DEDevelopment Estimate
DEDiscipline Engineer
DEDigital Exploitation
DEDecision Element
DEDesignated Engineer
DEDigital Enclosure
DEDisplay Entity
DEIndividual Drift Error (US DoD)
DEDamage Expectancy
DEDoppler Extractor (US NASA)
DEDraconian Empire (gaming)
DEDissemination Element
DECondor Flugdienst GmbH, Germany (IATA airline code)
DEDivisions Exercise
DEDivision/District Engineer (Army Corps of Engineers)
DEDisposable Excess
DEDrums Equivalent
DETotal Drift error
DEDeployment Echelon
DEAssault Personnel Destroyer
DEDCS/Engineering & Services
References in periodicals archive ?
In order to obtain its threshold and show the evolution of the noise and interference power at different instances, in this paper density evolution (DE) is applied in the large sparse system limit, and the corresponding coupled DE equations are derived.
The present version includes density evolution analysis for different system schemes and supporting implementation results based on density evolution.
Figure 4 illustrated the firing density evolution of neural oscillator population with increasing time.
Firing density evolution diagram of neural oscillator population is determined by the coupling term as shown in Figures 5(a), 5(b), and 5(c).
(1) In case of spontaneous activity of neurons, the amplitude of the average number density evolution tends to decrease if the inhibitory coupling strength increases.
Combined with the BP decoding algorithm, LDPC codes with optimized ([lambda](x), [rho](x)) by density evolution [5, 7, 8] can attain high performance which is close to the theoretical limit (Shannon limit).
Next we consider analysis based on the density evolution for different LLR calculation methods.
As discussed previously, diffusion-based model was used to describe the density evolution of the polymer-containing air bubbles.
Heat transfer by conduction in the powder and gas regions is included in the model formulation and a semi-empirical model is used to describe the density evolution. The model can be used to predict many features observed experimentally for the sintering of a polymer compact.
The model predictions are validated by comparing them with experimental data presented by Kontopoulou and Vlachopoulos (10), which were obtained by monitoring the density evolution of a powder compact under constant oven temperature.
However, the energy criterion does not give a single solution and another criterion on heat flux density evolution is added.
The heat flux density evolution on the mobile and the fixed parts of the mold are shown in Fig.