time-frequency space - vertaling naar russisch
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time-frequency space - vertaling naar russisch

Time-frequency representation; Time–frequency distribution; Time–frequency domain; Time-frequency distribution; Time–frequency transform; Time frequency transform; Time-frequency transform

time-frequency space      
частотно-временное простpанство
spatiotemporal         
  • '''here''']].
  • Figure 2–9. In this spacetime diagram, the 1 m length of the moving rod, as measured in the primed frame, is the foreshortened distance OC when projected onto the unprimed frame.
  • Figure 4-4. Dewan–Beran–Bell spaceship paradox
  • Figure 4–5. The curved lines represent the world lines of two observers A and B who accelerate in the same direction with the same constant magnitude acceleration. At A' and B', the observers stop accelerating. The dashed lines are lines of simultaneity for either observer before acceleration begins and after acceleration stops.
  • Figure 3–9. Energy and momentum of light in different inertial frames
  • Figure 5–9. (A) Cavendish experiment, (B) Kreuzer experiment
  • Figure 3–5. Derivation of Lorentz Transformation
  • Figure 5–3. Einstein's argument suggesting gravitational redshift
  • Figure 5–2. Equivalence principle
  • Figure 3–1. '''Galilean''' Spacetime and composition of velocities
  • Figure 2–3. (a) Galilean diagram of two frames of reference in standard configuration, (b) spacetime diagram of two frames of reference, (c) spacetime diagram showing the path of a reflected light pulse
  • '''Click here to animate.''']]
  • Figure 5-11. Gravity Probe B confirmed the existence of gravitomagnetism
  • Figure 2-11. Spacetime explanation of the twin paradox
  • Figure 3–4. Lorentz factor as a function of velocity
  • Figure 1–4. Hand-colored transparency presented by Minkowski in his 1908 ''Raum und Zeit'' lecture
  • Figure 2–4. The light cone centered on an event divides the rest of spacetime into the future, the past, and "elsewhere"
  • Figure 1-1.  Each location in spacetime is marked by four numbers defined by a [[frame of reference]]: the position in space, and the time (which can be visualized as the reading of a clock located at each position in space). The 'observer' synchronizes the clocks according to their own reference frame.
  • 1=''2'' and ''3''}} really represent tidal effects resulting from their differential attraction by mass&nbsp;''1''. (iii) A third reporter, trained in general relativity, knows that there are, in fact, no forces at all acting between the three objects. Rather, all three objects move along [[geodesics]] in spacetime.</ref>
  • Figure 3–2. Relativistic composition of velocities
  • Figure 3-10. Relativistic conservation of momentum
  • Figure 3–8. Relativistic spacetime momentum vector
  • Figure 2–6. Animation illustrating relativity of simultaneity
  • tanh]]). Sinh is red, cosh is blue and tanh is green.
  • Figure 2–7. (a) Families of invariant hyperbolae, (b) Hyperboloids of two sheets and one sheet
  • Figure 3–6. Spacetime diagram of relativistic Doppler effect
  • Figure 2–1. Spacetime diagram illustrating two photons, A and B, originating at the same event, and a slower-than-light-speed object, C
  • Figure 3-3. Spacetime diagrams illustrating time dilation and length contraction
  • Figure 2–8.  The invariant hyperbola comprises the points that can be reached from the origin in a fixed proper time by clocks traveling at different speeds
  • Figure 5–7. Origin of gravitomagnetism
  • Figure 2-2. Galilean diagram of two frames of reference in standard configuration
  • Figure 5-5. Contravariant components of the stress–energy tensor
  • Figure 3–7. Transverse Doppler effect scenarios
  • Figure 2–5. Light cone in 2D space plus a time dimension
MATHEMATICAL MODEL COMBINING SPACE AND TIME
Space-time interval; Spacetime interval; Time-space continuum; Space-like; Timelike; Spacelike; Light-like; Space-time continuum; Time-like; Space and time; Spacetime continuum; Neo newtonian; Neo-newtonian; Space/time continuum; Spacetime Interval; Space/time; Space time continueum; Interval spacetime; Space-time distance; Space time continuum; Invariant interval; Space time; Time space continuum; Time- space curvature; Space-Time; Space Time Continuum; Spacetimes; Lorentz interval; Time and space; Time and Space; Space–time; Space-time; Space-Time Continuum; Space–time continuum; Spacetime geometry; Draft:Spacetime; Spatiotemporal; Space Time; Spacetime (mathematics)

[speiʃiəu'temp(ə)rəl]

прилагательное

общая лексика

пространственно-временной

space-like         
  • '''here''']].
  • Figure 2–9. In this spacetime diagram, the 1&nbsp;m length of the moving rod, as measured in the primed frame, is the foreshortened distance OC when projected onto the unprimed frame.
  • Figure 4-4. Dewan–Beran–Bell spaceship paradox
  • Figure 4–5. The curved lines represent the world lines of two observers A and B who accelerate in the same direction with the same constant magnitude acceleration. At A' and B', the observers stop accelerating. The dashed lines are lines of simultaneity for either observer before acceleration begins and after acceleration stops.
  • Figure 3–9. Energy and momentum of light in different inertial frames
  • Figure 5–9. (A) Cavendish experiment, (B) Kreuzer experiment
  • Figure 3–5. Derivation of Lorentz Transformation
  • Figure 5–3. Einstein's argument suggesting gravitational redshift
  • Figure 5–2. Equivalence principle
  • Figure 3–1. '''Galilean''' Spacetime and composition of velocities
  • Figure 2–3. (a) Galilean diagram of two frames of reference in standard configuration, (b) spacetime diagram of two frames of reference, (c) spacetime diagram showing the path of a reflected light pulse
  • '''Click here to animate.''']]
  • Figure 5-11. Gravity Probe B confirmed the existence of gravitomagnetism
  • Figure 2-11. Spacetime explanation of the twin paradox
  • Figure 3–4. Lorentz factor as a function of velocity
  • Figure 1–4. Hand-colored transparency presented by Minkowski in his 1908 ''Raum und Zeit'' lecture
  • Figure 2–4. The light cone centered on an event divides the rest of spacetime into the future, the past, and "elsewhere"
  • Figure 1-1.  Each location in spacetime is marked by four numbers defined by a [[frame of reference]]: the position in space, and the time (which can be visualized as the reading of a clock located at each position in space). The 'observer' synchronizes the clocks according to their own reference frame.
  • 1=''2'' and ''3''}} really represent tidal effects resulting from their differential attraction by mass&nbsp;''1''. (iii) A third reporter, trained in general relativity, knows that there are, in fact, no forces at all acting between the three objects. Rather, all three objects move along [[geodesics]] in spacetime.</ref>
  • Figure 3–2. Relativistic composition of velocities
  • Figure 3-10. Relativistic conservation of momentum
  • Figure 3–8. Relativistic spacetime momentum vector
  • Figure 2–6. Animation illustrating relativity of simultaneity
  • tanh]]). Sinh is red, cosh is blue and tanh is green.
  • Figure 2–7. (a) Families of invariant hyperbolae, (b) Hyperboloids of two sheets and one sheet
  • Figure 3–6. Spacetime diagram of relativistic Doppler effect
  • Figure 2–1. Spacetime diagram illustrating two photons, A and B, originating at the same event, and a slower-than-light-speed object, C
  • Figure 3-3. Spacetime diagrams illustrating time dilation and length contraction
  • Figure 2–8.  The invariant hyperbola comprises the points that can be reached from the origin in a fixed proper time by clocks traveling at different speeds
  • Figure 5–7. Origin of gravitomagnetism
  • Figure 2-2. Galilean diagram of two frames of reference in standard configuration
  • Figure 5-5. Contravariant components of the stress–energy tensor
  • Figure 3–7. Transverse Doppler effect scenarios
  • Figure 2–5. Light cone in 2D space plus a time dimension
MATHEMATICAL MODEL COMBINING SPACE AND TIME
Space-time interval; Spacetime interval; Time-space continuum; Space-like; Timelike; Spacelike; Light-like; Space-time continuum; Time-like; Space and time; Spacetime continuum; Neo newtonian; Neo-newtonian; Space/time continuum; Spacetime Interval; Space/time; Space time continueum; Interval spacetime; Space-time distance; Space time continuum; Invariant interval; Space time; Time space continuum; Time- space curvature; Space-Time; Space Time Continuum; Spacetimes; Lorentz interval; Time and space; Time and Space; Space–time; Space-time; Space-Time Continuum; Space–time continuum; Spacetime geometry; Draft:Spacetime; Spatiotemporal; Space Time; Spacetime (mathematics)

математика

пространственноподобный

Смотрите также

space-like curve; space-like geodesic; space-like hypersurface; space-like line; space-like manifold; space-like projection; space-like surface; space-like value; space-like vector

Definitie

ЕВРОПЕЙСКОЕ КОСМИЧЕСКОЕ АГЕНТСТВО
(ЕКА) , международная организация 10 стран. Создана в 1975. Разрабатывает космические аппараты (КА) коммерческого и хозяйственно-прикладного назначения. ЕКА имеет сеть станций слежения за полетом космических аппаратов с центром управления в Дармштадте (Германия).

Wikipedia

Time–frequency representation

A time–frequency representation (TFR) is a view of a signal (taken to be a function of time) represented over both time and frequency. Time–frequency analysis means analysis into the time–frequency domain provided by a TFR. This is achieved by using a formulation often called "Time–Frequency Distribution", abbreviated as TFD.

TFRs are often complex-valued fields over time and frequency, where the modulus of the field represents either amplitude or "energy density" (the concentration of the root mean square over time and frequency), and the argument of the field represents phase.

Vertaling van &#39time-frequency space&#39 naar Russisch