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{{Quotation|A measurement always causes the system to jump into an [[Eigenvalues and eigenvectors|eigenstate]] of the dynamical variable that is being measured, the eigenvalue of this eigenstate belongs to being equal to the result of the measurement|[[Paul Dirac|P.A.M. Dirac]] (1958) in "[[The Principles of Quantum Mechanics]]" p. 36}}


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The framework of [[quantum mechanics]] requires a careful definition of '''measurement'''. The issue of measurement lies at the heart of the problem of the [[interpretation of quantum mechanics]], for which there is currently no consensus.
 
==Measurement from a practical point of view==
 
Measurement plays an important role in quantum mechanics, and it is viewed in different ways among various [[interpretations of quantum mechanics]]. In spite of considerable ''philosophical'' differences, different views of measurement almost universally agree on the ''practical'' question of what results from a routine quantum-physics laboratory measurement. To understand this, the [[Copenhagen interpretation]], which has been commonly used,<ref>Hermann Wimmel (1992). Quantum physics & observed reality: a critical interpretation of quantum mechanics. World Scientific. p. 2. ISBN 978-981-02-1010-6. Retrieved 9 May 2011.</ref> is employed in this article.
 
===Qualitative overview===
 
In classical mechanics, a simple system consisting of only one single particle is fully described by the position <math>\vec{x} (t)</math> and momentum <math>\vec{p} (t)</math> of the particle. As an analogue, in quantum mechanics a system is described by its [[quantum state]]. In mathematical languages, all possible pure states of a system form a complete abstract [[vector space]] called [[Hilbert space]], which is typically infinite-dimensional. A pure state is represented by a [[Quantum state|state vector]] (or precisely a [[Ray (quantum theory)#Pure_states_as_rays_in_a_Hilbert_space|ray]]) in the Hilbert space.
 
In the experimental aspect, once a quantum system has been prepared in laboratory, some measurable quantities such as position and energy are measured. That is, the dynamic state of the system is already in an [[Eigenstate#Eigenfunctions|eigenstate]] of some measurable quantities which is probably not the quantity that will be measured. For pedagogic reasons, the measurement is usually assumed to be ideally accurate. Hence, the dynamic state of a system after measurement is assumed to "[[Wave function collapse|collapse]]" into an eigenstate of the [[Operator (physics)|operator]] corresponding to the measurement. Repeating the same measurement without any significant evolution of the quantum state will lead to the same result. If the preparation is repeated, which does not put the system into the previous eigenstate, subsequent measurements will likely lead to different result. That is, the dynamic state collapses to different eigenstates.
 
The values obtained after the measurement is in general described by a [[probability distribution]], which is determined by an "average" (or "expectation") of the measurement operator based on the quantum state of the prepared system.<ref name=Sakurai24>{{cite book|author=J. J. Sakurai |title=Modern Quantum Mechanics|year=1994|edition=2nd|ISBN=0201539292}}</ref> The probability distribution is either [[continuous random variable|continuous]] (such as position and momentum) or [[discrete probability distribution|discrete]] (such as spin), depending on the quantity being measured.
 
The measurement process is often considered as [[stochastic process|random]] and [[indeterminism|indeterministic]]. Nonetheless, there is considerable dispute over this issue. In some [[interpretations of quantum mechanics]], the result merely ''appears'' random and indeterministic, whereas in other interpretations the indeterminism is core and irreducible. A significant element in this disagreement is the issue of "[[wavefunction collapse|collapse of the wavefunction]]" associated with the change in state following measurement. There are many philosophical issues and stances (and some mathematical variations) taken—and near universal agreement that we do not yet fully understand quantum reality. In any case, our descriptions of dynamics involve probabilities and averages.
 
===Quantitative details===
 
The mathematical relationship between the quantum state and the probability distribution is, again, widely accepted among physicists, and has been experimentally confirmed countless times. This section summarizes this relationship, which is stated in terms of the [[mathematical formulation of quantum mechanics]].
 
====Measurable quantities ("observables") as operators====
{{Main|Observable}}
 
It is a postulate of quantum mechanics that all measurements have an associated [[linear operator|operator]] (called an '''observable operator''', or just an '''observable'''), with the following properties:
#The observable is a [[Hermitian operator|Hermitian]] ([[self-adjoint operator|self-adjoint]]) [[linear operator|operator]] mapping a [[Hilbert space]] (namely, the [[state space (physics)|state space]], which consists of all possible quantum states) into itself.
#Thus, the observable's [[eigenvector]]s (called an [[eigenbasis]]) form an [[orthonormal]] [[basis (linear algebra)|basis]] that [[linear span|span]] the state space in which that observable exists.  Any quantum state can be represented as a [[quantum superposition|superposition]] of the eigenstates of an observable.
#Hermitian operators' [[eigenvalue]]s are [[real number|real]]. The possible outcomes of a measurement are precisely the eigenvalues of the given observable.
#For each eigenvalue there are one or more corresponding [[eigenvector]]s ([[eigenstate]]s). A measurement results in the system being in the eigenstate corresponding to the eigenvalue result of the measurement. If the eigenvalue determined from the measurement corresponds to more than one eigenstate ("degeneracy"), instead of being in a definite state, the system is in a sub-space of the measurement operator corresponding to all the states having that eigenvalue.
 
Important examples of observables are:
* The [[Hamiltonian (quantum mechanics)|Hamiltonian]] operator <math>\hat{H}</math>, which represents the total [[energy]] of the system. In nonrelativistic quantum mechanics the [[Hamiltonian (quantum mechanics)|nonrelativistic Hamiltonian]] operator is given by <math> {\hat H} = \hat T + \hat V ={\hat p^2 \over 2m} + V( \hat x )  </math>.
* The [[momentum]] operator <math> {\hat p}</math> is given by <math> {\hat p} = -i\hbar {\partial \over \partial x}  </math> (in the [[Position and momentum space#Functions and operators in position space|position basis]]), or <math>{\hat p} = p</math> (in the [[Position and momentum space#Functions and operators in momentum space|momentum basis]]).
* The [[position operator]] <math> {\hat x} </math> is given by <math>{\hat x} = x</math> (in the position basis), or <math> {\hat x}= i\hbar {\partial \over \partial p}  </math> (in the momentum basis).
 
Operators can be [[commutator|noncommuting]]. Two Hermitian operators commute if (and only if) there is at least one basis of vectors, each of which is an eigenvector of both operators (this is sometimes called a '''simultaneous eigenbasis'''). Noncommuting observables are said to be ''incompatible'' and cannot in general be measured simultaneously. In fact, they are related by an [[uncertainty principle]], as a direct consequence of the wave-like nature of the quantum postulate, and are associated with disturbance-due-to measurement due to the fundamental contributions of Werner Heisenberg.
 
==== Measurement probabilities and wavefunction collapse ====
 
There are a few possible ways to mathematically describe the measurement process (both the probability distribution and the collapsed wavefunction). The most convenient description depends on the [[spectrum of an operator|spectrum]] (i.e., set of eigenvalues) of the observable.
 
===== Discrete, nondegenerate spectrum =====
 
Let <math>\hat{O}</math> be an observable. By assumption, <math>\hat{O}</math> has discrete [[eigenstates]] <math>|1 \rang, |2 \rang, |3 \rang,...</math> with corresponding distinct eigenvalues <math>O_1, O_2, O_3,...</math>. That is, the states are nondegenerate.
 
Consider a system prepared in state <math>|\psi \rang</math>. Since the eigenstates of the observable <math>\hat{O}</math> form a complete [[basis (linear algebra)|basis]] called eigenbasis, the state vector <math>|\psi \rang</math> can be written in terms of the eigenstates as
:<math>|\psi\rang = c_1 | 1 \rang + c_2 | 2 \rang + c_3 | 3 \rang + \cdots</math>,
where <math>c_1,c_2,\ldots</math> are complex numbers in general. The eigenvalues <math>O_1, O_2, O_3,...</math> are all possible values of the measurement. The corresponding probabilities are given by
:<math> \Pr( O_n ) = \frac{ |\lang n | \psi \rang|^2}{\lang \psi | \psi\rang} = \frac{ | c_n |^2 }{\sum_k | c_k |^2} </math>
Usually <math>|\psi\rang</math> is assumed to be [[Normalisable wave function|normalized]], i.e. <math>\lang \psi | \psi\rang=1</math>. Therefore, the expression above is reduced to
:<math> \Pr( O_n ) = |\lang n | \psi \rang|^2 = | c_n |^2 </math>
 
If the result of the measurement is <math>O_n</math>, then the system (after measurement) is in pure state <math>|n\rang</math>. That is,
:<math> | \psi' \rang  = | n \rang </math>
so any repeated measurement of <math>{\hat O}</math> will yield the same result <math>O_n</math>.  
When there is a discontinuous change in state due to a measurement that involves discrete eigenvalues, that is called [[wavefunction collapse]]. For some, this is simply a description of a reasonably accurate discontinuous change in a mathematical representation of physical reality; for others, depending on philosophical orientation, this is a fundamentally serious problem with quantum theory.
 
===== Continuous, nondegenerate spectrum =====
 
Let <math>\hat{O}</math> be an observable. By assumption, <math>\hat{O}</math> has continuous eigenstate <math>|x\rang</math>, with corresponding distinct eigenvalue <math>x</math>. The eigenvalue forms a [[continuous spectrum]] filling the [[interval (mathematics)|interval]] (a,b).
 
Consider a system prepared in state <math>|\psi\rang</math>. Since the eigenstates of the observable <math>\hat{O}</math> form a complete [[basis (linear algebra)|basis]] called eigenbasis, the state vector <math>|\psi \rang</math> can be written in terms of the eigenstates as
 
:<math>|\psi\rang = \int_a^b c(x) | x \rang \, dx</math>,
 
where <math>c(x)</math> is a complex-valued function. The eigenvalue that fills up the interval <math>(a,b)</math> is the possible value of measurement. The corresponding probability is described by a probability function given by
 
:<math> \Pr( d<x<e ) = \frac{\int_d^e|\lang x|\psi\rang|^2\, dx}{\int_a^b\lang\psi|\psi\rang\, dx} = \frac{ \int_d^e | c(x) |^2 \, dx }{\int_a^b | c(x) |^2 \, dx} </math>
 
where <math>(d,e)\subseteq(a,b)</math>. Usually <math>|\psi\rang</math> is assumed to be [[Normalisable wave function|normalized]], i.e. <math>\int_a^b\lang\psi|\psi\rang\, dx=1</math>. Therefore, the expression above is reduced to
 
:<math> \Pr( d<x<e ) = \int_d^e | c(x) |^2 \, dx </math>
 
If the result of the measurement is <math>x</math>, then the system (after measurement) is in pure state <math>|x\rang</math>. That is,
 
:<math> |\psi'\rang = |x\rang.</math>
 
Alternatively, it is often possible and convenient to analyze a continuous-spectrum measurement by taking it to be the [[limit (mathematics)|limit]] of a different measurement with a discrete spectrum. For example, an analysis of [[scattering]] involves a continuous spectrum of energies, but by adding a [[particle in a box|"box" potential]] (which bounds the volume in which the particle can be found), the spectrum becomes [[discrete spectrum|discrete]]. By considering larger and larger boxes, this approach need not involve any approximation, but rather can be regarded as an equally valid formalism in which this problem can be analyzed.
 
===== Degenerate spectra =====
 
If there are multiple eigenstates with the same eigenvalue (called ''degeneracies''), the analysis is a bit less simple to state, but not essentially different. In the discrete case, for example, instead of finding a complete eigenbasis, it is a bit more convenient to write the Hilbert space as a [[direct sum of Hilbert spaces|direct sum]] of [[eigenspace|eigen''spaces'']]. The probability of measuring a particular eigenvalue is the squared component of the [[quantum state|state vector]] in the corresponding eigenspace, and the new state after measurement is the [[projection (linear algebra)|projection]] of the original state vector into the appropriate eigenspace.
 
===== Density matrix formulation =====
{{Main|Density matrix}}
Instead of performing quantum-mechanics computations in terms of [[wavefunction]]s ([[bra-ket notation|kets]]), it is sometimes necessary to describe a quantum-mechanical system in terms of a [[density matrix]]. The analysis in this case is formally slightly different, but the physical content is the same, and indeed this case can be derived from the wavefunction formulation above. The result for the discrete, degenerate case, for example, is as follows:
 
Let <math> {\hat O} </math> be an observable, and suppose that it has discrete [[eigenvalue]]s <math>O_1,O_2,O_3,\ldots</math>, associated with [[eigenspace]]s <math>V_1,V_2,\ldots</math> respectively. Let <math>P_n</math> be the [[projection (linear algebra)|projection operator]] into the space <math>V_n</math>.
 
Assume the system is prepared in the state described by the density matrix ''ρ''. Then measuring <math> {\hat O} </math> can yield any of the results <math>O_1, O_2, O_3, \ldots</math>, with corresponding probabilities given by
:<math> \Pr( O_n ) = \mathrm{Tr}(P_n \rho)</math>
where <math>\mathrm{Tr}</math> denotes [[trace (linear algebra)|trace]]. If the result of the measurement is ''n'', then the new density matrix will be
:<math> \rho' = \frac{P_n \rho P_n}{\mathrm{Tr}(P_n \rho)}</math>
Alternatively, one can say that the measurement process results in the new density matrix
:<math> \rho'' = \sum_n P_n \rho P_n</math>
where the difference is that <math> \rho''</math> is the density matrix describing the entire ensemble, whereas <math> \rho'</math> is the density matrix describing the sub-ensemble whose measurement result was <math>n</math>.
 
==== Statistics of measurement ====
 
As detailed above, the result of measuring a quantum-mechanical system is described by a probability distribution. Some properties of this distribution are as follows:
 
Suppose we take a measurement corresponding to observable <math>\hat O</math>, on a state whose quantum state is <math>|\psi\rang</math>.
*The [[expected value|mean]] (average) value of the measurement is (see [[Expectation value (quantum mechanics)]])
:: <math>\lang \psi | \hat O | \psi \rang </math>.
*The [[variance]] of the measurement is
:: <math>\lang \psi | \hat O^2  | \psi \rang - (\lang \psi | \hat O | \psi \rang)^2</math>
*The [[standard deviation]] of the measurement is
:: <math>\sqrt{\lang \psi | \hat O^2  | \psi \rang - (\lang \psi | \hat O | \psi \rang)^2}</math>
 
These are direct consequences of the above formulas for measurement probabilities.
 
==== Example ====
 
Suppose that we have a [[particle in a box|particle in a 1-dimensional box]], set up initially in the ground state <math>|\psi_1\rang</math>. As can be computed from the [[Schrödinger equation|time-independent Schrödinger equation]], the energy of this state is <math>E_1=\frac{\pi^2\hbar^2}{2mL^2}</math> (where ''m'' is the particle's mass and ''L'' is the box length), and the spatial wavefunction is <math>\lang x|\psi_1\rang = \sqrt{ \frac{2}{L} }~{\rm sin}\left(\frac{\pi x}{L}\right)</math>. If the energy is now measured, the result will always certainly be <math>E_1</math>, and this measurement will not affect the wavefunction.
 
Next suppose that the particle's position is measured. The position ''x'' will be measured with probability density
:<math> \Pr(S<x<S+dS) = \frac{2}{L}~{\rm sin}^2\left(\frac{\pi S}{L}\right)dS.</math>
If the measurement result was ''x''=''S'', then the wavefunction after measurement will be the position eigenstate <math>|x=S\rang</math>. If the particle's position is immediately measured again, the same position will be obtained.
 
The new wavefunction <math>|x=S\rang</math> can, like any wavefunction, be written as a superposition of eigenstates of any observable. In particular, using energy eigenstates, <math>| \psi_n\rang</math>, we have
:<math>|x=S\rang = \sum_n | \psi_n \rangle \left\langle \psi_n | x=S \right\rangle = \sum_n | \psi_n \rangle \sqrt{ \frac{2}{L} }~{\rm sin}\left(\frac{n \pi S}{L}\right)</math>
If we now leave this state alone, it will smoothly evolve in time according to the [[Schrödinger equation]]. But suppose instead that an energy measurement is immediately taken. Then the possible energy values <math>E_n</math> will be measured with relative probabilities:
:<math>\Pr(E_n) = |\lang \psi_n | S \rang|^2 = \frac{2}{L}~{\rm sin}^2\left(\frac{n \pi S}{L}\right)</math>
and moreover if the measurement result is <math>E_n</math>, then the new state will be the energy eigenstate <math>|\psi_n\rang</math>.
 
So in this example, due to the process of [[wavefunction collapse]], a particle initially in the ground state can end up in any energy level, after just two subsequent [[Commutativity|non-commuting]] measurements are made.
 
== Wavefunction collapse ==
{{Main|Wave function collapse}}
The process in which a quantum state becomes one of the eigenstates of the operator corresponding to the measured [[observable]] is called "collapse", or "[[Wave function collapse|wavefunction collapse]]". The final eigenstate appears randomly with a probability equal to the square of its overlap with the original state.<ref name=Sakurai24/> The process of collapse has been studied in many experiments, most famously in the [[double-slit experiment]]. The wavefunction collapse raises serious questions regarding "the measurement problem",<ref>{{cite book|url=http://books.google.com/books?id=5t0tm0FB1CsC&pg=PA215&lpg=PA215&dq=wave+function+collapse&source=bl&ots=a7iUGurRDC&sig=o1ddjY7lQrj4EQdvS49xcceWq2M&hl=en&ei=RfgtSsDNL4WgM8u-rf4J&sa=X&oi=book_result&ct=result&resnum=7#PPA215,M1 |title= The Quantum Challenge: Modern Research On The Foundations Of Quantum Mechanics | author= George S. Greenstein and Arthur G. Zajonc |page= |edition=2nd|year=2006|ISBN= 076372470X}}</ref> as well as questions of [[determinism]] and [[Principle of locality|locality]], as demonstrated in the [[EPR paradox]] and later in [[Greenberger–Horne–Zeilinger state|GHZ entanglement]]. (See below.)
 
In the last few decades, major advances have been made toward a theoretical understanding of the collapse process. This new theoretical framework, called [[quantum decoherence]], supersedes previous notions of instantaneous collapse and provides an explanation for the absence of [[quantum coherence]] after measurement. Decoherence correctly predicts the form and probability distribution of the final eigenstates, and explains the apparent randomness of the choice of final state in terms of [[einselection]].<ref name="zurek03">[[Wojciech H. Zurek]], Decoherence, [[einselection]], and the quantum origins of the classical,''Reviews of Modern Physics'' 2003, 75, 715 or http://arxiv.org/abs/quant-ph/0105127</ref>
 
=== von Neumann measurement scheme ===
 
The [[von Neumann]] measurement scheme, the ancestor of quantum [[decoherence]] theory, describes measurements by taking into account the measuring apparatus which is also treated as a quantum object.
Let the quantum state be in the superposition <math> \scriptstyle |\psi\rang = \sum_n c_n |\psi_n\rang </math>, where <math>\scriptstyle  |\psi_n\rang </math> are [[eigenstates]] of the operator for the measurement prior to von Neumann's second apparatus. In order to make the measurement, the system described by <math>\scriptstyle |\psi\rang </math> needs to interact with the measuring apparatus described by the quantum state <math> \scriptstyle |\phi\rang </math>, so that the total wave function before the measurement and interaction with the second apparatus is <math>\scriptstyle |\psi\rang |\phi\rang </math>. During the interaction of object and measuring instrument the [[unitary operator|unitary]] evolution is supposed to realize the following transition from the initial to the final total wave function:
:<math> |\psi\rang |\phi\rang \rightarrow \sum_n c_n |\psi_n\rang |\phi_n\rang \quad \text{(measurement of the first kind),} </math>
where <math>\scriptstyle |\phi_n\rang</math> are orthonormal states of the measuring apparatus. The unitary evolution above is referred to as premeasurement. The relation with [[wave function collapse]] is established by calculating the final density operator of the object <math>\scriptstyle \sum_n |c_n|^2  |\psi_n\rang\lang \psi_n|</math> from the final total wave function. This density operator is interpreted by von Neumann as describing an ensemble of objects being after the measurement with probability <math>\scriptstyle |c_n|^2 </math> in the state <math>\scriptstyle |\psi_n\rang. </math>
 
The transition
:<math> |\psi\rang \rightarrow \sum_n |c_n|^2 |\psi_n\rang \lang \psi_n|</math>
is often referred to as ''weak'' von Neumann projection, the [[wave function collapse]] or ''strong'' von Neumann projection
:<math> |\psi\rang \rightarrow \sum_n |c_n|^2 |\psi_n\rang \lang \psi_n| \rightarrow |\psi_n\rang </math>
being thought to correspond to an additional selection of a subensemble by means of observation.
 
In case the measured observable has a degenerate spectrum, weak von Neumann projection is generalized to Lüders projection
:<math> |\psi\rang \rightarrow \sum_n |c_n|^2 P_n,\; P_n = \sum_i |\psi_{ni}\rang \lang \psi_{ni}|, </math>
in which the vectors <math>\scriptstyle |\psi_{ni}\rang </math> for fixed n are the degenerate eigenvectors of the measured observable. For an arbitrary state described by a density operator
<math>\scriptstyle \rho</math> Lüders projection is given by
:<math> \rho \rightarrow \sum_n P_n \rho P_n.</math>
 
=== Measurements of the second kind ===
In a ''measurement of the second kind'' the unitary evolution during the interaction of object and measuring instrument is supposed to be given by
:<math> |\psi\rang |\phi\rang \rightarrow \sum_n c_n |\chi_n\rang |\phi_n\rang, </math>
 
in which the states <math>\scriptstyle |\chi_n\rang</math> of the object are determined by specific properties of the interaction between object and measuring instrument. They are normalized but not necessarily mutually orthogonal. The relation with [[wave function collapse]] is analogous to that obtained for measurements of the first kind, the final state of the object now being <math>\scriptstyle |\chi_n\rang</math> with probability <math>\scriptstyle |c_n|^2. </math> Note that many present-day measurement procedures are measurements of the second kind, some even functioning correctly ''only as a consequence of being of the second kind''. For instance, a photon counter, detecting a photon by absorbing and hence annihilating it, thus ideally leaving the electromagnetic field in the vacuum state rather than in the state corresponding to the number of detected photons; also the [[Stern–Gerlach experiment]] would not function at all if it really were a measurement of the first kind.<ref>{{cite journal|author=M.O. Scully, W.E. Lamb, A. Barut |title=On the theory of the Stern–Gerlach apparatus |journal=Foundations of Physics |volume=17 |pages=575–583 |year=1987 |url=http://www.springerlink.com/content/t4266804k832p42p/fulltext.pdf |accessdate=9 November 2012|bibcode = 1987FoPh...17..575S |doi = 10.1007/BF01882788 }}</ref>
 
=== Decoherence in quantum measurement ===
One can also introduce the interaction with the environment <math>\scriptstyle |e\rang </math>, so that, in a measurement of the first kind, after the interaction the total wave function takes a form
:<math> \sum_n c_n |\psi_n\rang |\phi_n\rang |e_n \rang,</math>
which is related to the phenomenon of [[decoherence]].
 
The above is completely described by the Schrödinger equation and there are not any interpretational problems with this. Now the problematic [[Wave function collapse|wavefunction collapse]] does not need to be understood as a process <math>\scriptstyle |\psi\rangle \rightarrow |\psi_n\rang </math> on the level of the measured system, but can also be understood as a process <math>\scriptstyle |\phi\rangle \rightarrow |\phi_n\rang </math> on the level of the measuring apparatus, or as a process <math>\scriptstyle |e\rangle \rightarrow |e_n\rang </math> on the level of the environment. Studying these processes provides considerable insight into the [[measurement problem]] by avoiding the arbitrary boundary between the quantum and classical worlds, though it does not explain the presence of randomness in the choice of final eigenstate. If the set of states
;<math> \{ |\psi_n\rang\} </math>, <math> \{ |\phi_n\rang\} </math>,  or <math> \{ |e_n\rang\} </math>
represents a set of states that do not overlap in space, the appearance of collapse can be generated by either the [[Bohm interpretation]] or the [[many worlds interpretation|Everett interpretation]] which both deny the reality of wavefunction collapse. Both of these are stated to predict the same probabilities for collapses to various states as the conventional interpretation by their supporters. The Bohm interpretation is held to be correct only by a small minority of physicists, since there are difficulties with the generalization for use with relativistic [[quantum field theory]]. However, there is no proof that the Bohm interpretation is inconsistent with quantum field theory, and work to reconcile the two is ongoing.  The [[Everett interpretation]] easily accommodates [[relativistic quantum field theory]].
 
== Philosophical problems of quantum measurements ==
 
=== What physical interaction constitutes a measurement? ===
 
Until the advent of [[quantum decoherence]] theory in the late 20th century, a major conceptual problem of quantum mechanics and especially the [[Copenhagen interpretation]] was the lack of a distinctive criterion for a given physical interaction to qualify as "a measurement" and cause a wavefunction to collapse. This is best illustrated by the [[Schrödinger's cat]] paradox. Certain aspects of this question are now well understood in the framework of quantum decoherence theory, such as an understanding of [[weak measurement]]s, and quantifying what measurements or interactions are sufficient to destroy [[quantum coherence]]. Nevertheless, there remains less than universal agreement among physicists on some aspects of the question of what constitutes a measurement.
 
=== Does measurement actually determine the state? ===
 
The question of whether (and in what sense) a measurement actually determines the state is one which differs among the different interpretations of quantum mechanics. (It is also closely related to the understanding of wavefunction collapse.) For example, in most versions of the [[Copenhagen interpretation]], the measurement determines the state, and after measurement the state is definitely what was measured. But according to the [[many-worlds interpretation]], measurement determines the state in a more restricted sense: In other "worlds", other measurement results were obtained, and the other possible states still exist.
 
=== Is the measurement process random or deterministic? ===
 
As described above, there is universal agreement that quantum mechanics ''appears'' [[random process|random]], in the sense that all experimental results yet uncovered can be predicted and understood in the framework of quantum mechanics measurements being fundamentally random. Nevertheless, it is not settled<ref name="Quantum mechanics: Myths and facts">{{cite journal|url=http://arxiv.org/pdf/quant-ph/0609163 |title=Quantum mechanics: Myths and facts |author=Hrvoje Nikolić |year=2007 |accessdate=9 November 2012 |journal=Foundation of Physics |volume=37|pages= 1563–1611}}</ref>
whether this is true, fundamental randomness, or merely "emergent" randomness resulting from underlying ''[[Hidden variable theory|hidden variables]]'' which deterministically cause measurement results to happen a certain way each time. This continues to be an area of active research.<ref>{{cite journal| author=S. Gröblacher ''et al.'' |title=An experimental test of non-local realism |journal= Nature |volume=446 |issue= 871 |year=2007 |doi=10.1038/nature05677}}</ref>
 
If there ''are'' hidden variables, they would have to be "[[Principle of locality|nonlocal]]".
 
=== Does the measurement process violate locality? ===
{{Main|Quantum nonlocality|Principle of locality}}
 
In physics, the '''Principle of locality''' is the concept that information cannot travel faster than the [[speed of light]] (also see [[special relativity]]). It is known experimentally (see [[Bell's theorem]], which is related to the [[EPR paradox]]) that ''if'' quantum mechanics is deterministic (due to hidden variables, as described above), ''then'' it is '''nonlocal''' (i.e. violates the principle of locality). Nevertheless, there is not universal agreement among physicists on whether quantum mechanics is nondeterministic, nonlocal, or both.<ref name="Quantum mechanics: Myths and facts"/>
 
== See also ==
 
* Measurement related problems and [[paradox]]es
** [[Afshar experiment]]
** [[Measurement problem]]
** [[Wave function collapse|Wavefunction collapse]]
** [[Quantum Zeno effect]]
** [[EPR paradox]]
** [[Quantum pseudo-telepathy]]
** [[Renninger negative-result experiment]]
** [[Elitzur–Vaidman bomb-testing problem]]
** [[Schrödinger's cat]]
** [[Popper's experiment]]
* [[Interpretation of quantum mechanics|Interpretations of quantum mechanics]]
** [[Transactional interpretation]]
** [[Copenhagen interpretation]]
** [[Many-worlds interpretation]]
** [[Hidden variables theory]]
* Quantum mechanics formalism
** [[Quantum mechanics]]
** [[Mathematical formulation of quantum mechanics]]
** [[Schrödinger equation]]
** [[Bra-ket notation]]
** [[POVM|Generalized measurement]] (POVM, Positive operator valued measure)
 
==References==
{{reflist}}
 
==Further reading==
* {{cite book|author=[[John A. Wheeler]] and [[Wojciech Hubert Zurek]], eds. |title=Quantum Theory and Measurement| publisher=Princeton University Press| year=1983| ISBN= 0-691-08316-9}}
* {{cite book|author=Vladimir B. Braginsky and Farid Ya. Khalili| title=Quantum Measurement| publisher=Cambridge University Press |year=1992| ISBN= 0-521-41928-X}}
* {{cite book|title= The Quantum Challenge: Modern Research On The Foundations Of Quantum Mechanics | author= George S. Greenstein and Arthur G. Zajonc |page= |edition=2nd|year=2006|ISBN= 076372470X}}
 
== External links ==
* "[http://physicsweb.org/article/world/15/9/1 The Double Slit Experiment]". (physicsweb.org)
* "[http://plato.stanford.edu/entries/qt-measurement/ Measurement in Quantum Mechanics]" Henry Krips in the Stanford Encyclopedia of Philosophy
* [http://arxiv.org/abs/quant-ph/0312059 Decoherence, the measurement problem, and interpretations of quantum mechanics]
* [http://arxiv.org/abs/quant-ph/0505070 Measurements and Decoherence]
* [http://arxiv.org/pdf/0810.1919 The conditions for discrimination between quantum states with minimum error]
* [http://arxiv.org/abs/1001.3032 Quantum behavior of measurement apparatus]
 
{{DEFAULTSORT:Measurement In Quantum Mechanics}}
[[Category:Quantum measurement| ]]
[[Category:Quantum mechanics]]
[[Category:Philosophy of physics]]
 
[[ar:القياس في ميكانيكا الكم]]
[[fr:Problème de la mesure quantique]]
[[hi:क्वांटम यांत्रिकीय मापन]]
[[ja:観測問題]]

Latest revision as of 07:45, 25 June 2013

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The framework of quantum mechanics requires a careful definition of measurement. The issue of measurement lies at the heart of the problem of the interpretation of quantum mechanics, for which there is currently no consensus.

Measurement from a practical point of view

Measurement plays an important role in quantum mechanics, and it is viewed in different ways among various interpretations of quantum mechanics. In spite of considerable philosophical differences, different views of measurement almost universally agree on the practical question of what results from a routine quantum-physics laboratory measurement. To understand this, the Copenhagen interpretation, which has been commonly used,[1] is employed in this article.

Qualitative overview

In classical mechanics, a simple system consisting of only one single particle is fully described by the position x(t) and momentum p(t) of the particle. As an analogue, in quantum mechanics a system is described by its quantum state. In mathematical languages, all possible pure states of a system form a complete abstract vector space called Hilbert space, which is typically infinite-dimensional. A pure state is represented by a state vector (or precisely a ray) in the Hilbert space.

In the experimental aspect, once a quantum system has been prepared in laboratory, some measurable quantities such as position and energy are measured. That is, the dynamic state of the system is already in an eigenstate of some measurable quantities which is probably not the quantity that will be measured. For pedagogic reasons, the measurement is usually assumed to be ideally accurate. Hence, the dynamic state of a system after measurement is assumed to "collapse" into an eigenstate of the operator corresponding to the measurement. Repeating the same measurement without any significant evolution of the quantum state will lead to the same result. If the preparation is repeated, which does not put the system into the previous eigenstate, subsequent measurements will likely lead to different result. That is, the dynamic state collapses to different eigenstates.

The values obtained after the measurement is in general described by a probability distribution, which is determined by an "average" (or "expectation") of the measurement operator based on the quantum state of the prepared system.[2] The probability distribution is either continuous (such as position and momentum) or discrete (such as spin), depending on the quantity being measured.

The measurement process is often considered as random and indeterministic. Nonetheless, there is considerable dispute over this issue. In some interpretations of quantum mechanics, the result merely appears random and indeterministic, whereas in other interpretations the indeterminism is core and irreducible. A significant element in this disagreement is the issue of "collapse of the wavefunction" associated with the change in state following measurement. There are many philosophical issues and stances (and some mathematical variations) taken—and near universal agreement that we do not yet fully understand quantum reality. In any case, our descriptions of dynamics involve probabilities and averages.

Quantitative details

The mathematical relationship between the quantum state and the probability distribution is, again, widely accepted among physicists, and has been experimentally confirmed countless times. This section summarizes this relationship, which is stated in terms of the mathematical formulation of quantum mechanics.

Measurable quantities ("observables") as operators

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It is a postulate of quantum mechanics that all measurements have an associated operator (called an observable operator, or just an observable), with the following properties:

  1. The observable is a Hermitian (self-adjoint) operator mapping a Hilbert space (namely, the state space, which consists of all possible quantum states) into itself.
  2. Thus, the observable's eigenvectors (called an eigenbasis) form an orthonormal basis that span the state space in which that observable exists. Any quantum state can be represented as a superposition of the eigenstates of an observable.
  3. Hermitian operators' eigenvalues are real. The possible outcomes of a measurement are precisely the eigenvalues of the given observable.
  4. For each eigenvalue there are one or more corresponding eigenvectors (eigenstates). A measurement results in the system being in the eigenstate corresponding to the eigenvalue result of the measurement. If the eigenvalue determined from the measurement corresponds to more than one eigenstate ("degeneracy"), instead of being in a definite state, the system is in a sub-space of the measurement operator corresponding to all the states having that eigenvalue.

Important examples of observables are:

Operators can be noncommuting. Two Hermitian operators commute if (and only if) there is at least one basis of vectors, each of which is an eigenvector of both operators (this is sometimes called a simultaneous eigenbasis). Noncommuting observables are said to be incompatible and cannot in general be measured simultaneously. In fact, they are related by an uncertainty principle, as a direct consequence of the wave-like nature of the quantum postulate, and are associated with disturbance-due-to measurement due to the fundamental contributions of Werner Heisenberg.

Measurement probabilities and wavefunction collapse

There are a few possible ways to mathematically describe the measurement process (both the probability distribution and the collapsed wavefunction). The most convenient description depends on the spectrum (i.e., set of eigenvalues) of the observable.

Discrete, nondegenerate spectrum

Let O^ be an observable. By assumption, O^ has discrete eigenstates |1,|2,|3,... with corresponding distinct eigenvalues O1,O2,O3,.... That is, the states are nondegenerate.

Consider a system prepared in state |ψ. Since the eigenstates of the observable O^ form a complete basis called eigenbasis, the state vector |ψ can be written in terms of the eigenstates as

|ψ=c1|1+c2|2+c3|3+,

where c1,c2, are complex numbers in general. The eigenvalues O1,O2,O3,... are all possible values of the measurement. The corresponding probabilities are given by

Pr(On)=|n|ψ|2ψ|ψ=|cn|2k|ck|2

Usually |ψ is assumed to be normalized, i.e. ψ|ψ=1. Therefore, the expression above is reduced to

Pr(On)=|n|ψ|2=|cn|2

If the result of the measurement is On, then the system (after measurement) is in pure state |n. That is,

|ψ=|n

so any repeated measurement of O^ will yield the same result On. When there is a discontinuous change in state due to a measurement that involves discrete eigenvalues, that is called wavefunction collapse. For some, this is simply a description of a reasonably accurate discontinuous change in a mathematical representation of physical reality; for others, depending on philosophical orientation, this is a fundamentally serious problem with quantum theory.

Continuous, nondegenerate spectrum

Let O^ be an observable. By assumption, O^ has continuous eigenstate |x, with corresponding distinct eigenvalue x. The eigenvalue forms a continuous spectrum filling the interval (a,b).

Consider a system prepared in state |ψ. Since the eigenstates of the observable O^ form a complete basis called eigenbasis, the state vector |ψ can be written in terms of the eigenstates as

|ψ=abc(x)|xdx,

where c(x) is a complex-valued function. The eigenvalue that fills up the interval (a,b) is the possible value of measurement. The corresponding probability is described by a probability function given by

Pr(d<x<e)=de|x|ψ|2dxabψ|ψdx=de|c(x)|2dxab|c(x)|2dx

where (d,e)(a,b). Usually |ψ is assumed to be normalized, i.e. abψ|ψdx=1. Therefore, the expression above is reduced to

Pr(d<x<e)=de|c(x)|2dx

If the result of the measurement is x, then the system (after measurement) is in pure state |x. That is,

|ψ=|x.

Alternatively, it is often possible and convenient to analyze a continuous-spectrum measurement by taking it to be the limit of a different measurement with a discrete spectrum. For example, an analysis of scattering involves a continuous spectrum of energies, but by adding a "box" potential (which bounds the volume in which the particle can be found), the spectrum becomes discrete. By considering larger and larger boxes, this approach need not involve any approximation, but rather can be regarded as an equally valid formalism in which this problem can be analyzed.

Degenerate spectra

If there are multiple eigenstates with the same eigenvalue (called degeneracies), the analysis is a bit less simple to state, but not essentially different. In the discrete case, for example, instead of finding a complete eigenbasis, it is a bit more convenient to write the Hilbert space as a direct sum of eigenspaces. The probability of measuring a particular eigenvalue is the squared component of the state vector in the corresponding eigenspace, and the new state after measurement is the projection of the original state vector into the appropriate eigenspace.

Density matrix formulation

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. Instead of performing quantum-mechanics computations in terms of wavefunctions (kets), it is sometimes necessary to describe a quantum-mechanical system in terms of a density matrix. The analysis in this case is formally slightly different, but the physical content is the same, and indeed this case can be derived from the wavefunction formulation above. The result for the discrete, degenerate case, for example, is as follows:

Let O^ be an observable, and suppose that it has discrete eigenvalues O1,O2,O3,, associated with eigenspaces V1,V2, respectively. Let Pn be the projection operator into the space Vn.

Assume the system is prepared in the state described by the density matrix ρ. Then measuring O^ can yield any of the results O1,O2,O3,, with corresponding probabilities given by

Pr(On)=Tr(Pnρ)

where Tr denotes trace. If the result of the measurement is n, then the new density matrix will be

ρ=PnρPnTr(Pnρ)

Alternatively, one can say that the measurement process results in the new density matrix

ρ=nPnρPn

where the difference is that ρ is the density matrix describing the entire ensemble, whereas ρ is the density matrix describing the sub-ensemble whose measurement result was n.

Statistics of measurement

As detailed above, the result of measuring a quantum-mechanical system is described by a probability distribution. Some properties of this distribution are as follows:

Suppose we take a measurement corresponding to observable O^, on a state whose quantum state is |ψ.

ψ|O^|ψ.
ψ|O^2|ψ(ψ|O^|ψ)2
ψ|O^2|ψ(ψ|O^|ψ)2

These are direct consequences of the above formulas for measurement probabilities.

Example

Suppose that we have a particle in a 1-dimensional box, set up initially in the ground state |ψ1. As can be computed from the time-independent Schrödinger equation, the energy of this state is E1=π222mL2 (where m is the particle's mass and L is the box length), and the spatial wavefunction is x|ψ1=2Lsin(πxL). If the energy is now measured, the result will always certainly be E1, and this measurement will not affect the wavefunction.

Next suppose that the particle's position is measured. The position x will be measured with probability density

Pr(S<x<S+dS)=2Lsin2(πSL)dS.

If the measurement result was x=S, then the wavefunction after measurement will be the position eigenstate |x=S. If the particle's position is immediately measured again, the same position will be obtained.

The new wavefunction |x=S can, like any wavefunction, be written as a superposition of eigenstates of any observable. In particular, using energy eigenstates, |ψn, we have

|x=S=n|ψnψn|x=S=n|ψn2Lsin(nπSL)

If we now leave this state alone, it will smoothly evolve in time according to the Schrödinger equation. But suppose instead that an energy measurement is immediately taken. Then the possible energy values En will be measured with relative probabilities:

Pr(En)=|ψn|S|2=2Lsin2(nπSL)

and moreover if the measurement result is En, then the new state will be the energy eigenstate |ψn.

So in this example, due to the process of wavefunction collapse, a particle initially in the ground state can end up in any energy level, after just two subsequent non-commuting measurements are made.

Wavefunction collapse

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. The process in which a quantum state becomes one of the eigenstates of the operator corresponding to the measured observable is called "collapse", or "wavefunction collapse". The final eigenstate appears randomly with a probability equal to the square of its overlap with the original state.[2] The process of collapse has been studied in many experiments, most famously in the double-slit experiment. The wavefunction collapse raises serious questions regarding "the measurement problem",[3] as well as questions of determinism and locality, as demonstrated in the EPR paradox and later in GHZ entanglement. (See below.)

In the last few decades, major advances have been made toward a theoretical understanding of the collapse process. This new theoretical framework, called quantum decoherence, supersedes previous notions of instantaneous collapse and provides an explanation for the absence of quantum coherence after measurement. Decoherence correctly predicts the form and probability distribution of the final eigenstates, and explains the apparent randomness of the choice of final state in terms of einselection.[4]

von Neumann measurement scheme

The von Neumann measurement scheme, the ancestor of quantum decoherence theory, describes measurements by taking into account the measuring apparatus which is also treated as a quantum object. Let the quantum state be in the superposition |ψ=ncn|ψn, where |ψn are eigenstates of the operator for the measurement prior to von Neumann's second apparatus. In order to make the measurement, the system described by |ψ needs to interact with the measuring apparatus described by the quantum state |ϕ, so that the total wave function before the measurement and interaction with the second apparatus is |ψ|ϕ. During the interaction of object and measuring instrument the unitary evolution is supposed to realize the following transition from the initial to the final total wave function:

|ψ|ϕncn|ψn|ϕn(measurement of the first kind),

where |ϕn are orthonormal states of the measuring apparatus. The unitary evolution above is referred to as premeasurement. The relation with wave function collapse is established by calculating the final density operator of the object n|cn|2|ψnψn| from the final total wave function. This density operator is interpreted by von Neumann as describing an ensemble of objects being after the measurement with probability |cn|2 in the state |ψn.

The transition

|ψn|cn|2|ψnψn|

is often referred to as weak von Neumann projection, the wave function collapse or strong von Neumann projection

|ψn|cn|2|ψnψn||ψn

being thought to correspond to an additional selection of a subensemble by means of observation.

In case the measured observable has a degenerate spectrum, weak von Neumann projection is generalized to Lüders projection

|ψn|cn|2Pn,Pn=i|ψniψni|,

in which the vectors |ψni for fixed n are the degenerate eigenvectors of the measured observable. For an arbitrary state described by a density operator ρ Lüders projection is given by

ρnPnρPn.

Measurements of the second kind

In a measurement of the second kind the unitary evolution during the interaction of object and measuring instrument is supposed to be given by

|ψ|ϕncn|χn|ϕn,

in which the states |χn of the object are determined by specific properties of the interaction between object and measuring instrument. They are normalized but not necessarily mutually orthogonal. The relation with wave function collapse is analogous to that obtained for measurements of the first kind, the final state of the object now being |χn with probability |cn|2. Note that many present-day measurement procedures are measurements of the second kind, some even functioning correctly only as a consequence of being of the second kind. For instance, a photon counter, detecting a photon by absorbing and hence annihilating it, thus ideally leaving the electromagnetic field in the vacuum state rather than in the state corresponding to the number of detected photons; also the Stern–Gerlach experiment would not function at all if it really were a measurement of the first kind.[5]

Decoherence in quantum measurement

One can also introduce the interaction with the environment |e, so that, in a measurement of the first kind, after the interaction the total wave function takes a form

ncn|ψn|ϕn|en,

which is related to the phenomenon of decoherence.

The above is completely described by the Schrödinger equation and there are not any interpretational problems with this. Now the problematic wavefunction collapse does not need to be understood as a process |ψ|ψn on the level of the measured system, but can also be understood as a process |ϕ|ϕn on the level of the measuring apparatus, or as a process |e|en on the level of the environment. Studying these processes provides considerable insight into the measurement problem by avoiding the arbitrary boundary between the quantum and classical worlds, though it does not explain the presence of randomness in the choice of final eigenstate. If the set of states

{|ψn}, {|ϕn}, or {|en}

represents a set of states that do not overlap in space, the appearance of collapse can be generated by either the Bohm interpretation or the Everett interpretation which both deny the reality of wavefunction collapse. Both of these are stated to predict the same probabilities for collapses to various states as the conventional interpretation by their supporters. The Bohm interpretation is held to be correct only by a small minority of physicists, since there are difficulties with the generalization for use with relativistic quantum field theory. However, there is no proof that the Bohm interpretation is inconsistent with quantum field theory, and work to reconcile the two is ongoing. The Everett interpretation easily accommodates relativistic quantum field theory.

Philosophical problems of quantum measurements

What physical interaction constitutes a measurement?

Until the advent of quantum decoherence theory in the late 20th century, a major conceptual problem of quantum mechanics and especially the Copenhagen interpretation was the lack of a distinctive criterion for a given physical interaction to qualify as "a measurement" and cause a wavefunction to collapse. This is best illustrated by the Schrödinger's cat paradox. Certain aspects of this question are now well understood in the framework of quantum decoherence theory, such as an understanding of weak measurements, and quantifying what measurements or interactions are sufficient to destroy quantum coherence. Nevertheless, there remains less than universal agreement among physicists on some aspects of the question of what constitutes a measurement.

Does measurement actually determine the state?

The question of whether (and in what sense) a measurement actually determines the state is one which differs among the different interpretations of quantum mechanics. (It is also closely related to the understanding of wavefunction collapse.) For example, in most versions of the Copenhagen interpretation, the measurement determines the state, and after measurement the state is definitely what was measured. But according to the many-worlds interpretation, measurement determines the state in a more restricted sense: In other "worlds", other measurement results were obtained, and the other possible states still exist.

Is the measurement process random or deterministic?

As described above, there is universal agreement that quantum mechanics appears random, in the sense that all experimental results yet uncovered can be predicted and understood in the framework of quantum mechanics measurements being fundamentally random. Nevertheless, it is not settled[6] whether this is true, fundamental randomness, or merely "emergent" randomness resulting from underlying hidden variables which deterministically cause measurement results to happen a certain way each time. This continues to be an area of active research.[7]

If there are hidden variables, they would have to be "nonlocal".

Does the measurement process violate locality?

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In physics, the Principle of locality is the concept that information cannot travel faster than the speed of light (also see special relativity). It is known experimentally (see Bell's theorem, which is related to the EPR paradox) that if quantum mechanics is deterministic (due to hidden variables, as described above), then it is nonlocal (i.e. violates the principle of locality). Nevertheless, there is not universal agreement among physicists on whether quantum mechanics is nondeterministic, nonlocal, or both.[6]

See also

References

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Further reading

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    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  • 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  • 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534

External links

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  1. Hermann Wimmel (1992). Quantum physics & observed reality: a critical interpretation of quantum mechanics. World Scientific. p. 2. ISBN 978-981-02-1010-6. Retrieved 9 May 2011.
  2. 2.0 2.1 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  3. 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  4. Wojciech H. Zurek, Decoherence, einselection, and the quantum origins of the classical,Reviews of Modern Physics 2003, 75, 715 or http://arxiv.org/abs/quant-ph/0105127
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    There are various methods to go about discovering the precise property. Some local newspapers (together with the Straits Instances ) have categorised property sections and many local property brokers have websites. Now there are some specifics to consider when buying a 'new launch' rental. Intended use of the unit Every sale begins with 10 p.c low cost for finish of season sale; changes to 20 % discount storewide; follows by additional reduction of fiftyand ends with last discount of 70 % or extra. Typically there is even a warehouse sale or transferring out sale with huge mark-down of costs for stock clearance. Deborah Regulation from Expat Realtor shares her property market update, plus prime rental residences and houses at the moment available to lease Esparina EC @ Sengkang
  6. 6.0 6.1 One of the biggest reasons investing in a Singapore new launch is an effective things is as a result of it is doable to be lent massive quantities of money at very low interest rates that you should utilize to purchase it. Then, if property values continue to go up, then you'll get a really high return on funding (ROI). Simply make sure you purchase one of the higher properties, reminiscent of the ones at Fernvale the Riverbank or any Singapore landed property Get Earnings by means of Renting

    In its statement, the singapore property listing - website link, government claimed that the majority citizens buying their first residence won't be hurt by the new measures. Some concessions can even be prolonged to chose teams of consumers, similar to married couples with a minimum of one Singaporean partner who are purchasing their second property so long as they intend to promote their first residential property. Lower the LTV limit on housing loans granted by monetary establishments regulated by MAS from 70% to 60% for property purchasers who are individuals with a number of outstanding housing loans on the time of the brand new housing purchase. Singapore Property Measures - 30 August 2010 The most popular seek for the number of bedrooms in Singapore is 4, followed by 2 and three. Lush Acres EC @ Sengkang

    Discover out more about real estate funding in the area, together with info on international funding incentives and property possession. Many Singaporeans have been investing in property across the causeway in recent years, attracted by comparatively low prices. However, those who need to exit their investments quickly are likely to face significant challenges when trying to sell their property – and could finally be stuck with a property they can't sell. Career improvement programmes, in-house valuation, auctions and administrative help, venture advertising and marketing, skilled talks and traisning are continuously planned for the sales associates to help them obtain better outcomes for his or her shoppers while at Knight Frank Singapore. No change Present Rules

    Extending the tax exemption would help. The exemption, which may be as a lot as $2 million per family, covers individuals who negotiate a principal reduction on their existing mortgage, sell their house short (i.e., for lower than the excellent loans), or take part in a foreclosure course of. An extension of theexemption would seem like a common-sense means to assist stabilize the housing market, but the political turmoil around the fiscal-cliff negotiations means widespread sense could not win out. Home Minority Chief Nancy Pelosi (D-Calif.) believes that the mortgage relief provision will be on the table during the grand-cut price talks, in response to communications director Nadeam Elshami. Buying or promoting of blue mild bulbs is unlawful.

    A vendor's stamp duty has been launched on industrial property for the primary time, at rates ranging from 5 per cent to 15 per cent. The Authorities might be trying to reassure the market that they aren't in opposition to foreigners and PRs investing in Singapore's property market. They imposed these measures because of extenuating components available in the market." The sale of new dual-key EC models will even be restricted to multi-generational households only. The models have two separate entrances, permitting grandparents, for example, to dwell separately. The vendor's stamp obligation takes effect right this moment and applies to industrial property and plots which might be offered inside three years of the date of buy. JLL named Best Performing Property Brand for second year running

    The data offered is for normal info purposes only and isn't supposed to be personalised investment or monetary advice. Motley Fool Singapore contributor Stanley Lim would not personal shares in any corporations talked about. Singapore private home costs increased by 1.eight% within the fourth quarter of 2012, up from 0.6% within the earlier quarter. Resale prices of government-built HDB residences which are usually bought by Singaporeans, elevated by 2.5%, quarter on quarter, the quickest acquire in five quarters. And industrial property, prices are actually double the levels of three years ago. No withholding tax in the event you sell your property. All your local information regarding vital HDB policies, condominium launches, land growth, commercial property and more

    There are various methods to go about discovering the precise property. Some local newspapers (together with the Straits Instances ) have categorised property sections and many local property brokers have websites. Now there are some specifics to consider when buying a 'new launch' rental. Intended use of the unit Every sale begins with 10 p.c low cost for finish of season sale; changes to 20 % discount storewide; follows by additional reduction of fiftyand ends with last discount of 70 % or extra. Typically there is even a warehouse sale or transferring out sale with huge mark-down of costs for stock clearance. Deborah Regulation from Expat Realtor shares her property market update, plus prime rental residences and houses at the moment available to lease Esparina EC @ Sengkang
  7. One of the biggest reasons investing in a Singapore new launch is an effective things is as a result of it is doable to be lent massive quantities of money at very low interest rates that you should utilize to purchase it. Then, if property values continue to go up, then you'll get a really high return on funding (ROI). Simply make sure you purchase one of the higher properties, reminiscent of the ones at Fernvale the Riverbank or any Singapore landed property Get Earnings by means of Renting

    In its statement, the singapore property listing - website link, government claimed that the majority citizens buying their first residence won't be hurt by the new measures. Some concessions can even be prolonged to chose teams of consumers, similar to married couples with a minimum of one Singaporean partner who are purchasing their second property so long as they intend to promote their first residential property. Lower the LTV limit on housing loans granted by monetary establishments regulated by MAS from 70% to 60% for property purchasers who are individuals with a number of outstanding housing loans on the time of the brand new housing purchase. Singapore Property Measures - 30 August 2010 The most popular seek for the number of bedrooms in Singapore is 4, followed by 2 and three. Lush Acres EC @ Sengkang

    Discover out more about real estate funding in the area, together with info on international funding incentives and property possession. Many Singaporeans have been investing in property across the causeway in recent years, attracted by comparatively low prices. However, those who need to exit their investments quickly are likely to face significant challenges when trying to sell their property – and could finally be stuck with a property they can't sell. Career improvement programmes, in-house valuation, auctions and administrative help, venture advertising and marketing, skilled talks and traisning are continuously planned for the sales associates to help them obtain better outcomes for his or her shoppers while at Knight Frank Singapore. No change Present Rules

    Extending the tax exemption would help. The exemption, which may be as a lot as $2 million per family, covers individuals who negotiate a principal reduction on their existing mortgage, sell their house short (i.e., for lower than the excellent loans), or take part in a foreclosure course of. An extension of theexemption would seem like a common-sense means to assist stabilize the housing market, but the political turmoil around the fiscal-cliff negotiations means widespread sense could not win out. Home Minority Chief Nancy Pelosi (D-Calif.) believes that the mortgage relief provision will be on the table during the grand-cut price talks, in response to communications director Nadeam Elshami. Buying or promoting of blue mild bulbs is unlawful.

    A vendor's stamp duty has been launched on industrial property for the primary time, at rates ranging from 5 per cent to 15 per cent. The Authorities might be trying to reassure the market that they aren't in opposition to foreigners and PRs investing in Singapore's property market. They imposed these measures because of extenuating components available in the market." The sale of new dual-key EC models will even be restricted to multi-generational households only. The models have two separate entrances, permitting grandparents, for example, to dwell separately. The vendor's stamp obligation takes effect right this moment and applies to industrial property and plots which might be offered inside three years of the date of buy. JLL named Best Performing Property Brand for second year running

    The data offered is for normal info purposes only and isn't supposed to be personalised investment or monetary advice. Motley Fool Singapore contributor Stanley Lim would not personal shares in any corporations talked about. Singapore private home costs increased by 1.eight% within the fourth quarter of 2012, up from 0.6% within the earlier quarter. Resale prices of government-built HDB residences which are usually bought by Singaporeans, elevated by 2.5%, quarter on quarter, the quickest acquire in five quarters. And industrial property, prices are actually double the levels of three years ago. No withholding tax in the event you sell your property. All your local information regarding vital HDB policies, condominium launches, land growth, commercial property and more

    There are various methods to go about discovering the precise property. Some local newspapers (together with the Straits Instances ) have categorised property sections and many local property brokers have websites. Now there are some specifics to consider when buying a 'new launch' rental. Intended use of the unit Every sale begins with 10 p.c low cost for finish of season sale; changes to 20 % discount storewide; follows by additional reduction of fiftyand ends with last discount of 70 % or extra. Typically there is even a warehouse sale or transferring out sale with huge mark-down of costs for stock clearance. Deborah Regulation from Expat Realtor shares her property market update, plus prime rental residences and houses at the moment available to lease Esparina EC @ Sengkang