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{{ArticleIcons|ultimate=y}}
{{Use American English|date = February 2019}}
{{disambig2|Greninja's appearance in ''Super Smash Bros. Ultimate''|the character in other contexts|Greninja}}
{{Short description|Important, well-understood quantum mechanical model}}
{{Infobox Character
{{Quantum mechanics}}
|name = Greninja
{{redirect|QHO|text=It is also the [[IATA airport code]] for [[Transportation in Houston#Airports|all airports in the Houston area]]}}
|image = [[File:Greninja SSBU.png|250px]]
 
|game = SSBU
[[File:QuantumHarmonicOscillatorAnimation.gif|thumb|300px|right|Some trajectories of a [[harmonic oscillator]] according to [[Newton's laws]] of [[classical mechanics]] (A–B), and according to the [[Schrödinger equation]] of [[quantum mechanics]] (C–H). In A–B, the particle (represented as a ball attached to a [[Hooke's law|spring]]) oscillates back and forth. In C–H, some solutions to the Schrödinger Equation are shown, where the horizontal axis is position, and the vertical axis is the real part (blue) or imaginary part (red) of the [[wavefunction]]. C, D, E, F, but not G, H, are [[energy eigenstate]]s. H is a [[Coherent states|coherent state]]—a quantum state that approximates the classical trajectory.]]
|ssbgame1 = SSB4
 
|availability = [[Unlockable character|Unlockable]]
The '''quantum harmonic oscillator''' is the [[quantum mechanics|quantum-mechanical]] analog of the [[harmonic oscillator|classical harmonic oscillator]]. Because an arbitrary smooth [[Potential energy|potential]] can usually be approximated as a [[Harmonic oscillator#Simple harmonic oscillator|harmonic potential]] at the vicinity of a stable [[equilibrium point]],  it is one of the most important model systems in quantum mechanics. Furthermore, it is one of the few quantum-mechanical systems for which an exact, [[List_of_quantum-mechanical_systems_with_analytical_solutions|analytical solution]] is known.<ref>{{Cite book | author=Griffiths, David J. | title=Introduction to Quantum Mechanics | edition=2nd | publisher=Prentice Hall | year=2004 | isbn=978-0-13-805326-0 | author-link=David Griffiths (physicist) | url-access=registration | url=https://archive.org/details/introductiontoel00grif_0 }}</ref><ref>{{Cite book| author=Liboff, Richard L. | title=Introductory Quantum Mechanics | publisher=Addison–Wesley | year=2002 | isbn=978-0-8053-8714-8| author-link=Liboff, Richard L.}}</ref><ref>{{Cite web | last =Rashid | first =Muneer A. | author-link =Munir Ahmad Rashid | title =Transition amplitude for time-dependent linear harmonic oscillator with Linear time-dependent terms added to the Hamiltonian | website =M.A. Rashid – [[National University of Sciences and Technology, Pakistan|Center for Advanced Mathematics and Physics]] | publisher =[[National Center for Physics]] | year =2006 | url =http://www.ncp.edu.pk/docs/12th_rgdocs/Munir-Rasheed.pdf | format =[[PDF]]-[[Microsoft PowerPoint]] | access-date =19 October 2010 }}</ref>
}}
 
'''Greninja''' ({{ja|ゲッコウガ|Gekkōga}}, ''Gekkouga'') is a playable character in ''[[Super Smash Bros. Ultimate]]''. It was officially revealed on June 12th, 2018 alongside {{SSBU|Mr. Game & Watch}} and the rest of the returning roster. Greninja is classified as [[Fighter number|Fighter #50]].
==One-dimensional harmonic oscillator==
 
===Hamiltonian and energy eigenstates===
[[Image:HarmOsziFunktionen.png|thumb|Wavefunction representations for the first eight bound eigenstates, ''n'' = 0 to 7. The horizontal axis shows the position ''x''.]]
[[Image:Aufenthaltswahrscheinlichkeit harmonischer Oszillator.png|thumb|Corresponding probability densities.]]
 
The [[Hamiltonian (quantum mechanics)|Hamiltonian]] of the particle is:
<math display="block">\hat H = \frac{{\hat p}^2}{2m} + \frac{1}{2} k {\hat x}^2 = \frac{{\hat p}^2}{2m} + \frac{1}{2} m \omega^2 {\hat x}^2 \, ,</math>
where {{mvar|m}} is the particle's mass, {{mvar|k}} is the force constant, <math display="inline">\omega = \sqrt{k / m}</math> is the [[angular frequency]] of the oscillator, <math>\hat{x}</math> is the [[position operator]] (given by {{mvar|x}} in the coordinate basis), and <math>\hat{p}</math>  is the [[momentum operator]] (given by <math>\hat p = -i \hbar \, \partial / \partial x</math> in the coordinate basis). The first term in the Hamiltonian represents the kinetic energy of the particle, and the second term represents its potential energy, as in [[Hooke's law]].
 
One may write the time-independent [[Schrödinger equation]],
<math display="block"> \hat H \left| \psi \right\rangle = E \left| \psi \right\rangle  ~,</math>
where {{mvar|E}} denotes a to-be-determined real number that will specify a time-independent [[energy level]], or [[eigenvalue]], and the solution  {{math|{{!}}''ψ''⟩}} denotes that level's energy [[eigenstate]].
 
One may solve the differential equation representing this eigenvalue problem in the coordinate basis, for the [[wave function]] {{math|1=⟨''x''{{!}}''ψ''⟩ = ''ψ''(''x'')}}, using a [[spectral method]]. It turns out that there is a family of solutions. In this basis, they amount to [[Hermite polynomials#Hermite functions| Hermite functions]],
<math display="block"> \psi_n(x) = \frac{1}{\sqrt{2^n\,n!}}  \left(\frac{m\omega}{\pi \hbar}\right)^{1/4}  e^{
- \frac{m\omega x^2}{2 \hbar}} H_n\left(\sqrt{\frac{m\omega}{\hbar}} x \right), \qquad n = 0,1,2,\ldots. </math>
 
The functions ''H<sub>n</sub>'' are the physicists' [[Hermite polynomials]],
<math display="block">H_n(z)=(-1)^n~ e^{z^2}\frac{d^n}{dz^n}\left(e^{-z^2}\right).</math>
 
The corresponding energy levels are
<math display="block"> E_n = \hbar \omega\bigl(n + \tfrac{1}{2}\bigr)=(2 n + 1) {\hbar \over 2} \omega~.</math>
 
This energy spectrum is noteworthy for three reasons.  First, the energies are quantized, meaning that only discrete energy values (integer-plus-half multiples of {{math|''ħω''}}) are possible; this is a general feature of quantum-mechanical systems when a particle is confined. Second, these discrete energy levels are equally spaced, unlike in the [[Bohr model]] of the atom, or the [[particle in a box]]. Third, the lowest achievable energy (the energy of the {{math|1=''n'' = 0}} state, called the [[ground state]]) is not equal to the minimum of the potential well, but {{math|''ħω''/2}} above it; this is called [[zero-point energy]]. Because of the zero-point energy, the position and momentum of the oscillator in the ground state are not fixed (as they would be in a classical oscillator), but have a small range of variance, in accordance with the [[Heisenberg uncertainty principle]].
 
The ground state probability density is concentrated at the origin, which means the particle spends most of its time at the bottom of the potential well, as one would expect for a state with little energy. As the energy increases, the probability density peaks at the classical "turning points", where the state's energy coincides with the potential energy. (See the discussion below of the highly excited states.) This is consistent with the classical harmonic oscillator, in which the particle spends more of its time (and is therefore more likely to be found) near the turning points, where it is moving the slowest. The [[correspondence principle]] is thus satisfied. Moreover, special nondispersive [[wave packet]]s, with minimum uncertainty,  called [[Coherent states#The wavefunction of a coherent state|coherent states]] oscillate very much like classical objects, as illustrated in the figure; they are ''not'' eigenstates of the Hamiltonian.
 
===Ladder operator method===
[[Image:QHarmonicOscillator.png|right|thumb|Probability densities <nowiki>|</nowiki>''ψ<sub>n</sub>''(''x'')<nowiki>|</nowiki><sup>2</sup> <!--or in pseudoTeX: <math>\left |\psi_n(x)\right |^2</math> --> for the bound eigenstates, beginning with the ground state (''n'' = 0) at the bottom and increasing in energy toward the top. The horizontal axis shows the position {{mvar|x}}, and brighter colors represent higher probability densities.]]
 
The "[[ladder operator]]" method, developed by [[Paul Dirac]], allows extraction of the energy eigenvalues without directly solving the differential equation. It is generalizable to more complicated problems, notably in [[quantum field theory]].  Following this approach, we define the operators {{mvar|a}} and its [[Hermitian adjoint|adjoint]] {{math|''a''<sup>†</sup>}},
<math display="block">\begin{align}
          a &=\sqrt{m\omega \over 2\hbar} \left(\hat x + {i \over m \omega} \hat p \right) \\
  a^\dagger &=\sqrt{m\omega \over 2\hbar} \left(\hat x - {i \over m \omega} \hat p \right)
\end{align}</math>Note these operators classically are exactly the [[Generator (mathematics)|generators]] of normalized rotation in the phase space of <math>x</math> and <math>m\frac{dx}{dt}</math>, ''i.e'' they describe the forwards and backwards evolution in time of a classical harmonic oscillator.
 
These operators lead to the useful representation of <math>\hat{x}</math> and  <math>\hat{p}</math>,
<math display="block">\begin{align}
  \hat x &=  \sqrt{\frac{\hbar}{2 m\omega}}(a^\dagger + a) \\
  \hat p &= i\sqrt{\frac{\hbar m \omega}{2}}(a^\dagger - a) ~.
\end{align}</math>
 
The operator {{mvar|a}} is not [[Hermitian operator|Hermitian]], since itself and its adjoint {{math|''a''<sup>†</sup>}} are not equal. The energy eigenstates {{math|{{ket|''n''}}}} (also known as [[Fock state|Fock states]]), when operated on by these ladder operators, give
<math display="block">\begin{align}
  a^\dagger|n\rangle &= \sqrt{n + 1} | n + 1\rangle \\
          a|n\rangle &= \sqrt{n} | n - 1\rangle.
\end{align}</math>
 
It is then evident that {{math|''a''<sup>†</sup>}}, in essence, appends a single quantum of energy to the oscillator, while {{mvar|a}} removes a quantum. For this reason, they are sometimes referred to as "creation" and "annihilation" operators.
 
From the relations above, we can also define a number operator {{mvar|N}}, which has the following property:
<math display="block">\begin{align}
                        N &= a^\dagger a \\
  N\left| n \right\rangle &= n\left| n \right\rangle.
\end{align}</math>
 
The following [[commutator]]s can be easily obtained by substituting the [[canonical commutation relation]],
<math display="block">[a, a^\dagger] = 1,\qquad[N, a^\dagger] = a^{\dagger},\qquad[N, a] = -a, </math>
 
And the Hamilton operator can be expressed as
<math display="block">\hat H = \hbar\omega\left(N + \frac{1}{2}\right),</math>
 
so the eigenstate of {{mvar|N}} is also the eigenstate of energy.


Billy Bob Thompson, Yūji Ueda, Frédéric Clou and Benedikt Gutjan's portrayals of Greninja from ''Super Smash Bros. 4'' were repurposed for the English, Japanese, French and German versions of ''Ultimate'', respectively.
The commutation property yields
<math display="block">\begin{align}
  Na^{\dagger}|n\rangle &= \left(a^\dagger N + [N, a^\dagger]\right)|n\rangle \\
                        &= \left(a^\dagger N + a^\dagger\right)|n\rangle \\
                        &= (n + 1)a^\dagger|n\rangle,
\end{align} </math>


==How to unlock==
and similarly,
Complete one of the following:
<math display="block">Na|n\rangle = (n - 1)a | n \rangle.</math>
*Play [[VS. match]]es, with Greninja being the 58th character to be unlocked.
*Clear {{SSBU|Classic Mode}} with {{SSBU|Donkey Kong}} or any character in his unlock tree, being the 6th character unlocked after {{SSBU|Sheik}}.
*Have Greninja join the player's party in [[World of Light]].
Greninja must then be defeated on [[Kalos Pokémon League]] (the [[Ω form]] is used in World of Light).


==Attributes==
This means that {{mvar|a}} acts on  {{math|{{!}}''n''⟩}}  to produce, up to a multiplicative constant,   {{math|{{!}}''n''–1⟩}}, and {{math|''a''<sup>†</sup>}} acts on  {{math|{{!}}''n''⟩}} to produce {{math|{{!}}''n''+1⟩}}. For this reason, {{mvar|a}} is called a '''annihilation operator''' ("lowering operator"), and {{math|''a''<sup>†</sup>}} a '''creation operator''' ("raising operator"). The two operators together are called [[ladder operator]]s. In quantum field theory, {{mvar|a}} and {{math|''a''<sup>†</sup>}} are alternatively called "annihilation" and "creation" operators because they destroy and create particles, which correspond to our quanta of energy.
Greninja, true to being a ninja-themed character, has very strong mobility; it has the 8th fastest [[dash|run speed]], the 10th fastest [[air speed]], is tied for the 9th fastest [[fall speed|falling ]] (and [[fast fall|fast falling]]) speed, the 2nd highest [[gravity]], and possesses the 2nd highest [[jump|jump height]] overall. However, unlike most characters who boast similar mobility (such as {{SSBU|Sheik}}), Greninja boasts a surprising amount of KO options, good range on plenty of its attacks, and KO throws.


One of Greninja's most notable traits is its high mobility which complements its grounded moveset. Greninja's dash attack comes out on frame 7 and has very low ending lag, as well as the ability to cross upon shields. Its knockback angle allows for many true follow-ups and strings over a large range of percents. Its neutral jab attack comes out on frame 3, making it a good grounded combo breaker. It can also lock, which gives Greninja access to potent punishes from opponents missing techs. Its down tilt is an excellent combo starter due to its low startup, ending lag and vertical launch angle. Greninja's up tilt is a frame 9 disjointed hitbox that acts well as an anti-air and can also be a combo starter. Its smash attacks are also reliable in their own right; its forward smash is quick for its range and power, down smash is an excellent punishment option for ledge regrabs, as well as sending at a low angle, and up smash is a potent combo finisher.
Given any energy eigenstate, we can act on it with the lowering operator, {{mvar|a}}, to produce another eigenstate with {{math|''ħω''}} less energy. By repeated application of the lowering operator, it seems that we can produce energy eigenstates down to {{math|1=''E'' = −∞}}. However, since
<math display="block">n = \langle n | N | n \rangle = \langle n | a^\dagger a | n \rangle = \Bigl(a | n \rangle \Bigr)^\dagger a | n \rangle \geqslant 0,</math>


Greninja also has a very strong air game due to its aforementioned air speed and jump height. Greninja's aerials are reliable for multiple situations and all have low landing lag (except for down aerial, at 30 frames). Its neutral aerial is a decent low percent combo starter due to it having incredibly low landing lag and a good launch angle. It can also KO at high percentages. Its forward aerial acts as a combo finisher from its combo starters and can KO moderately early. Forward aerial's low landing lag and disjointed nature also make it safe on shield in many situations when spaced correctly. Its up aerial is a great juggling option with low all-around lag and boasting good KO potential near the upper blast line. Greninja can also utilize its multihits to drag down opponents to create tech chase and jab lock situations. Its back aerial is a very fast follow up or offstage edgeguarding option. Down aerial can be used as a mix up to return to the stage from far above, as well as perform surprise combos on hit with both its [[meteor smash]] and sourspot hitbox.
the smallest eigen-number is 0, and
<math display="block">a \left| 0 \right\rangle = 0. </math>


Greninja's grab game is overall very effective, due to its grabs being among the longest ranges of any non-tether grab in the game. Its forward, up, and back throws can KO at high percentages. Down throw acts as a middle percent combo starter, as well as a strong DI mix up, especially at higher percentages at ledge as a 50/50 between DI in and out in conjunction with forward throw. Up throw acts as a versatile combo starter that can lead to juggling situations. Because of this, Greninja has plenty of options off of a grab, as not one of its throws could be considered useless.
In this case, subsequent applications of the lowering operator will just produce zero kets, instead of additional energy eigenstates. Furthermore, we have shown above that
<math display="block">\hat H \left|0\right\rangle = \frac{\hbar\omega}{2} \left|0\right\rangle</math>


Finally, Greninja's special moves are effective in various situations. [[Water Shuriken]] acts as a versatile zoning tool, as well as a high-percentage KO option when fully charged. At low-to-mid percents, it is also a combo starter, allowing Greninja to rush down its opponent and follow up with any aerial attack or an up smash. [[Shadow Sneak]] works as an effective recovery mix up, as well as a potent KO move from a good read or pseudo-combo finisher. Despite lacking an offensive hitbox, [[Hydro Pump]] is a good recovery move for its long distance, and can be used for gimping recoveries due to having windbox properties. [[Substitute]] is a counterattack with the unique attribute of being able to be aimed in one of 8 different directions upon a successful counter. These angled follow ups allow for Greninja to gain pseudo-follow ups as well as KO earlier by picking the optimal angle in regards to stage positioning.
Finally, by acting on  |0⟩ with the raising operator and multiplying by suitable [[Wave function#Normalization condition|normalization factors]], we can produce an infinite set of energy eigenstates
<math display="block">\left\{\left| 0 \right\rangle, \left| 1 \right\rangle, \left| 2 \right\rangle, \ldots , \left| n \right\rangle, \ldots\right\},</math>


Like all characters, Greninja is flawed in many ways. One of Greninja's primary flaws is its inability to break out of disadvantage state. While not as bad as the previous game, Greninja still has difficulties escaping combos due to its fast falling speed and its aerials still having relatively high startup. This can sometimes be alleviated with its back or down aerials, but both are not very effective due to back aerial's almost entirely horizontal hitboxes and down aerial's landing lag. Another option is aerial Water Shuriken, which stalls Greninja in the air and can be used as a landing mix up, as well as Hydro Pump landing mix ups.  
such that
<math display="block">\hat H \left| n \right\rangle = \hbar\omega \left( n + \frac{1}{2} \right) \left| n \right\rangle, </math>
which matches the energy spectrum given in the preceding section.


Greninja's biggest weakness however, is its terrible out of shield game, which is arguably the worst of the entire cast. Because of its high short hop, its aerials slow startup, and lacking a fast grab (although it has good range), Greninja lacks an effective out of shield option faster than frame 14. While its back aerial is fairly quick at frame 5 (making it frame 8 out of shield), it is unable to hit opponents in front of Greninja and is very inconsistent at hitting opponents behind Greninja due to its high short hop. Jumping or rolling out of shield are potential options to reset neutral, but they are very predictable and easily read. Thus, when Greninja is pinned down in shield, it has difficulty escaping the situation without being heavily punished. Combined with its vulnerability to combos, this gives it an atrocious defensive game.  
Arbitrary eigenstates can be expressed in terms of |0⟩,
<math display="block">|n\rangle = \frac{(a^\dagger)^n}{\sqrt{n!}} |0\rangle. </math>
{{math proof|<math display="block">\begin{align}
  \langle n | aa^\dagger | n \rangle &= \langle n|\left([a, a^\dagger] + a^\dagger a\right)| n \rangle = \langle n|(N + 1)|n\rangle = n + 1 \\
    \Rightarrow a^\dagger | n\rangle &= \sqrt{n + 1} | n + 1\rangle \\
                    \Rightarrow|n\rangle &= \frac{a^\dagger}{\sqrt{n}} | n - 1 \rangle = \frac{(a^\dagger)^2}{\sqrt{n(n - 1)}} | n - 2 \rangle = \cdots = \frac{(a^\dagger)^n}{\sqrt{n!}}|0\rangle.
\end{align}</math>}}


Altogether, Greninja's playstyle requires players to think like an actual ninja: utilizing Greninja's superb mobility and fast attacks to rush down opponents, saving the slower attacks for potential mixups, mindgames and surprise KO options, and remaining unpredictable to prevent being trapped into disadvantageous positions.
====Analytical questions====


==Changes from ''[[Super Smash Bros. 4]]''==
The preceding analysis is algebraic, using only the commutation relations between the raising and lowering operators. Once the algebraic analysis is complete, one should turn to analytical questions. First, one should find the ground state, that is, the solution of the equation <math>a\psi_0 = 0</math>. In the position representation, this is the first-order differential equation
Greninja has been greatly buffed from ''Smash 4'' to ''Ultimate''. Its playstyle's traits have been further improved in the transition, while the general engine changes benefit said playstyle.
<math display="block">\left(x+\frac{\hbar}{m\omega}\frac{d}{dx}\right)\psi_0 = 0,</math>
whose solution is easily found to be the Gaussian<ref>The normalization constant is <math>C = \left(\frac{m\omega}{\pi \hbar}\right)^{\frac{1}{4}}</math>, and satisfies the normalization condition <math>\int_{-\infty}^{\infty}\psi_0(x)^{*}\psi_0(x)dx = 1</math>.</ref>
<math display="block">\psi_0(x)=Ce^{-\frac{m\omega x^2}{2\hbar}}.</math>
Conceptually, it is important that there is only one solution of this equation; if there were, say, two linearly independent ground states, we would get two independent chains of eigenvectors for the harmonic oscillator. Once the ground state is computed, one can show inductively that the excited states are Hermite polynomials times the Gaussian ground state, using the explicit form of the raising operator in the position representation. One can also prove that, as expected from the uniqueness of the ground state, the Hermite functions energy eigenstates <math>\psi_n</math> constructed by the ladder method form a ''complete'' orthonormal set of functions.<ref>See Theorem 11.4 in {{citation|first=Brian C.|last=Hall|title=Quantum Theory for Mathematicians|series=Graduate Texts in Mathematics|volume=267|isbn=978-1461471158 |publisher=Springer|year=2013}}</ref>


Most of the universal changes notably benefit Greninja. As with all other characters in the game, Greninja's already quick mobility is faster like most characters, which benefits its hit-and-run playstyle, allowing Greninja to close in the distance and escape to reset the neutral game much more easily. The ability to run cancel into any ground move allows Greninja to further exploit its amazing ground mobility, allowing for easier setups into its combo starters, such as up and down tilt and dash attack. Furthermore, the reduced landing lag on Greninja's aerial attacks gives it an easier time landing, while the universal 3-frame jumpsquat improves Greninja's ground-to-air potential. The implementation of [[spot dodge]] canceling improves its potential punish game, due to its wide variety of combo starters and fast frame data. Finally, the changes to air dodge mechanics slightly improve its previously below average edgeguarding game.
Explicitly connecting with the previous section, the ground state  |0⟩  in the position representation is determined by <math> a| 0\rangle =0</math>,
<math display="block">  \left\langle x \mid a \mid 0 \right\rangle = 0 \qquad
  \Rightarrow \left(x + \frac{\hbar}{m\omega}\frac{d}{dx}\right)\left\langle x\mid 0\right\rangle = 0 \qquad
  \Rightarrow          </math>
<math display="block"> \left\langle x\mid 0\right\rangle = \left(\frac{m\omega}{\pi\hbar}\right)^\frac{1}{4} \exp\left( -\frac{m\omega}{2\hbar}x^2 \right)
    = \psi_0  ~,</math>
hence
<math display="block"> \langle x \mid a^\dagger \mid 0 \rangle = \psi_1 (x) ~,</math>
so that <math>\psi_1(x,t)=\langle x \mid e^{-3i\omega t/2} a^\dagger \mid 0 \rangle </math>, and so on.


Aside from the universal changes, Greninja has also received notable direct buffs. The biggest ones were to its grab game: its standing grab is faster and its pummel, previously one of the worst in ''Smash 4'', deals less damage but is significantly faster, which allows Greninja to deal much more damage before throwing the opponent. Greninja's forward throw has higher knockback, allowing it to KO in an emergency, as with up throw. Its up and down throws also have better combo and juggling potential due to the universal changes to mobility - down throw notably now allows for potential KO confirms into forward and back aerial. Other buffs include [[Water Shuriken]] having more range, improving Greninja's camping ability. Greninja now has a new down tilt that has lower ending lag and sends at more favorable angles, and its dash attack sends at a higher angle, further improving Greninja's combo game. Greninja's KO power has also been buffed, with forward smash and forward aerial receiving higher knockback, up smash connecting better into its second hit, and down smash having faster startup. Lastly, [[Substitute]] now slows opponents down and offers Greninja intangibility during all of its attack variations, bringing it in line with other counterattacks.
===Natural length and energy scales===
The quantum harmonic oscillator possesses natural scales for length and energy, which can be used to simplify the problem. These can be found by [[nondimensionalization#Quantum harmonic oscillator|nondimensionalization]].


On the other hand, Greninja is not without its nerfs. Notably, the ability to tech footstools has made footstool combos harder to pull off, which hinders Greninja's combo ability (specifically from its down aerial); however, this nerf is alleviated by Greninja's buffed combo game, due to other universal changes that impact it more positively. Substitute's attack variants are all weaker while also being more laggy overall, which compensates for the attack's new intangibility. In exchange for its buffed mobility, Greninja is now lighter, which brings it slightly more in-line with other combo-centric and/or hit-and-run characters, while not compensating much for its vulnerability to combos.
The result is that, if  ''energy'' is measured in units of  {{math|''ħω''}} and ''distance'' in units of {{math|{{sqrt|''ħ''/(''mω'')}}}}, then the Hamiltonian simplifies to
<math display="block"> H = -\frac{1}{2} {d^2 \over dx^2} +\frac{1}{2}  x^2 ,</math>
while the energy eigenfunctions and eigenvalues simplify to Hermite functions and integers offset by a half,
<math display="block">\psi_n(x)= \left\langle x \mid n \right\rangle = {1 \over \sqrt{2^n n!}}~ \pi^{-1/4} \exp(-x^2 / 2)~ H_n(x),</math>
<math display="block">E_n = n + \tfrac{1}{2} ~,</math>
where {{math|''H''<sub>''n''</sub>(''x'')}} are the [[Hermite polynomials]].


As a result of receiving multiple buffs with relatively few nerfs, Greninja has improved significantly from ''Smash 4'', and has retained its status as a viable character in ''Ultimate'', with above average representation and some strong results in competitive play thanks to smashers such as {{Sm|iStudying}}, {{Sm|Jw}}, {{Sm|Lea}}, {{Sm|Somé}}, and {{Sm|Stroder}}. Because of this, Greninja is considered as a high or even top-tier character by many professional players.
To avoid confusion, these "natural units"  will mostly not be adopted in this article. However, they frequently come in handy when performing calculations, by bypassing clutter.


{{SSB4 to SSBU changelist|char=Greninja}}
For example, the [[fundamental solution]] ([[Propagator#Basic_examples:_propagator_of_free_particle_and_harmonic_oscillator|propagator]]) of {{math|''H'' − ''i∂<sub>t</sub>''}}, the time-dependent Schrödinger operator for this oscillator, simply boils down to the [[Mehler kernel]],<ref>[[Wolfgang Pauli|Pauli, W.]]  (2000), ''Wave Mechanics: Volume 5 of Pauli Lectures on Physics'' (Dover Books on Physics). {{ISBN|978-0486414621}} ; Section 44.</ref><ref>[[Edward Condon|Condon, E. U.]]  (1937). "Immersion of the Fourier transform in a continuous group of functional transformations", ''Proc. Natl. Acad. Sci. USA''  '''23''', 158–164. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1076889/pdf/pnas01779-0028.pdf online]</ref>
<math display="block">\langle x \mid \exp (-itH) \mid y \rangle \equiv K(x,y;t)= \frac{1}{\sqrt{2\pi i \sin t}} \exp \left(\frac{i}{2\sin t}\left ((x^2+y^2)\cos t - 2xy\right )\right )~,</math>
where {{math|1= ''K''(''x'',''y'';0) = ''δ''(''x'' − ''y'')}}. The most general solution for a given initial configuration {{math|''ψ''(''x'',0)}} then is simply
<math display="block">\psi(x,t)=\int dy~ K(x,y;t) \psi(y,0) \,.</math>
{{see also|Path integral formulation#Simple harmonic oscillator}}


==Update history==
===Coherent states===
Greninja has received a mix of minor buffs and nerfs via game updates. Several glitches have also been fixed over time.


'''{{GameIcon|ssbu}} {{SSBU|1.2.0}}'''
{{main|Coherent state}}
{{UpdateList (SSBU)/1.2.0|char=Greninja}}


'''{{GameIcon|ssbu}} {{SSBU|2.0.0}}'''
[[File:QHO-coherentstate3-animation-color.gif|thumb|Time evolution of the probability distribution (and phase, shown as color) of a coherent state with &#124;''α''&#124;=3.]]
{{UpdateList (SSBU)/2.0.0|char=Greninja}}


'''{{GameIcon|ssbu}} {{SSBU|3.0.0}}'''
The [[Coherent states#The wavefunction of a coherent state|coherent states]] (also known as Glauber states) of the harmonic oscillator are special nondispersive [[wave packet]]s, with minimum uncertainty {{math|1=''σ<sub>x</sub>'' ''σ<sub>p</sub>'' = {{frac|''ℏ''|2}}}}, whose [[observable]]s' [[Expectation value (quantum mechanics)|expectation values]] evolve like a classical system. They are eigenvectors of the annihilation operator, ''not'' the Hamiltonian, and form an [[Overcompleteness|overcomplete]] basis which consequentially lacks orthogonality.
{{UpdateList (SSBU)/3.0.0|char=Greninja}}


'''{{GameIcon|ssbu}} {{SSBU|3.1.0}}'''
The coherent states are indexed by {{math|''α'' ∈ '''C'''}} and expressed in the {{math|{{braket|ket|''n''}}}} basis as
{{UpdateList (SSBU)/3.1.0|char=Greninja}}


'''{{GameIcon|ssbu}} {{SSBU|4.0.0}}'''
<math display="block">|\alpha\rangle = \sum_{n=0}^\infty |n\rangle \langle n | \alpha \rangle = e^{-\frac{1}{2} |\alpha|^2} \sum_{n=0}^\infty\frac{\alpha^n}{\sqrt{n!}} |n\rangle = e^{-\frac{1}{2} |\alpha|^2} e^{\alpha a^\dagger} e^{-{\alpha^* a}} |0\rangle.</math>
{{UpdateList (SSBU)/4.0.0|char=Greninja}}


'''{{GameIcon|ssbu}} {{SSBU|7.0.0}}'''
Because <math>a \left| 0 \right\rangle = 0 </math> and via the Kermack-McCrae identity, the last form is equivalent to a [[Unitary operator|unitary]] [[displacement operator]] acting on the ground state: <math>|\alpha\rangle=e^{\alpha \hat a^\dagger - \alpha^*\hat a}|0\rangle  = D(\alpha)|0\rangle</math>. The [[position space]] wave functions are
{{UpdateList (SSBU)/7.0.0|char=Greninja}}


'''{{GameIcon|ssbu}} {{SSBU|8.0.0}}'''
<math display="block">\psi_\alpha(x')= \left(\frac{m\omega}{\pi\hbar}\right)^{\frac{1}{4}} e^{\frac{i}{\hbar} \langle\hat{p}\rangle_\alpha x' - \frac{m\omega}{2\hbar}(x' - \langle\hat{x}\rangle_\alpha)^2} .</math>
{{UpdateList (SSBU)/8.0.0|char=Greninja}}


==Moveset==
Since coherent states are not energy eigenstates, their time evolution is not a simple shift in wavefunction phase. The time-evolved states are, however, also coherent states but with phase-shifting parameter {{mvar|α}} instead: <math>\alpha(t) = \alpha(0) e^{-i\omega t}</math>.
* Greninja can [[Crawling|crawl]], [[wall cling]], and [[wall jump]].
''For a gallery of Greninja's hitboxes, see [[Greninja (SSBU)/Hitboxes|here]].''


{{MovesetTable
===Highly excited states===
|neutralname=&nbsp;
{{multiple image
|neutralcount=3
| width = 320
|neutralinf=y
| direction = vertical
|neutral1dmg=2%
| image1 = Excited_state_for_quantum_harmonic_oscillator.svg
|neutral2dmg=2%
| image2 = QHOn30pdf.svg
|neutral3dmg=3%
| footer = Wavefunction (top) and probability density (bottom) for the {{math|1=''n'' = 30}} excited state of the quantum harmonic oscillator. Vertical dashed lines indicate the classical turning points, while the dotted line represents the classical probability density.
|neutralinfdmg=0.5% (loop), 2% (last)
|neutraldesc=Two alternating palm thrusts followed by a double palm thrust that emits a small blast of water. If button mashed, it is instead followed by a series of knifehand strikes that emit blade-shaped water blasts that concludes with an outward knifehand strike that emits a wide blast of water. It can also be jab canceled, such as into forward tilt, down tilt and forward smash.
|ftiltname=&nbsp;
|ftiltdmg=7.3%
|ftiltdesc=A hook kick which stops half way. It can be angled and can [[lock]] opponents.
|utiltname=&nbsp;
|utiltdmg=4.5%
|utiltdesc=Swings its tongue upwards. A good aerial combo starter and juggling tool due to its low knockback and somewhat disjointed hitbox. It can combo into itself at low percents and is a reliable way to connect into up aerial.
|dtiltname=&nbsp;
|dtiltdmg=4%
|dtiltdesc=Does a downward hand sweep. It sends opponents at an upward angle, making it a versatile combo starter. Notably, it can confirm a KO into an up smash rather easily.
|dashname=&nbsp;
|dashdmg=8%
|dashdesc=Does a sweep kick. Is arguably one of the best dash attacks in the game, as it launches opponents at an excellent angle for combos, making it one of Greninja's best combo starters. Reliably combos into back aerial at virtually any percent, and can set up up aerial strings or drag-down combos with up aerial.
|fsmashname=&nbsp;
|fsmashdmg=14%
|fsmashdesc=An inward slash with a water kunai. Deals good knockback and has good range. However, it has notable ending lag.
|usmashname=&nbsp;
|usmashdmg=5% (hit 1), 14% (hit 2 clean center), 11% (hit 2 clean sides), 10% (hit 2 late)
|usmashdesc=Two reverse gripped inward slashes with water kunai, similar to {{SSBU|Sheik}}'s up smash. Greninja's strongest finisher, especially when hit clean. Can be combo'd into from a down-tilt at specific percentages for a KO.
|dsmashname=&nbsp;
|dsmashdmg=13% (kunai), 11% (arms)
|dsmashdesc=Hits both sides with water kunai. Due to it sending opponents at an [[semi-spike]] angle and coming out on frame 11, it is a quick and effective way to set up an edge-guard situation.
|nairname=&nbsp;
|nairdmg=11% (clean), 6% (late)
|nairdesc=Strikes a ninjutsu pose while emitting an exploding water bubble. Despite noticeable start-up lag for a neutral aerial(frame 12), it boasts great combo potential at low to mid percentages with its strong and weak hits and can KO confirm into up-smash at high percents with the weak hit. It can also KO at very high percents with its strong hit.
|fairname=&nbsp;
|fairdmg=14%
|fairdesc=Slashes with a water kunai. It has some start-up and suffers from high end lag, but it is a great tool in the neutral for spacing due to its disjointed hitbox and can be used for KOing. It is also safe on shield if spaced correctly.
|bairname=&nbsp;
|bairdmg= 3% (hit 1), 2.5% (hit 2), 6% (hit 3)
|bairdesc=Kicks backwards three times. It is Greninja's fastest aerial attack, although it is also one of the weakest aerials of its kind. However, this makes it a useful combo tool in return, as it can be followed up from a down throw, down tilt, as well as a dash attack. It can be a situational out-of-shield option if the opponent crosses-up on its shield.
|uairname=&nbsp;
|uairdmg=1.3% (hits 1-5), 3% (hit 6)
|uairdesc=Does a upward corkscrew kick, similar to both {{SSBU|Sheik}}'s and {{SSBU|Joker}}'s up aerials. One of Greninja's best combo and KO tools, as it can juggle and KO effectively due to its great jumping prowess. It also allows for drag-down combos because it's multi-hit properties, although this requires precise timing to land it at the right time, as its final launching hit comes out too fast to set up drag-down combos otherwise.
|dairname=&nbsp;
|dairdmg=8%
|dairdesc=A diving double foot stomp. It acts as a [[stall-then-fall]] and bounces off opponents. The clean hit [[meteor smash]]es opponents while the late hit sends the opponent upwards, allowing for some situational combos.
|grabname=&nbsp;
|grabdesc=Grabs with a whirlpool. While its standing grab is slow, it is among the longest-reaching grabs in the game.
|pummelname=&nbsp;
|pummeldmg=1%
|pummeldesc=Compresses target with water. Decent speed.
|fthrowname=&nbsp;
|fthrowdmg=3.5% (hit 1), 4.5% (throw)
|fthrowdesc=Shoves the opponent forward. Can KO at high percentages near the edge.
|bthrowname=&nbsp;
|bthrowdmg=9%
|bthrowdesc=Greninja leans forward and flings the opponent backwards. Like forward throw, its decent knockback gives it good edgeguarding potential at high percentages.
|uthrowname=&nbsp;
|uthrowdmg=5%
|uthrowdesc=Tosses the opponent upwards. One of Greninja's most useful throws, as it can combo into a up tilt or up aerial at low and medium percents and can even KO at later percents.
|dthrowname=&nbsp;
|dthrowdmg=5%
|dthrowdesc=Slams the opponent onto the ground. It can combo into a down tilt, forward tilt, and dash attack at low percentages. It can combo into back aerial at medium percents and later into forward aerial as well at higher percentages with good timing.
|floorfname=&nbsp;
|floorfdmg=8%
|floorfdesc=Sweep kicks around itself while getting up.
|floorbname=&nbsp;
|floorbdmg=8%
|floorbdesc=Sweep kicks around itself while getting up.
|floortname=&nbsp;
|floortdmg=8%
|floortdesc=Sweep kicks around itself while getting up.
|edgename=&nbsp;
|edgedmg=9%
|edgedesc=Performs a roundhouse kick while climbing up.
|nsname=Water Shuriken
|nsdmg=3%-10.8% (uncharged), 1.0% (fully charged looping hits), 9% (fully charged final hit)
|nsdesc=Uses Water Shuriken, which can be charged. Depending on how long the move is charged, the shuriken will be larger and do more damage, however the speed and distance will decrease as a result. At full charge, it hits multiple times and can kill with a Shadow Sneak follow-up at low and medium percents. It is also a decent KOing option at higher percents. A fully charged water shuriken that is reflected at a higher speed will have trouble landing the final hit on Greninja because of the looping hits not moving Greninja far enough for it.
|ssname=Shadow Sneak
|ssdmg=10% (normal), 12% (reverse)
|ssdesc=Disappears briefly, then preforms a forward kick or a drop kick (relative to the user's reappearance in relation to the enemy) to attack. The move activates when the special button is released. The way the shadow moves is relative to Greninja's position, and it can be moved further or closer to change how far Greninja teleports. While performing Shadow Sneak, Greninja cannot run, attack, grab, dodge or shield. However, it can walk slowly, jump and taunt. Has strong knockback and base knockback, which allows it to kill notably early when hitting the move offstage.
|usname=Hydro Pump
|usdmg=2% (per shot)
|usdesc=Uses Hydro Pump to propel itself in the inputted direction; it can be used twice. Each shot has a [[windbox]] effect that pushes opponents, making it a decent option for gimping predictable recoveries.
|dsname=Substitute
|dsdmg=14% (up or down), 11% (left or right)
|dsdesc=Does a pose, and if anyone hits it while posing, Greninja will temporarily disappear, get replaced by a wooden log or a Substitute doll, and then appear behind the opponent and strike them. It deviates noticeably from other counters, as the attack itself can be angled in an inputted direction and launching the opponent in that direction (with the down input meteor smashing opponents, which makes it a good punish against reckless edgeguarders).
|fsname=Secret Ninja Attack
|fsdmg=6% (the mat), 50% (Total in the attack after mat)
|fsdesc=Turns into Ash-Greninja and attacks the opponent with a mat. If an opponent is caught in the mat, Greninja will send them up into the air and strike the opponent repeatedly in midair with its kunai, before slamming them down with a final hit.
|game=SSBU
|dtauntname=
|dtauntdmg=0.5%
|dtauntdesc=While standing on one foot, Greninja holds out its hands, faces the screen, and summons small sprays of water. The sprays produce some knockback, though they're able to KO only at above 420%. A video showing the exact KO percentages at which each character can be KO'd can be found [https://www.youtube.com/watch?v=cH7IDQ_8vic here]. Unlike the rest of Greninja's taunts, this one cannot be cancelled (unless Shadow Sneak is being charged before using it).
}}
}}
===[[On-screen appearance]]===
When {{mvar|n}} is large, the eigenstates are localized into the classical allowed region, that is, the region in which a classical particle with energy {{math|''E''<sub>''n''</sub>}} can move. The eigenstates are peaked near the turning points: the points at the ends of the classically allowed region where the classical particle changes direction. This phenomenon can be verified through [[Hermite_polynomials#Asymptotic_expansion|asymptotics of the Hermite polynomials]],  and also through the [[WKB approximation]].
*Emerges from a [[Poké Ball]], then performs a ninjutsu hand sign that emits a small burst of water from its hands.
 
<gallery>
The frequency of oscillation at {{mvar|x}} is proportional to the momentum {{math|''p''(''x'')}} of a classical particle of energy {{math|''E''<sub>''n''</sub>}}  and position {{mvar|x}}.  Furthermore, the square of the amplitude (determining the probability density) is ''inversely'' proportional to  {{math|''p''(''x'')}},  reflecting the length of time the classical particle spends near {{mvar|x}}. The system behavior in a small neighborhood of the turning point does not have a simple classical explanation, but can be modeled using an [[Airy function]]. Using properties of the Airy function,  one may estimate the probability of finding the particle outside the classically allowed region,  to be approximately
GreninjaOnScreenAppearanceSSBU.gif|Greninja's on-screen appearance
<math display="block">\frac{2}{n^{1/3}3^{2/3}\Gamma^2(\tfrac{1}{3})}=\frac{1}{n^{1/3}\cdot  7.46408092658...}</math>
</gallery>
This is also given, asymptotically, by the integral
<math display="block">\frac{1}{2\pi}\int_{0}^{\infty}e^{(2n+1)\left (x-\tfrac{1}{2}\sinh(2x)  \right )}dx ~.</math>
 
===Phase space solutions===
In the [[phase space formulation]] of quantum mechanics, eigenstates of the quantum harmonic oscillator in [[quasiprobability distribution#Fock state|several different representations]] of the [[quasiprobability distribution]] can be written in closed form. The most widely used of these is for the [[Wigner quasiprobability distribution]].
 
The Wigner quasiprobability distribution for the energy eigenstate {{math|{{!}}''n''⟩}} is, in the natural units described above,{{citation needed|date=July 2020}}
<math display="block">F_n(x, p) = \frac{(-1)^n}{\pi \hbar} L_n\left(2(x^2 + p^2)\right) e^{-(x^2 + p^2)} \,,</math>
where ''L<sub>n</sub>'' are the [[Laguerre polynomials]]. This example illustrates how the Hermite and Laguerre polynomials are [[Hermite polynomials#Wigner distributions of Hermite functions|linked]] through the [[Wigner–Weyl transform|Wigner map]].
 
Meanwhile, the [[Husimi_Q_representation|Husimi Q function]] of the harmonic oscillator eigenstates have an even simpler form. If we work in the natural units described above, we have
<math display="block">Q_n(x,p)=\frac{(x^2+p^2)^n}{n!}\frac{e^{-(x^2+p^2)}}{\pi}</math>
This claim can be verified using the [[Segal–Bargmann_space#The Segal.E2.80.93Bargmann transform|Segal–Bargmann transform]]. Specifically, since the [[Segal–Bargmann space#The canonical commutation relations|raising operator in the Segal–Bargmann representation]] is simply multiplication by <math>z=x+ip</math> and the ground state is the constant function 1, the normalized harmonic oscillator states in this representation are simply <math>z^n/\sqrt{n!}</math> . At this point, we can appeal to the formula for the Husimi Q function in terms of the Segal–Bargmann transform.
 
==''N''-dimensional isotropic harmonic oscillator==
The one-dimensional harmonic oscillator is readily generalizable to {{math|''N''}} dimensions, where {{math|1=''N'' = 1, 2, 3, …}}. In one dimension, the position of the particle was specified by a single [[coordinate system|coordinate]], {{math|''x''}}. In {{math|''N''}} dimensions, this is replaced by {{math|''N''}} position coordinates, which we label {{math|''x''<sub>1</sub>, …, ''x''<sub>''N''</sub>}}. Corresponding to each position coordinate is a momentum; we label these {{math|''p''<sub>1</sub>, …, ''p''<sub>''N''</sub>}}. The [[canonical commutation relations]] between these operators are
<math display="block">\begin{align}
{[}x_i , p_j{]} &= i\hbar\delta_{i,j} \\
{[}x_i , x_j{]} &= 0                  \\
{[}p_i , p_j{]} &= 0
\end{align}</math>
 
The Hamiltonian for this system is
<math display="block"> H = \sum_{i=1}^N \left( {p_i^2 \over 2m} + {1\over 2} m \omega^2 x_i^2 \right).</math>
 
As the form of this Hamiltonian makes clear, the {{math|''N''}}-dimensional harmonic oscillator is exactly analogous to {{math|''N''}} independent one-dimensional harmonic oscillators with the same mass and spring constant. In this case, the quantities {{math|''x''<sub>1</sub>, ..., ''x''<sub>''N''</sub>}} would refer to the positions of each of the {{math|''N''}} particles. This is a convenient property of the {{math|''r''<sup>2</sup>}} potential, which allows the potential energy to be separated into terms depending on one coordinate each.
 
This observation makes the solution straightforward. For a particular set of quantum numbers <math>\{n\}\equiv
\{n_1, n_2, \dots, n_N\}</math> the energy eigenfunctions for the {{math|''N''}}-dimensional oscillator are expressed in terms of the 1-dimensional eigenfunctions as:
 
<math display="block">\langle \mathbf{x}|\psi_{\{n\}}\rangle = \prod_{i=1}^N\langle x_i\mid \psi_{n_i}\rangle</math>
 
In the ladder operator method, we define {{math|''N''}} sets of ladder operators,
 
<math display="block">\begin{align}
a_i &= \sqrt{m\omega \over 2\hbar} \left(x_i + {i \over m \omega} p_i \right), \\
a^{\dagger}_i &= \sqrt{m \omega \over 2\hbar} \left( x_i - {i \over m \omega} p_i \right).
\end{align}</math>
 
By an analogous procedure to the one-dimensional case, we can then show that each of the {{math|''a<sub>i</sub>''}} and {{math|''a''<sup>†</sup><sub>''i''</sub>}} operators lower and raise the energy by {{math|''ℏω''}} respectively. The Hamiltonian is
<math display="block">H = \hbar \omega \, \sum_{i=1}^N \left(a_i^\dagger \,a_i + \frac{1}{2}\right).</math>
This Hamiltonian is invariant under the dynamic symmetry group {{math|''U''(''N'')}} (the unitary group in {{math|''N''}} dimensions), defined by
<math display="block">
U\, a_i^\dagger \,U^\dagger = \sum_{j=1}^N  a_j^\dagger\,U_{ji}\quad\text{for all}\quad
U \in U(N),</math>
where <math>U_{ji}</math> is an element in the defining matrix representation of {{math|''U''(''N'')}}.
 
The energy levels of the system are
<math display="block"> E = \hbar \omega \left[(n_1 + \cdots + n_N) + {N\over 2}\right].</math>
<math display="block">n_i = 0, 1, 2, \dots \quad (\text{the energy level in dimension } i).</math>
 
As in the one-dimensional case, the energy is quantized. The ground state energy is {{math|''N''}} times the one-dimensional ground energy, as we would expect using the analogy to {{math|''N''}} independent one-dimensional oscillators. There is one further difference: in the one-dimensional case, each energy level corresponds to a unique quantum state. In {{math|''N''}}-dimensions, except for the ground state, the energy levels are ''degenerate'', meaning there are several states with the same energy.
 
The degeneracy can be calculated relatively easily.  As an example, consider the 3-dimensional case: Define {{math|1=''n'' = ''n''<sub>1</sub> + ''n''<sub>2</sub> + ''n''<sub>3</sub>}}. All states with the same {{math|''n''}} will have the same energy.  For a given {{math|''n''}}, we choose a particular {{math|''n''<sub>1</sub>}}. Then {{math|1=''n''<sub>2</sub> + ''n''<sub>3</sub> = ''n'' − ''n''<sub>1</sub>}}. There are {{math|''n'' − ''n''<sub>1</sub> + 1}} possible pairs {{math|{{mset|''n''<sub>2</sub>, ''n''<sub>3</sub>}}}}. {{math|''n''<sub>2</sub>}} can take on the values {{math|0}} to {{math|''n'' − ''n''<sub>1</sub>}}, and for each {{math|''n''<sub>2</sub>}} the value of {{math|''n''<sub>3</sub>}} is fixed. The degree of degeneracy therefore is:
<math display="block">g_n = \sum_{n_1=0}^n n - n_1 + 1 = \frac{(n+1)(n+2)}{2}</math>
Formula for general {{math|''N''}} and {{math|''n''}} [{{math|''g''<sub>''n''</sub>}} being the dimension of the symmetric irreducible {{math|''n''}}-th power representation of the unitary group {{math|''U''(''N'')}}]:
<math display="block">g_n = \binom{N+n-1}{n}</math>
The special case {{math|''N''}} = 3, given above, follows directly from this general equation.  This is however, only true for distinguishable particles, or one particle in {{math|''N''}} dimensions (as dimensions are distinguishable). For the case of {{math|''N''}} bosons in a one-dimension harmonic trap, the degeneracy scales as the number of ways to partition an integer {{math|''n''}} using integers less than or equal to {{math|''N''}}.
 
<math display="block">g_n = p(N_{-},n)</math>
 
This arises due to the constraint of putting {{math|''N''}} quanta into a state ket where <math display="inline">\sum_{k=0}^\infty k n_k = n  </math>   and <math display="inline"> \sum_{k=0}^\infty  n_k = N </math>, which are the same constraints as in integer partition.
 
===Example: 3D isotropic harmonic oscillator===
[[File:2D_Spherical_Harmonic_Orbitals.png|thumb|300px|right|Schrödinger 3D spherical harmonic orbital solutions in 2D density plots; the [[Mathematica]] source code that used for generating the plots is at the top]]
The Schrödinger equation for a particle in a spherically-symmetric three-dimensional harmonic oscillator can be solved explicitly by separation of variables; see [[Particle in a spherically symmetric potential#3D isotropic harmonic oscillator|this article]] for the present case. This procedure is analogous to the separation performed in the [[Hydrogen-like atom#Schrödinger equation in a spherically symmetric potential|hydrogen-like atom]] problem, but with a different [[Particle in a spherically symmetric potential|spherically symmetric potential]]
<math display="block">V(r) = {1\over 2} \mu \omega^2 r^2,</math>
where {{mvar|μ}} is the mass of the particle. Because {{mvar|m}} will be used below for the magnetic quantum number, mass is indicated by  {{mvar|μ}}, instead of {{mvar|m}}, as earlier in this article.


===[[Taunt]]s===
The solution reads<ref>[[Albert Messiah]], ''Quantum Mechanics'', 1967, North-Holland, Ch XII,  § 15, p 456.[https://archive.org/details/QuantumMechanicsVolumeI/page/n239 online]</ref>
*'''Up Taunt''': Stands upright, clasping its hands together before assuming a ninjutsu stance. The stance resembles one of its attack animations from the ''Pokémon'' series.
<math display="block">\psi_{klm}(r,\theta,\phi) = N_{kl} r^{l}e^{-\nu r^2}L_k^{\left(l+{1\over 2}\right)}(2\nu r^2) Y_{lm}(\theta,\phi)</math>
*'''Side Taunt''': Shakes head from side to side, causing its tongue to whip out in the same directions.  Particles of saliva fly off with each whip.
where
*'''Down Taunt''': Poses with arms out and palms upward, and summons small sprays of water from them, which deal a small amount of damage.
:<math>N_{kl}=\sqrt{\sqrt{\frac{2\nu^3}{\pi }}\frac{2^{k+2l+3}\;k!\;\nu^l}{(2k+2l+1)!!}}~~</math> is a normalization constant; <math>\nu \equiv {\mu \omega \over 2 \hbar}~</math>;
<gallery>
:<math>{L_k}^{(l+{1\over 2})}(2\nu r^2)</math>  
SSBUGreninjaTaunt1.gif|Greninja's up taunt.
are [[Laguerre polynomials#Generalized Laguerre polynomials|generalized Laguerre polynomials]]; The order {{mvar|k}}  of the polynomial is a non-negative integer;
SSBUGreninjaTaunt2.gif|Greninja's side taunt.
*<math>Y_{lm}(\theta,\phi)\,</math> is a [[spherical harmonics|spherical harmonic function]];
SSBUGreninjaTaunt3.gif|Greninja's down taunt.
*{{mvar|ħ}} is the reduced [[Planck constant]]: <math>\hbar\equiv\frac{h}{2\pi}~.</math>
</gallery>


===[[Idle Pose]]s===
The energy eigenvalue is
*Crosses arms over its body, then separates them with a flourish.
<math display="block">E=\hbar \omega \left(2k + l + \frac{3}{2}\right) .</math>
*Hunches over and assumes a ninjutsu stance.
The energy is usually described by the single [[quantum number]]
<gallery>
<math display="block">n\equiv 2k+l  \,.</math>
SSBUGreninjaIdle1.gif|Greninja's first idle pose
SSBUGreninjaIdle2.gif|Greninja's second idle pose
</gallery>


===[[Crowd cheer]]===
Because {{mvar|k}} is a non-negative integer, for every even {{mvar|n}} we have {{math|1=''ℓ'' = 0, 2, , ''n'' − 2, ''n''}} and for every odd {{mvar|n}}  we have {{math|1=''ℓ'' = 1, 3, …, ''n'' − 2, ''n''}} . The magnetic quantum number {{mvar|m}} is an integer satisfying {{math|−''ℓ'' ≤ ''m'' ≤ ''ℓ''}}, so for every {{mvar|n}} and ''ℓ'' there are 2''ℓ''&nbsp;+&nbsp;1 different [[quantum state]]s, labeled by {{mvar|m}} . Thus, the degeneracy at level {{mvar|n}} is
<div class="tabber">
<math display="block">\sum_{l=\ldots,n-2,n} (2l+1) = {(n+1)(n+2)\over 2} \,,</math>
<div class="tabbertab" title="English, Japanese/Chinese, Italian, Dutch, French">
where the sum starts from 0 or 1, according to whether {{mvar|n}} is even or odd.
{| class="wikitable" border="1" cellpadding="4" cellspacing="1"
This result is in accordance with the dimension formula above, and amounts to the dimensionality of a symmetric representation of {{math|SU(3)}},<ref>Fradkin, D. M. "Three-dimensional isotropic harmonic oscillator and SU3." ''American Journal of Physics'' '''33''' (3) (1965) 207–211.</ref> the relevant degeneracy group.
|-
!{{{name|}}}
!Cheer (English)
!Cheer (Japanese/Chinese)
!Cheer (Italian)
!Cheer (Dutch)
!Cheer (French)
|-
! scope="row"|Cheer
|[[File:Greninja Cheer English SSBU.ogg|center]]||[[File:Greninja Cheer Japanese SSBU.ogg|center]]||[[File:Greninja Cheer Italian SSBU.ogg|center]]||[[File:Greninja Cheer Dutch SSBU.ogg|center]]||{{NTSC}} [[File:Greninja Cheer French NTSC SSBU.ogg|center]] <br> {{PAL}} [[File:Greninja Cheer French PAL SSBU.ogg|center]]
|-
! scope="row"|Description
|Gre - ninja! || Ge - kkou -ga! || Gre - nin - ja! || Gre - ninja! || Am - phi - no - bi!
|}
</div>
<div class="tabbertab" title="German, Spanish, Russian, Korean">
{| class="wikitable" border="1" cellpadding="4" cellspacing="1"
|-
!{{{name|}}}
!Cheer (German)
!Cheer (Spanish)
!Cheer (Russian)
!Cheer (Korean)
|-
! scope="row"|Cheer
|[[File:Greninja Cheer German SSBU.ogg|center]]||{{NTSC}} [[File:Greninja Cheer Spanish NTSC SSBU.ogg|center]] <br> {{PAL}} [[File:Greninja Cheer Spanish PAL SSBU.ogg|center]]||[[File:Greninja Cheer Russian SSBU.ogg|center]]||[[File:Greninja Cheer Korean SSBU.ogg|center]]
|-
! scope="row"|Description
|Quaaaaa - jutsu! || Greninja! Greninja! Ya ya ya! || Gre - ninja! || Gae - gul - nin - ja!
|}
</div>
</div>


===[[Victory pose]]s===
==Applications==
*'''Left:''' Does a few hand seals with splashing water, and then a ninja pose. It resembles one of its attack animations in [[bulbapedia:Pokémon X and Y|''Pokémon X'' and ''Y'']].
===Harmonic oscillators lattice: phonons===
*'''Up:''' Performs Double Team to briefly create three afterimages of itself.
{{see also|Canonical quantization}}
*'''Right:''' Does a flip, lands in a spinning pose, and crosses its arms.
[[File:PokemonSeriesVictoryThemeUltimate.ogg|thumb|A small excerpt of the title theme of ''Pokémon Red, Blue, Yellow, and Green Versions'', a track which would go on to become the ''Pokémon'' main theme and the title theme for the entire series.]]
<gallery>
GreninjaVictoryPose1SSBU.gif
GreninjaVictoryPose2SSBU.gif
GreninjaVictoryPose3SSBU.gif
</gallery>


==In competitive play==
We can extend the notion of a harmonic oscillator to a one-dimensional lattice of many particles. Consider a one-dimensional quantum mechanical ''harmonic chain'' of ''N'' identical atoms. This is the simplest quantum mechanical model of a lattice, and we will see how [[phonon]]s arise from it. The formalism that we will develop for this model is readily generalizable to two and three dimensions.
In the early metagame, players quickly noticed that Greninja had been buffed from ''Smash 4'', with improved versatility and speed and, despite losing its [[footstool]] combos, gained a stronger combo game thanks to improved frame data on moves such as dash attack, up throw, down throw, and neutral air. Despite this, Greninja is not a very popular pick due to its high learning curve. Nevertheless, smashers such as {{Sm|Stroder}},  {{Sm|Venia}}, {{Sm|Jw}}, and {{Sm|Lea}} have proven that the character is a very viable pick, and Greninja has been solidified as a upper high-tier character.


===Most historically significant players===
As in the previous section, we denote the positions of the masses by  {{math|''x''<sub>1</sub>, ''x''<sub>2</sub>, …}}, as measured from their equilibrium positions (i.e.  {{math|1=''x<sub>i</sub>'' = 0}} if the particle {{mvar|i}} is at its equilibrium position). In two or more dimensions, the {{math|''x<sub>i</sub>''}} are vector quantities. The [[Hamiltonian (quantum mechanics)|Hamiltonian]] for this system is
<!--This character has a ten player limit for this section. Before adding and/or removing a player, read these guidelines: https://www.ssbwiki.com/SmashWiki:Notability#%22Most_historically_significant_players%22_guidelines -->


''Any number following the Smasher name indicates placement on the [[Fall 2019 PGRU]], which recognizes the official top 50 players in the world in [[Super Smash Bros. Ultimate]] from July 13th, 2019 to December 15th, 2019.''
<math display="block">\mathbf{H} = \sum_{i=1}^N {p_i^2 \over 2m} + {1\over 2} m \omega^2 \sum_{\{ij\} (nn)} (x_i - x_j)^2 \,,</math>
where {{mvar|m}} is the (assumed uniform) mass of each atom, and  {{math|''x<sub>i</sub>''}} and  {{math|''p<sub>i</sub>''}} are the position and [[momentum]] operators for the ''i'' th atom and the sum is made over the nearest neighbors (nn).  However, it is customary to rewrite the Hamiltonian in terms of the [[normal modes]] of the [[wavevector]] rather than in terms of the particle coordinates so that one can work in the more convenient [[Fourier space]].


''See also: [[:Category:Greninja professionals (SSBU)]]''
We introduce, then, a set of {{mvar|N}} "normal coordinates" {{math|''Q<sub>k</sub>''}}, defined as the [[discrete Fourier transform]]s of the {{mvar|x}}s, and {{mvar|N}} "conjugate momenta"  {{mvar|Π}} defined as the Fourier transforms of the {{mvar|p}}s,
<math display="block">Q_k = {1\over\sqrt{N}} \sum_{l} e^{ikal} x_l</math>
<math display="block">\Pi_{k} = {1\over\sqrt{N}} \sum_{l}  e^{-ikal} p_l \,.</math>


*{{Sm|Elexiao|France}} - One of the best Greninja players in Europe. Placed 1st at {{Trn|4 Seasons Tournament: Winter 2020}}, 2nd at {{Trn|SEL 4: Crêpes Strikes Back}}, 5th at {{Trn|VCA 2019}}, 7th at {{Trn|Valhalla III}}, and 9th at {{Trn|Ultimate Fighting Arena 2019}} with wins over players such as {{Sm|Oryon}}, {{Sm|Flow}}, and {{Sm|Tru4}}. Currently ranked 13th on the [[European Smash Rankings]].
The quantity {{math|''k<sub>n</sub>''}} will turn out to be the [[Wavenumber|wave number]] of the phonon, i.e. 2''π''  divided by the [[wavelength]]. It takes on quantized values, because the number of atoms is finite.
*{{Sm|iStudying|Netherlands}} - One of the best Greninja players in Europe. Placed 1st at both {{Trn|The Ultimate Performance 3}} and {{Trn|Heroes of Dutch Comic Con Winter Edition}}, 9th at both {{Trn|Ultimate Fighting Arena 2019}} and {{Trn|Temple: Hermès Edition}}, and 13th at {{Trn|Valhalla III}} with wins over players such as {{Sm|Stroder Ame}}, {{Sm|quiK}}, and {{Sm|Space}}. Currently ranked 15th on the [[European Smash Rankings]].
*{{Sm|Jw|Canada}} - The best Greninja player in Canada. Placed 9th at {{Trn|Pound 2019}}, 13th at {{Trn|Shine 2019}}, 17th at both {{Trn|Get On My Level 2019}} and {{Trn|The Big House 9}}, and 33rd at {{Trn|Frostbite 2020}} with wins over players such as {{Sm|MkLeo}}, {{Sm|Mr. E}}, and {{Sm|Wishes}}. Currently ranked 1st on the [[Smash Canada Rankings Ultimate]].
*{{Sm|Lea|Japan}} (#21) - The best Greninja player in the world. Placed  5th at both {{Trn|Umebura SP 3}} and {{Trn|Umebura SP 6}}, 7th at both {{Trn|2GG: Kongo Saga}} and  {{Trn|Kagaribi 4}}, and 9th at {{Trn|Frostbite 2019}} with wins over players such as {{Sm|KEN}}, {{Sm|Raito}}, and {{Sm|Dabuz}}.
*{{Sm|Oisiitofu|Japan}} -  Placed 9th at both {{Trn|Sumabato SP 2}} and {{Trn|Maesuma TOP 1}}, 13th at {{Trn|Sumabato SP 12}}, and 17th at both {{Trn|KVOxTSB 2019}} and {{Trn|Sumabato SP 7}} with wins over players such as {{Sm|Zackray}}, {{Sm|Atelier}}, and {{Sm|Nishiya}}. Currently ranked 86th on the [[Japan Player Rankings]].
*{{Sm|Regerets|Philippines}} - The best Greninja player in the Philippines. Placed 3rd at {{Trn|Gamebookr's Mid-Year Smash Tournament}} and 7th at both {{Trn|Uprising 2019}} and {{Trn|REV Major 2019}} with wins over players such as {{Sm|Aluf}}, {{Sm|JJROCKETS}}, and {{Sm|PSI Force}}. Currently ranked 1st on the [[Filipino Power Rankings]].
*{{Sm|Somé|Japan}} - Placed 1st at {{Trn|TSC 11}}, 3rd at {{Trn|TSC 12}}, 7th at {{Trn|Sumabato SP 4}}, 9th at {{Trn|Umebura SP 6}}, and 13th at {{Trn|Umebura SP 4}} with wins over players such as {{Sm|Jagaimo}}, {{Sm|Etsuji}}, and {{Sm|HIKARU}}. Currently ranked 21st on the [[Japan Player Rankings]].
*{{Sm|Stroder|USA}} - One of the best Greninja players in the world. Placed 1st at {{Trn|Ascension VIII}}, 5th at {{Trn|Glitch 8 - Missingno}}, 9th at {{Trn|Mainstage}}, 13th at {{Trn|Shine 2019}}, and 25th at {{Trn|EVO 2019}} with wins over players such as {{Sm|Tweek}}, {{Sm|Maister}}, and {{Sm|ESAM}}. Formerly ranked 29th on the [[Spring 2019 PGRU]].
*{{Sm|Tarik|Germany}} - One of the best Greninja players in Europe. Placed 1st at {{Trn|Calyptus Cup X: Powwer Up}}, 2nd at {{Trn|Smashwick 4}}, 7th at {{Trn|Syndicate 2019}}, 9th at {{Trn|Ultimate Fighting Arena 2019}}, and 25th at {{Trn|Glitch 8 - Missingno}} with wins over players such as {{Sm|ESAM}}, {{Sm|MVD}}, and {{Sm|Chag}}. Ranked 14th on the [[European Smash Rankings]].
*{{Sm|Venia|USA}} -  One of the best Greninja players in the United States but is currently banned from several tournaments. Placed 3rd at both {{Trn|Player's Ball Ultimate}} and {{Trn|Return to Yoshi's Island}}, 25th at {{Trn|Let's Make Big Moves}}, and 33rd at both {{Trn|The Big House 9}} and {{Trn|GENESIS 7}} with wins over {{Sm|Tweek}}, {{Sm|Dabuz}}, and {{Sm|Mr. E}}. Currently ranked 2nd on the [[New York City Power Rankings#Super Smash Bros. Ultimate rankings|New York City Ultimate Power Rankings]].


=={{SSBU|Classic Mode}}: Your Turn, Greninja!==
This preserves the desired commutation relations in either real space or wave vector space
[[File:SSBU Congratulations Greninja.png|thumb|Greninja's congratulations screen.]]
<math display="block"> \begin{align}  
Greninja fights against characters that represent different types from the ''Pokémon'' games: for example, Charizard and Bowser represent the Fire type, while Mewtwo, Ness and Lucas represent the Psychic type.
\left[x_l , p_m \right]&=i\hbar\delta_{l,m} \\
\left[ Q_k , \Pi_{k'} \right] &={1\over N} \sum_{l,m} e^{ikal} e^{-ik'am}  [x_l , p_m ] \\
&= {i \hbar\over N} \sum_{m} e^{iam(k-k')} = i\hbar\delta_{k,k'} \\
\left[ Q_k , Q_{k'} \right] &= \left[ \Pi_k , \Pi_{k'} \right] = 0 ~.
\end{align}</math>


{|class="wikitable" style="text-align:center"
From the general result
!Round!!Opponent!!Stage!!Music!!Notes
<math display="block"> \begin{align}
|-
\sum_{l}x_l x_{l+m}&={1\over N}\sum_{kk'}Q_k Q_{k'}\sum_{l} e^{ial\left(k+k'\right)}e^{iamk'}= \sum_{k}Q_k Q_{-k}e^{iamk} \\
|1||{{CharHead|Charizard|SSBU|hsize=20px}} and {{CharHead|Bowser|SSBU|hsize=20px}}||[[Pokémon Stadium]]||''{{SSBUMusicLink|Pokémon|Battle! (Elite Four) / Battle! (Solgaleo/Lunala)}}''||Represents Fire-type. Charizard's {{SSBU|Pokémon Trainer}} is absent.
\sum_{l}{p_l}^2 &= \sum_{k}\Pi_k \Pi_{-k}   ~,
|-
\end{align}</math>
|2||{{CharHead|Pikachu|SSBU|hsize=20px}}, {{CharHead|Pichu|SSBU|hsize=20px}}, and {{CharHead|Zero Suit Samus|SSBU|hsize=20px}}||[[Pokémon Stadium 2]]||''{{SSBUMusicLink|Pokémon|Battle! (Steven)}}''||Represents Electric-type.
it is easy to show, through elementary trigonometry, that the potential energy term is
|-
<math display="block"> {1\over 2} m \omega^2 \sum_{j} (x_j - x_{j+1})^2= {1\over 2} m \omega^2\sum_{k}Q_k Q_{-k}(2-e^{ika}-e^{-ika})= {1\over 2} m \sum_{k}{\omega_k}^2Q_k Q_{-k} ~ ,</math>
|3||{{CharHead|Lucario|SSBU|hsize=20px}}, {{CharHead|Ryu|SSBU|hsize=20px}}, and {{CharHead|Ken|SSBU|hsize=20px}}||Pokémon Stadium||''{{SSBUMusicLink|Pokémon|Battle! (Reshiram / Zekrom)}}''||Represents Fighting-type.
where
|-
<math display="block">\omega_k = \sqrt{2 \omega^2 (1 - \cos(ka))} ~.</math>
|4||{{CharHead|Ivysaur|SSBU|hsize=20px}}||Pokémon Stadium||''{{SSBUMusicLink|Pokémon|Battle! (Gladion)}}''||Represents Grass-type. Ivysaur's Pokémon Trainer is absent.
|-
|5||{{CharHead|Mewtwo|SSBU|hsize=20px}}, {{CharHead|Ness|SSBU|hsize=20px}}, and {{CharHead|Lucas|SSBU|hsize=20px}}||Pokémon Stadium 2||''{{SSBUMusicLink|Pokémon|Battle! (Dialga/Palkia) / Spear Pillar}}''||Represents Psychic-type.
|-
|6||{{CharHead|Squirtle|SSBU|hsize=20px}} and {{Head|Greninja|g=SSBU|s=20px|cl=Black}} Greninja||[[Kalos Pokémon League]]||''{{SSBUMusicLink|Pokémon|Battle! (Champion) - Pokémon X / Pokémon Y}}''||Represents Water-type. Squirtle's Pokémon Trainer is absent.  The CPU will be the {{Head|Greninja|g=SSBU|s=20px}} default Greninja if the player chooses the black costume.
|-
|colspan="5"|[[Bonus Stage]]
|-
|Final||{{SSBU|Master Hand}}||{{SSBU|Final Destination}}||''{{SSBUMusicLink|Super Smash Bros.|Master Hand}}'' <small>(Less than 7.0 intensity)</small><br>''{{SSBUMusicLink|Super Smash Bros.|Master Hand / Crazy Hand}}'' <small>(Intensity 7.0 or higher)</small>||On intensity 7.0 and higher, {{SSBU|Crazy Hand}} fights alongside Master Hand.
|}


Note: All rounds except the sixth round take place on Pokémon Stadium and Pokémon Stadium 2. If applicable, each stage will also shift to their appropriately-typed form at the earliest possible opportunity. (The stages remain in their default form in rounds 3 and 5, as none of the stages have Psychic or Fighting-themed forms.)
The Hamiltonian may be written in wave vector space as
<math display="block">\mathbf{H} = {1\over {2m}}\sum_k \left(
{ \Pi_k\Pi_{-k} } + m^2 \omega_k^2 Q_k Q_{-k}
\right) ~.</math>


[[Credits]] roll after completing Classic Mode. Completing it as Greninja has ''{{SSBUMusicLink|Pokémon|Battle! (Trainer Battle) - Pokémon X / Pokémon Y}}'' accompany the credits.
Note that the couplings between the position variables have been transformed away; if the {{mvar|Q}}s and {{mvar| Π}}s were [[Hermitian operator|hermitian]] (which they are not), the transformed Hamiltonian would describe {{mvar|N}} ''uncoupled'' harmonic oscillators.
{{clr}}


==Role in [[World of Light]]==
The form of the quantization depends on the choice of boundary conditions; for simplicity, we impose ''periodic'' boundary conditions, defining the {{math|(''N'' + 1)}}-th atom as equivalent to the first atom. Physically, this corresponds to joining the chain at its ends. The resulting quantization is
[[File:WoL-50Greninja.jpg|thumb|Finding Greninja in World of Light|left]]
Greninja was among the fighters that were summoned to fight the army of [[Master Hand]]s.


During the opening cutscene, Greninja was present on the cliffside when [[Galeem]] unleashed his beams of light. Greninja leaped into the air to avoid one of the beams, which hit {{SSBU|Lucario}} instead. Greninja was hit shortly after and vaporized, getting imprisoned by Galeem afterward along with the other fighters, sans {{SSBU|Kirby}}. A puppet fighter cloned from Greninja is later seen alongside ones cloned from {{SSBU|Fox}}, {{SSBU|Samus}}, {{SSBU|Link}} and other fighters.
<math display="block">k=k_n = {2n\pi \over Na}
\quad \hbox{for}\ n = 0, \pm1, \pm2, \ldots , \pm {N \over 2}. </math>


Greninja was one of the many fighters that fell under [[Dharkon]]'s control upon Galeem's first defeat, and it can be found in the [[Mysterious Dimension]] at [[The Dark Realm]]. It can be seen impeding the path, making it an obligatory unlock.
The upper bound to {{mvar|n}} comes from the minimum wavelength, which is twice the lattice spacing {{mvar|a}}, as discussed above.


Greninja is later seen among several other fighters, making their last stand against Galeem and Dharkon. It also shows up in the bad ending where Galeem emerges victorious against Dharkon, witnessing Galeem engulf the world in light.
The harmonic oscillator eigenvalues or energy levels for the mode {{math|''ω<sub>k</sub>''}} are
{{clrl}}
<math display="block">E_n = \left({1\over2}+n\right)\hbar\omega_k  \quad\hbox{for}\quad n=0,1,2,3,\ldots</math>


===Fighter Battle===
If we ignore the [[zero-point energy]] then the levels are evenly spaced at
{|class="wikitable" style="width:100%;"
<math display="block">\hbar\omega,\, 2\hbar\omega,\, 3\hbar\omega,\, \ldots  </math>
|-
!style="width:5%;"|No.
!style="width:5%;"|Image
!Name
!Type
!Power
!Stage
!Music
|-
|50
|[[File:Greninja SSBU.png|center|64x64px]]
|Greninja
|{{SpiritType|Shield}} <center>{{color|#18aef5|Shield}}</center>
|10,600
|[[Kalos Pokémon League]] ([[Ω form]])
|''{{SSBUMusicLink|Pokémon|Battle! (Trainer Battle) - Pokémon X / Pokémon Y}}''
|}
{{clear}}


==[[Spirit]]==
So an '''exact''' amount of [[energy]] {{math|''ħω''}}, must be supplied to the harmonic oscillator lattice to push it to the next energy level. In analogy to the [[photon]] case when the [[electromagnetic field]] is quantised, the quantum of vibrational energy is called a [[phonon]].
Greninja's fighter spirit can be obtained by completing {{SSBU|Classic Mode}}. It is also available periodically for purchase in the shop for 300 Gold, but only after Greninja has been unlocked. Unlocking Greninja in World of Light allows the player to preview the spirit below in the Spirit List under the name "???". As a fighter spirit, it cannot be used in Spirit Battles and is purely aesthetic. Its fighter spirit has an alternate version that replaces it with its artwork in ''Ultimate''.


<center>
All quantum systems show wave-like and particle-like properties. The particle-like properties of the phonon are best understood using the methods of [[second quantization]] and operator techniques described elsewhere.<ref name="Mahan">{{cite book| last=Mahan |first=GD |title=Many particle physics|publisher= Springer|location=New York | isbn=978-0306463389 |year=1981}}</ref>
<gallery>
SSBU spirit Greninja.png|418. '''''Greninja'''''
</gallery>
</center>


==In Spirit battles==
In the continuum limit, ''a''→0, ''N''→∞, while ''Na'' is held fixed. The canonical coordinates ''Q<sub>k</sub>'' devolve to the decoupled momentum modes of a scalar field, <math>\phi_k</math>, whilst the location index {{mvar|i}} (''not the displacement dynamical variable'') becomes the ''parameter {{mvar|x}} argument of the scalar field, <math>\phi (x,t)</math>.
===As the main opponent===
{|class="wikitable sortable" style="width:100%;"
! colspan=4|Spirit
! colspan=7|Battle parameters
! colspan=1|Inspiration
|-
! style="width:5%;"|No.
! style="width:5%;"|Image
! Name
! Series
! Enemy Fighter(s)
! style="width:5%;"|Type
! style="width:5%;"|Power
! Stage
! Rules
! Conditions
! Music
! Character
|-
|154
|{{SpiritTableName|Winky|size=64}}
|''Donkey Kong'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Green}}
|{{SpiritType|Attack}}
|1,700
|[[Mushroom Kingdom U]]
|N/A
|•The enemy deals damage when falling<br>•The enemy has increased jump power
|{{SSBUMusicLink|Donkey Kong|Jungle Level (Brawl)}}
|
|-
|199
|{{SpiritTableName|Zora|size=64}}
|''The Legend of Zelda'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Violet}}
|{{SpiritType|Shield}}
|1,800
|[[Great Bay]]
|N/A
|•The enemy's neutral special has increased power
|{{SSBUMusicLink|The Legend of Zelda|Ocarina of Time Medley}}
|
|-
|385
|{{SpiritTableName|Slippy Toad|link=y|size=64}}
|''Star Fox'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Green}}<br>•{{SSBU|Fox}} {{Head|Fox|g=SSBU|s=20px|cl=Black}}
|{{SpiritType|Shield}}
|9,600
|[[Frigate Orpheon]] (hazards off)
|N/A
|•Defeat the main fighter to win<br>•Timed battle (1:30)<br>•The enemy tends to avoid conflict
|{{SSBUMusicLink|Star Fox|Corneria - Star Fox}}
|
|-
|482
|{{SpiritTableName|Raikou, Entei, & Suicune|customname=[[Raikou]], [[Entei]], & [[Suicune]]|size=64}}
|''Pokémon'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Violet}}<br>•{{SSBU|Incineroar}} {{Head|Incineroar|g=SSBU|s=20px|cl=White}}<br>•{{SSBU|Pikachu}} {{Head|Pikachu|g=SSBU|s=20px|cl=Libre}}
|{{SpiritType|Shield}}
|9,900
|[[Suzaku Castle]]
|•Hazard: Lava Floor
|•The floor is lava
|{{SSBUMusicLink|Pokémon|Pokémon Red / Pokémon Blue Medley}}
|Suicune
|-
|516
|{{SpiritTableName|Darkrai|link=y|size=64}}
|''Pokémon'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Black}}
|{{SpiritType|Shield}}
|9,900
|[[Luigi's Mansion]] ([[Ω form]])
|•Item: [[Black Hole]]<br>•Hazard: Slumber Floor
|•The floor is sleep-inducing<br>•Only certain Pokémon will emerge from Poké Balls (Darkrai)
|{{SSBUMusicLink|Pokémon|Battle! (Team Galactic)}}
|
|-
|770
|{{SpiritTableName|Metal Gear RAY|size=64}}
|''Metal Gear Solid'' Series
|•Metal {{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Grey}} (140 HP)
|{{SpiritType|Grab}}
|4,200
|[[Shadow Moses Island]]
|•Item: Exploding Types
|•[[Stamina battle]]<br>•Explosion attacks aren't as effective against the enemy<br>•The enemy is metal
|{{SSBUMusicLink|Metal Gear|Yell "Dead Cell"}}
|
|-
|893
|{{SpiritTableName|Shadow Man|size=64}}
|''Mega Man'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Purple}}×3 (60 HP)
|{{SpiritType|Shield}}
|3,500
|[[Norfair]] ([[Battlefield form]])
|N/A
|•The enemy's neutral special has increased power<br>•[[Stamina battle]]<br>•The enemy favors neutral specials
|{{SSBUMusicLink|Mega Man|Shadow Man Stage}}
|
|-
|1,014
|{{SpiritTableName|Luka|size=64}}
|''Bayonetta'' Series
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Black}}
|{{SpiritType|Shield}}
|3,800
|[[New Donk City Hall]]
|•Temporary Invincibility
|•The enemy becomes temporarily invincible when badly damaged
|{{SSBUMusicLink|Bayonetta|Riders Of The Light}}
|
|-
|1,048
|{{SpiritTableName|Octoling Octopus|size=64}}
|''Splatoon'' Series
|•{{SSBU|Greninja}} Team {{Head|Greninja|g=SSBU|s=20px|cl=Pink}}×4
|{{SpiritType|Shield}}
|3,900
|[[Moray Towers]]
|N/A
|•Timed battle (2:00)
|{{SSBUMusicLink|Splatoon|Octoweaponry}}
|
|-
|1,143
|{{SpiritTableName|Frog & Snake|customname=[[Sablé Prince|Frog & Snake]]|size=64}}
|''Kaeru no Tame ni Kane wa Naru''
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Green}}<br>•{{SSBU|King K. Rool}} {{Head|King K. Rool|g=SSBU|s=20px|cl=Blue}}
|{{SpiritType|Shield}}
|3,600
|[[Dream Land GB]] (Castle Lololo interior)
|•Assist Trophy Enemies ([[Sablé Prince]])
|•Hostile assist trophies will appear
|{{SSBUMusicLink|Kirby|Kirby Retro Medley}} (Castle Lololo)
|Frog
|-
|rowspan="2"|1,291
|{{SpiritTableName|Ninjara|link=y|size=64|dlcalt=y}}
|rowspan="2"|''ARMS''
|•{{SSBU|Greninja}} {{Head|Greninja|g=SSBU|s=20px|cl=Green}}
|rowspan="2"|{{SpiritType|Grab}}
|rowspan="2"|3,600
|rowspan="2"|[[Suzaku Castle]]
|rowspan="2"|•Item: [[Boomerang]]
|rowspan="2"|•The enemy has increased move speed
|rowspan="2"|{{SSBUMusicLink|ARMS|Ninja College}}
|rowspan="2"|
|-
|style="background-color:#EEE;"|•{{SSBU|Mii Brawler}} {{Head|Mii Brawler|g=SSBU|s=20px}} (Moveset [[Flashing Mach Punch|2]][[Suplex|3]][[Soaring Axe Kick|1]][[Counter Throw|3]], Ninjara Wig, Ninjara Outfit)<ref group="SB" name="DLC"/>
|}


<references group="SB">
===Molecular vibrations===
<ref name="DLC">This alternative occurs when the corresponding DLC has been purchased and downloaded.</ref>
{{main|Molecular vibration}}
</references>
* The vibrations of a [[diatomic molecule]] are an example of a two-body version of the quantum harmonic oscillator. In this case, the angular frequency is given by <math display="block">\omega = \sqrt{\frac{k}{\mu}} </math> where <math>\mu = \frac{m_1 m_2}{m_1 + m_2}</math> is the [[reduced mass]] and <math>m_1</math> and <math>m_2</math> are the masses of the two atoms.<ref>{{Cite web | title=Quantum Harmonic Oscillator | website=Hyperphysics | access-date=24 September 2009 | url=http://hyperphysics.phy-astr.gsu.edu/hbase/quantum/hosc.html}}</ref>
* The [[Hooke's atom]] is a simple model of the [[helium]] atom using the quantum harmonic oscillator.
* Modelling phonons, as discussed above.
* A charge <math>q</math> with mass <math>m</math> in a uniform magnetic field <math>\mathbf{B}</math> is an example of a one-dimensional quantum harmonic oscillator: [[Landau quantization]].


==[[Alternate costume (SSBU)#Greninja|Alternate costumes]]==
==See also==
{|style="margin:1em auto 1em auto;text-align:center"
{{Div col}}
|-
*[[Quantum pendulum]]
|colspan=8|[[File:Greninja Palette (SSBU).png|link=Alternate costume (SSBU)#Greninja|1000px]]
*[[Quantum machine]]
|-
*[[Gas in a harmonic trap]]
|{{Head|Greninja|g=SSBU|s=50px}}
*[[Creation and annihilation operators]]
|{{Head|Greninja|g=SSBU|s=50px|cl=Red}}
*[[Coherent state]]
|{{Head|Greninja|g=SSBU|s=50px|cl=Pink}}
*[[Morse potential]]
|{{Head|Greninja|g=SSBU|s=50px|cl=Black}}
*[[Bertrand's theorem]]
|{{Head|Greninja|g=SSBU|s=50px|cl=Violet}}
*[[Mehler kernel]]
|{{Head|Greninja|g=SSBU|s=50px|cl=Green}}
*[[Molecular vibration#Quantum mechanics|Molecular vibration]]
|{{Head|Greninja|g=SSBU|s=50px|cl=Grey}}
{{Div col end}}
|{{Head|Greninja|g=SSBU|s=50px|cl=Purple}}
|}


==Gallery==
==References==
<gallery>
{{Reflist}}
Pokémon Smash Bros.png|Artwork of all playable Pokémon characters and Poké Ball Pokémon, as posted by the official Pokémon Twitter account.
SSBU Greninja Number.png|Greninja's fighter card.
Greninja unlock notice SSBU.jpg|Greninja's unlock notice.
SSBUWebsiteGreninja1.jpg|Greninja coming to a halt on [[Kalos Pokémon League]].
SSBUWebsiteGreninja2.jpg|Charging [[Water Shuriken]] next to {{SSBU|Ryu}} on [[Suzaku Castle]].
SSBUWebsiteGreninja3.jpg|Jumping on {{SSBU|Battlefield}}.
SSBUWebsiteGreninja4.jpg|Performing its neutral aerial with [[Leviathan]] on [[Midgar]].
SSBUWebsiteGreninja5.jpg|With its [[Substitute|Substitute Doll]] on [[Wuhu Island]] after [[tripping]].
SSBUWebsiteGreninja6.jpg|Performing [[Shadow Sneak]] on [[Luigi's Mansion]].
SSBUWebsiteLucario3.jpg|Struck by {{SSBU|Lucario}} on [[Pokémon Stadium 2]].
</gallery>


===Fighter Showcase Video===
==External links==
{{#widget:YouTube|id=rMCn8NuATaE}}
*[http://hyperphysics.phy-astr.gsu.edu/hbase/quantum/hosc.html Quantum Harmonic Oscillator]
*[http://behindtheguesses.blogspot.com/2009/03/quantum-harmonic-oscillator-ladder.html Rationale for choosing the ladder operators]
*[http://www.brummerblogs.com/curvature/3d-harmonic-oscillator-eigenfunctions/  Live 3D intensity plots of quantum harmonic oscillator]
*[http://ltl.tkk.fi/~ethuneb/courses/monqo.pdf Driven and damped quantum harmonic oscillator (lecture notes of course "quantum optics in electric circuits")]


==Trivia==
{{Use dmy dates|date=August 2019}}
*In the ''Pokémon'' series, Ash-Greninja is only obtainable as a male. The fact that Greninja transforms into Ash-Greninja for its [[Final Smash]], [[Secret Ninja Attack]], implies that Greninja is a male in ''Ultimate''.
*Greninja's new character portrait resembles its [[air dodge]] animation.
**It also resembles {{SSB4|Fox}}'s character portrait from ''Super Smash Bros. 4'' but with the arm and leg positions mirrored.
*Greninja's fighter number, 50, is the same as the number of its [[mariowiki:Costume Mario|costume]] in ''Super Mario Maker''. It shares this distinction with {{SSBU|Inkling}}.
*Greninja, {{SSBU|Ivysaur}}, {{SSBU|Olimar}}, {{SSBU|Little Mac}}, {{SSBU|Ryu}} and {{SSBU|Ken}} are the only characters to never appear as minions in any Spirit battles.
*Alongside {{SSBU|Luigi}}, Greninja is one of two characters in ''Ultimate'' with a taunt that cannot be cancelled, due to the fact that their non-cancelable taunts have hitboxes.
**Strangely, this does not apply for {{SSBU|Snake}} and {{SSBU|Kazuya}}'s taunts that have damaging hitboxes
**Greninja and Luigi are also the only two characters whose Classic Mode titles feature their names.
*Greninja can also be unlocked immediately after clearing Classic Mode as Sheik, referencing their ninja-like traits and movements.
*Greninja appears slightly tilted in its [[damage meter]] compared to its character artwork. This distinction is shared with fellow ''Pokémon'' series character {{SSBU|Incineroar}}.
**Coincidentally, both are final evolutions of starter Pokémon and both have Dark as their secondary type.
**Both are also found and unlocked in the Dark Realm in World of Light.
*Incineroar and {{SSBU|Jigglypuff}} are the only Pokémon that are not encountered in Greninja's Classic Mode route.
*Oddly, Greninja does not vanish when performing a directional [[air dodge]] despite the sound effects playing. It shares this oddity with {{SSBU|Rosalina & Luma}} and {{SSBU|Palutena}}.
*In ''Ultimate'', Greninja has a weight of 88, which almost matches its weight in ''Pokémon'' (in pounds), being 88.2 lbs.


{{SSBUCharacters}}
{{DEFAULTSORT:Quantum Harmonic Oscillator}}
{{Pokémon universe}}
[[Category:Quantum models]]
[[Category:Greninja (SSBU)| ]]
[[Category:Quantum mechanics]]
[[Category:Pokémon (SSBU)]]
[[Category:Oscillators]]
[[Category:Spirits]]
[[es:Greninja (SSBU)]]

Revision as of 10:41, February 9, 2022

Template:Use American English Template:Short description Template:Quantum mechanics

"QHO" redirects here. For {{{2}}}, see [[{{{3}}}|{{{3}}}]].
File:QuantumHarmonicOscillatorAnimation.gif
Some trajectories of a harmonic oscillator according to Newton's laws of classical mechanics (A–B), and according to the Schrödinger equation of quantum mechanics (C–H). In A–B, the particle (represented as a ball attached to a spring) oscillates back and forth. In C–H, some solutions to the Schrödinger Equation are shown, where the horizontal axis is position, and the vertical axis is the real part (blue) or imaginary part (red) of the wavefunction. C, D, E, F, but not G, H, are energy eigenstates. H is a coherent state—a quantum state that approximates the classical trajectory.

The quantum harmonic oscillator is the quantum-mechanical analog of the classical harmonic oscillator. Because an arbitrary smooth potential can usually be approximated as a harmonic potential at the vicinity of a stable equilibrium point, it is one of the most important model systems in quantum mechanics. Furthermore, it is one of the few quantum-mechanical systems for which an exact, analytical solution is known.[1][2][3]

One-dimensional harmonic oscillator

Hamiltonian and energy eigenstates

File:HarmOsziFunktionen.png
Wavefunction representations for the first eight bound eigenstates, n = 0 to 7. The horizontal axis shows the position x.
File:Aufenthaltswahrscheinlichkeit harmonischer Oszillator.png
Corresponding probability densities.

The Hamiltonian of the particle is:

where Template:Mvar is the particle's mass, Template:Mvar is the force constant, is the angular frequency of the oscillator, is the position operator (given by Template:Mvar in the coordinate basis), and is the momentum operator (given by in the coordinate basis). The first term in the Hamiltonian represents the kinetic energy of the particle, and the second term represents its potential energy, as in Hooke's law.

One may write the time-independent Schrödinger equation,

where Template:Mvar denotes a to-be-determined real number that will specify a time-independent energy level, or eigenvalue, and the solution Template:Math denotes that level's energy eigenstate.

One may solve the differential equation representing this eigenvalue problem in the coordinate basis, for the wave function Template:Math, using a spectral method. It turns out that there is a family of solutions. In this basis, they amount to Hermite functions,

The functions Hn are the physicists' Hermite polynomials,

The corresponding energy levels are

This energy spectrum is noteworthy for three reasons. First, the energies are quantized, meaning that only discrete energy values (integer-plus-half multiples of Template:Math) are possible; this is a general feature of quantum-mechanical systems when a particle is confined. Second, these discrete energy levels are equally spaced, unlike in the Bohr model of the atom, or the particle in a box. Third, the lowest achievable energy (the energy of the Template:Math state, called the ground state) is not equal to the minimum of the potential well, but Template:Math above it; this is called zero-point energy. Because of the zero-point energy, the position and momentum of the oscillator in the ground state are not fixed (as they would be in a classical oscillator), but have a small range of variance, in accordance with the Heisenberg uncertainty principle.

The ground state probability density is concentrated at the origin, which means the particle spends most of its time at the bottom of the potential well, as one would expect for a state with little energy. As the energy increases, the probability density peaks at the classical "turning points", where the state's energy coincides with the potential energy. (See the discussion below of the highly excited states.) This is consistent with the classical harmonic oscillator, in which the particle spends more of its time (and is therefore more likely to be found) near the turning points, where it is moving the slowest. The correspondence principle is thus satisfied. Moreover, special nondispersive wave packets, with minimum uncertainty, called coherent states oscillate very much like classical objects, as illustrated in the figure; they are not eigenstates of the Hamiltonian.

Ladder operator method

File:QHarmonicOscillator.png
Probability densities |ψn(x)|2 for the bound eigenstates, beginning with the ground state (n = 0) at the bottom and increasing in energy toward the top. The horizontal axis shows the position Template:Mvar, and brighter colors represent higher probability densities.

The "ladder operator" method, developed by Paul Dirac, allows extraction of the energy eigenvalues without directly solving the differential equation. It is generalizable to more complicated problems, notably in quantum field theory. Following this approach, we define the operators Template:Mvar and its adjoint Template:Math,

Note these operators classically are exactly the generators of normalized rotation in the phase space of and , i.e they describe the forwards and backwards evolution in time of a classical harmonic oscillator.

These operators lead to the useful representation of and ,

The operator Template:Mvar is not Hermitian, since itself and its adjoint Template:Math are not equal. The energy eigenstates Template:Math (also known as Fock states), when operated on by these ladder operators, give

It is then evident that Template:Math, in essence, appends a single quantum of energy to the oscillator, while Template:Mvar removes a quantum. For this reason, they are sometimes referred to as "creation" and "annihilation" operators.

From the relations above, we can also define a number operator Template:Mvar, which has the following property:

The following commutators can be easily obtained by substituting the canonical commutation relation,

And the Hamilton operator can be expressed as

so the eigenstate of Template:Mvar is also the eigenstate of energy.

The commutation property yields

and similarly,

This means that Template:Mvar acts on Template:Math to produce, up to a multiplicative constant, Template:Math, and Template:Math acts on Template:Math to produce Template:Math. For this reason, Template:Mvar is called a annihilation operator ("lowering operator"), and Template:Math a creation operator ("raising operator"). The two operators together are called ladder operators. In quantum field theory, Template:Mvar and Template:Math are alternatively called "annihilation" and "creation" operators because they destroy and create particles, which correspond to our quanta of energy.

Given any energy eigenstate, we can act on it with the lowering operator, Template:Mvar, to produce another eigenstate with Template:Math less energy. By repeated application of the lowering operator, it seems that we can produce energy eigenstates down to Template:Math. However, since

the smallest eigen-number is 0, and

In this case, subsequent applications of the lowering operator will just produce zero kets, instead of additional energy eigenstates. Furthermore, we have shown above that

Finally, by acting on |0⟩ with the raising operator and multiplying by suitable normalization factors, we can produce an infinite set of energy eigenstates

such that

which matches the energy spectrum given in the preceding section.

Arbitrary eigenstates can be expressed in terms of |0⟩,

Template:Math proof

Analytical questions

The preceding analysis is algebraic, using only the commutation relations between the raising and lowering operators. Once the algebraic analysis is complete, one should turn to analytical questions. First, one should find the ground state, that is, the solution of the equation . In the position representation, this is the first-order differential equation

whose solution is easily found to be the Gaussian[4]
Conceptually, it is important that there is only one solution of this equation; if there were, say, two linearly independent ground states, we would get two independent chains of eigenvectors for the harmonic oscillator. Once the ground state is computed, one can show inductively that the excited states are Hermite polynomials times the Gaussian ground state, using the explicit form of the raising operator in the position representation. One can also prove that, as expected from the uniqueness of the ground state, the Hermite functions energy eigenstates constructed by the ladder method form a complete orthonormal set of functions.[5]

Explicitly connecting with the previous section, the ground state |0⟩ in the position representation is determined by ,

hence
so that , and so on.

Natural length and energy scales

The quantum harmonic oscillator possesses natural scales for length and energy, which can be used to simplify the problem. These can be found by nondimensionalization.

The result is that, if energy is measured in units of Template:Math and distance in units of Template:Math, then the Hamiltonian simplifies to

while the energy eigenfunctions and eigenvalues simplify to Hermite functions and integers offset by a half,
where Template:Math are the Hermite polynomials.

To avoid confusion, these "natural units" will mostly not be adopted in this article. However, they frequently come in handy when performing calculations, by bypassing clutter.

For example, the fundamental solution (propagator) of Template:Math, the time-dependent Schrödinger operator for this oscillator, simply boils down to the Mehler kernel,[6][7]

where Template:Math. The most general solution for a given initial configuration Template:Math then is simply

See also: Path integral formulation#Simple harmonic oscillator

Coherent states

Main article: Coherent state
File:QHO-coherentstate3-animation-color.gif
Time evolution of the probability distribution (and phase, shown as color) of a coherent state with |α|=3.

The coherent states (also known as Glauber states) of the harmonic oscillator are special nondispersive wave packets, with minimum uncertainty Template:Math, whose observables' expectation values evolve like a classical system. They are eigenvectors of the annihilation operator, not the Hamiltonian, and form an overcomplete basis which consequentially lacks orthogonality.

The coherent states are indexed by Template:Math and expressed in the Template:Math basis as

Because and via the Kermack-McCrae identity, the last form is equivalent to a unitary displacement operator acting on the ground state: . The position space wave functions are

Since coherent states are not energy eigenstates, their time evolution is not a simple shift in wavefunction phase. The time-evolved states are, however, also coherent states but with phase-shifting parameter Template:Mvar instead: .

Highly excited states

Template:Multiple image When Template:Mvar is large, the eigenstates are localized into the classical allowed region, that is, the region in which a classical particle with energy Template:Math can move. The eigenstates are peaked near the turning points: the points at the ends of the classically allowed region where the classical particle changes direction. This phenomenon can be verified through asymptotics of the Hermite polynomials, and also through the WKB approximation.

The frequency of oscillation at Template:Mvar is proportional to the momentum Template:Math of a classical particle of energy Template:Math and position Template:Mvar. Furthermore, the square of the amplitude (determining the probability density) is inversely proportional to Template:Math, reflecting the length of time the classical particle spends near Template:Mvar. The system behavior in a small neighborhood of the turning point does not have a simple classical explanation, but can be modeled using an Airy function. Using properties of the Airy function, one may estimate the probability of finding the particle outside the classically allowed region, to be approximately

This is also given, asymptotically, by the integral

Phase space solutions

In the phase space formulation of quantum mechanics, eigenstates of the quantum harmonic oscillator in several different representations of the quasiprobability distribution can be written in closed form. The most widely used of these is for the Wigner quasiprobability distribution.

The Wigner quasiprobability distribution for the energy eigenstate Template:Math is, in the natural units described above,Template:Citation needed

where Ln are the Laguerre polynomials. This example illustrates how the Hermite and Laguerre polynomials are linked through the Wigner map.

Meanwhile, the Husimi Q function of the harmonic oscillator eigenstates have an even simpler form. If we work in the natural units described above, we have

This claim can be verified using the Segal–Bargmann transform. Specifically, since the raising operator in the Segal–Bargmann representation is simply multiplication by and the ground state is the constant function 1, the normalized harmonic oscillator states in this representation are simply . At this point, we can appeal to the formula for the Husimi Q function in terms of the Segal–Bargmann transform.

N-dimensional isotropic harmonic oscillator

The one-dimensional harmonic oscillator is readily generalizable to Template:Math dimensions, where Template:Math. In one dimension, the position of the particle was specified by a single coordinate, Template:Math. In Template:Math dimensions, this is replaced by Template:Math position coordinates, which we label Template:Math. Corresponding to each position coordinate is a momentum; we label these Template:Math. The canonical commutation relations between these operators are

The Hamiltonian for this system is

As the form of this Hamiltonian makes clear, the Template:Math-dimensional harmonic oscillator is exactly analogous to Template:Math independent one-dimensional harmonic oscillators with the same mass and spring constant. In this case, the quantities Template:Math would refer to the positions of each of the Template:Math particles. This is a convenient property of the Template:Math potential, which allows the potential energy to be separated into terms depending on one coordinate each.

This observation makes the solution straightforward. For a particular set of quantum numbers the energy eigenfunctions for the Template:Math-dimensional oscillator are expressed in terms of the 1-dimensional eigenfunctions as:

In the ladder operator method, we define Template:Math sets of ladder operators,

By an analogous procedure to the one-dimensional case, we can then show that each of the Template:Math and Template:Math operators lower and raise the energy by Template:Math respectively. The Hamiltonian is

This Hamiltonian is invariant under the dynamic symmetry group Template:Math (the unitary group in Template:Math dimensions), defined by
where is an element in the defining matrix representation of Template:Math.

The energy levels of the system are

As in the one-dimensional case, the energy is quantized. The ground state energy is Template:Math times the one-dimensional ground energy, as we would expect using the analogy to Template:Math independent one-dimensional oscillators. There is one further difference: in the one-dimensional case, each energy level corresponds to a unique quantum state. In Template:Math-dimensions, except for the ground state, the energy levels are degenerate, meaning there are several states with the same energy.

The degeneracy can be calculated relatively easily. As an example, consider the 3-dimensional case: Define Template:Math. All states with the same Template:Math will have the same energy. For a given Template:Math, we choose a particular Template:Math. Then Template:Math. There are Template:Math possible pairs Template:Math. Template:Math can take on the values Template:Math to Template:Math, and for each Template:Math the value of Template:Math is fixed. The degree of degeneracy therefore is:

Formula for general Template:Math and Template:Math [[[:Template:Math]] being the dimension of the symmetric irreducible Template:Math-th power representation of the unitary group Template:Math]:
The special case Template:Math = 3, given above, follows directly from this general equation. This is however, only true for distinguishable particles, or one particle in Template:Math dimensions (as dimensions are distinguishable). For the case of Template:Math bosons in a one-dimension harmonic trap, the degeneracy scales as the number of ways to partition an integer Template:Math using integers less than or equal to Template:Math.

This arises due to the constraint of putting Template:Math quanta into a state ket where and , which are the same constraints as in integer partition.

Example: 3D isotropic harmonic oscillator

File:2D Spherical Harmonic Orbitals.png
Schrödinger 3D spherical harmonic orbital solutions in 2D density plots; the Mathematica source code that used for generating the plots is at the top

The Schrödinger equation for a particle in a spherically-symmetric three-dimensional harmonic oscillator can be solved explicitly by separation of variables; see this article for the present case. This procedure is analogous to the separation performed in the hydrogen-like atom problem, but with a different spherically symmetric potential

where Template:Mvar is the mass of the particle. Because Template:Mvar will be used below for the magnetic quantum number, mass is indicated by Template:Mvar, instead of Template:Mvar, as earlier in this article.

The solution reads[8]

where

is a normalization constant; ;

are generalized Laguerre polynomials; The order Template:Mvar of the polynomial is a non-negative integer;

The energy eigenvalue is

The energy is usually described by the single quantum number

Because Template:Mvar is a non-negative integer, for every even Template:Mvar we have Template:Math and for every odd Template:Mvar we have Template:Math . The magnetic quantum number Template:Mvar is an integer satisfying Template:Math, so for every Template:Mvar and there are 2 + 1 different quantum states, labeled by Template:Mvar . Thus, the degeneracy at level Template:Mvar is

where the sum starts from 0 or 1, according to whether Template:Mvar is even or odd. This result is in accordance with the dimension formula above, and amounts to the dimensionality of a symmetric representation of Template:Math,[9] the relevant degeneracy group.

Applications

Harmonic oscillators lattice: phonons

See also: Canonical quantization

We can extend the notion of a harmonic oscillator to a one-dimensional lattice of many particles. Consider a one-dimensional quantum mechanical harmonic chain of N identical atoms. This is the simplest quantum mechanical model of a lattice, and we will see how phonons arise from it. The formalism that we will develop for this model is readily generalizable to two and three dimensions.

As in the previous section, we denote the positions of the masses by Template:Math, as measured from their equilibrium positions (i.e. Template:Math if the particle Template:Mvar is at its equilibrium position). In two or more dimensions, the Template:Math are vector quantities. The Hamiltonian for this system is

where Template:Mvar is the (assumed uniform) mass of each atom, and Template:Math and Template:Math are the position and momentum operators for the i th atom and the sum is made over the nearest neighbors (nn). However, it is customary to rewrite the Hamiltonian in terms of the normal modes of the wavevector rather than in terms of the particle coordinates so that one can work in the more convenient Fourier space.

We introduce, then, a set of Template:Mvar "normal coordinates" Template:Math, defined as the discrete Fourier transforms of the Template:Mvars, and Template:Mvar "conjugate momenta" Template:Mvar defined as the Fourier transforms of the Template:Mvars,

The quantity Template:Math will turn out to be the wave number of the phonon, i.e. 2π divided by the wavelength. It takes on quantized values, because the number of atoms is finite.

This preserves the desired commutation relations in either real space or wave vector space

From the general result

it is easy to show, through elementary trigonometry, that the potential energy term is
where

The Hamiltonian may be written in wave vector space as

Note that the couplings between the position variables have been transformed away; if the Template:Mvars and Template:Mvars were hermitian (which they are not), the transformed Hamiltonian would describe Template:Mvar uncoupled harmonic oscillators.

The form of the quantization depends on the choice of boundary conditions; for simplicity, we impose periodic boundary conditions, defining the Template:Math-th atom as equivalent to the first atom. Physically, this corresponds to joining the chain at its ends. The resulting quantization is

The upper bound to Template:Mvar comes from the minimum wavelength, which is twice the lattice spacing Template:Mvar, as discussed above.

The harmonic oscillator eigenvalues or energy levels for the mode Template:Math are

If we ignore the zero-point energy then the levels are evenly spaced at

So an exact amount of energy Template:Math, must be supplied to the harmonic oscillator lattice to push it to the next energy level. In analogy to the photon case when the electromagnetic field is quantised, the quantum of vibrational energy is called a phonon.

All quantum systems show wave-like and particle-like properties. The particle-like properties of the phonon are best understood using the methods of second quantization and operator techniques described elsewhere.[10]

In the continuum limit, a→0, N→∞, while Na is held fixed. The canonical coordinates Qk devolve to the decoupled momentum modes of a scalar field, , whilst the location index Template:Mvar (not the displacement dynamical variable) becomes the parameter Template:Mvar argument of the scalar field, .

Molecular vibrations

Main article: Molecular vibration
  • The vibrations of a diatomic molecule are an example of a two-body version of the quantum harmonic oscillator. In this case, the angular frequency is given by
    where is the reduced mass and and are the masses of the two atoms.[11]
  • The Hooke's atom is a simple model of the helium atom using the quantum harmonic oscillator.
  • Modelling phonons, as discussed above.
  • A charge with mass in a uniform magnetic field is an example of a one-dimensional quantum harmonic oscillator: Landau quantization.

See also

Template:Div col

Template:Div col end

References

  1. ^ Griffiths, David J. (2004). https://archive.org/details/introductiontoel00grif_0 Introduction to Quantum Mechanics, 2nd, Prentice Hall. ISBN 978-0-13-805326-0.
  2. ^ Liboff, Richard L. (2002). Introductory Quantum Mechanics. Addison–Wesley. ISBN 978-0-8053-8714-8.
  3. ^ Rashid, Muneer A. (2006). Transition amplitude for time-dependent linear harmonic oscillator with Linear time-dependent terms added to the Hamiltonian (PDF-Microsoft PowerPoint). National Center for Physics.
  4. ^ The normalization constant is , and satisfies the normalization condition .
  5. ^ See Theorem 11.4 in Template:Citation
  6. ^ Pauli, W. (2000), Wave Mechanics: Volume 5 of Pauli Lectures on Physics (Dover Books on Physics). Template:ISBN ; Section 44.
  7. ^ Condon, E. U. (1937). "Immersion of the Fourier transform in a continuous group of functional transformations", Proc. Natl. Acad. Sci. USA 23, 158–164. online
  8. ^ Albert Messiah, Quantum Mechanics, 1967, North-Holland, Ch XII,  § 15, p 456.online
  9. ^ Fradkin, D. M. "Three-dimensional isotropic harmonic oscillator and SU3." American Journal of Physics 33 (3) (1965) 207–211.
  10. ^ Mahan, GD (1981). Many particle physics. New York: Springer. ISBN 978-0306463389.
  11. ^ Quantum Harmonic Oscillator.

External links

Template:Use dmy dates

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