Coverage for qml_essentials/entanglement.py: 90%
185 statements
« prev ^ index » next coverage.py v7.9.2, created at 2025-08-18 11:46 +0000
1from typing import Optional, Any, List
2import pennylane as qml
3import pennylane.numpy as np
4from copy import deepcopy
5from qml_essentials.utils import logm_v
6from qml_essentials.model import Model
7import logging
9log = logging.getLogger(__name__)
12class Entanglement:
14 @staticmethod
15 def meyer_wallach(
16 model: Model,
17 n_samples: Optional[int | None],
18 seed: Optional[int],
19 scale: bool = False,
20 **kwargs: Any,
21 ) -> float:
22 """
23 Calculates the entangling capacity of a given quantum circuit
24 using Meyer-Wallach measure.
26 Args:
27 model (Model): The quantum circuit model.
28 n_samples (Optional[int]): Number of samples per qubit.
29 If None or < 0, the current parameters of the model are used.
30 seed (Optional[int]): Seed for the random number generator.
31 scale (bool): Whether to scale the number of samples.
32 kwargs (Any): Additional keyword arguments for the model function.
34 Returns:
35 float: Entangling capacity of the given circuit, guaranteed
36 to be between 0.0 and 1.0.
37 """
38 if "noise_params" in kwargs:
39 log.warning(
40 "Meyer-Wallach measure not suitable for noisy circuits.\
41 Consider 'relative_entropy' instead."
42 )
44 if scale:
45 n_samples = np.power(2, model.n_qubits) * n_samples
47 rng = np.random.default_rng(seed)
48 if n_samples is not None and n_samples > 0:
49 assert seed is not None, "Seed must be provided when samples > 0"
50 # TODO: maybe switch to JAX rng
51 model.initialize_params(rng=rng, repeat=n_samples)
52 else:
53 if seed is not None:
54 log.warning("Seed is ignored when samples is 0")
56 # implicitly set input to none in case it's not needed
57 kwargs.setdefault("inputs", None)
58 # explicitly set execution type because everything else won't work
59 rhos = model(execution_type="density", **kwargs).reshape(
60 -1, 2**model.n_qubits, 2**model.n_qubits
61 )
63 measure = np.zeros(len(rhos))
65 for i, rho in enumerate(rhos):
66 measure[i] = Entanglement._compute_meyer_wallach_meas(rho, model.n_qubits)
68 # Average all iterated states
69 entangling_capability = min(max(measure.mean(), 0.0), 1.0)
70 log.debug(f"Variance of measure: {measure.var()}")
72 # catch floating point errors
73 return float(entangling_capability)
75 @staticmethod
76 def _compute_meyer_wallach_meas(rho: np.ndarray, n_qubits: int):
77 qb = list(range(n_qubits))
78 entropy = 0
79 for j in range(n_qubits):
80 # Formula 6 in https://doi.org/10.48550/arXiv.quant-ph/0305094
81 density = qml.math.partial_trace(rho, qb[:j] + qb[j + 1 :])
82 # only real values, because imaginary part will be separate
83 # in all following calculations anyway
84 # entropy should be 1/2 <= entropy <= 1
85 entropy += np.trace((density @ density).real)
87 # inverse averaged entropy and scale to [0, 1]
88 return 2 * (1 - entropy / n_qubits)
90 @staticmethod
91 def bell_measurements(
92 model: Model, n_samples: int, seed: int, scale: bool = False, **kwargs: Any
93 ) -> float:
94 """
95 Compute the Bell measurement for a given model.
97 Args:
98 model (Model): The quantum circuit model.
99 n_samples (int): The number of samples to compute the measure for.
100 seed (int): The seed for the random number generator.
101 scale (bool): Whether to scale the number of samples
102 according to the number of qubits.
103 **kwargs (Any): Additional keyword arguments for the model function.
105 Returns:
106 float: The Bell measurement value.
107 """
108 if "noise_params" in kwargs:
109 log.warning(
110 "Bell Measurements not suitable for noisy circuits.\
111 Consider 'relative_entropy' instead."
112 )
114 if scale:
115 n_samples = np.power(2, model.n_qubits) * n_samples
117 def _circuit(
118 params: np.ndarray,
119 inputs: np.ndarray,
120 enc_params: Optional[np.ndarray] = None,
121 ) -> List[np.ndarray]:
122 """
123 Compute the Bell measurement circuit.
125 Args:
126 params (np.ndarray): The model parameters.
127 inputs (np.ndarray): The input to the model.
128 enc_params (Optional[np.ndarray]): The frequency encoding parameters.
130 Returns:
131 List[np.ndarray]: The probabilities of the Bell measurement.
132 """
133 model._variational(params, inputs, enc_params)
135 qml.map_wires(
136 model._variational,
137 {i: i + model.n_qubits for i in range(model.n_qubits)},
138 )(params, inputs)
140 for q in range(model.n_qubits):
141 qml.CNOT(wires=[q, q + model.n_qubits])
142 qml.H(q)
144 obs_wires = [(q, q + model.n_qubits) for q in range(model.n_qubits)]
145 return [qml.probs(wires=w) for w in obs_wires]
147 model.circuit = qml.QNode(
148 _circuit,
149 qml.device(
150 "default.qubit",
151 shots=model.shots,
152 wires=model.n_qubits * 2,
153 ),
154 )
156 rng = np.random.default_rng(seed)
157 if n_samples is not None and n_samples > 0:
158 assert seed is not None, "Seed must be provided when samples > 0"
159 # TODO: maybe switch to JAX rng
160 model.initialize_params(rng=rng, repeat=n_samples)
161 params = model.params
162 else:
163 if seed is not None:
164 log.warning("Seed is ignored when samples is 0")
166 if len(model.params.shape) <= 2:
167 params = model.params.reshape(*model.params.shape, 1)
168 else:
169 log.info(f"Using sample size of model params: {model.params.shape[-1]}")
170 params = model.params
172 n_samples = params.shape[-1]
173 measure = np.zeros(n_samples)
175 # implicitly set input to none in case it's not needed
176 kwargs.setdefault("inputs", None)
177 exp = model(params=params, **kwargs)
178 exp = 1 - 2 * exp[..., -1]
179 measure = 2 * (1 - exp.mean(axis=0))
180 entangling_capability = min(max(measure.mean(), 0.0), 1.0)
181 log.debug(f"Variance of measure: {measure.var()}")
183 return float(entangling_capability)
185 @staticmethod
186 def relative_entropy(
187 model: Model,
188 n_samples: int,
189 n_sigmas: int,
190 seed: Optional[int],
191 scale: bool = False,
192 **kwargs: Any,
193 ) -> float:
194 """
195 Calculates the relative entropy of entanglement of a given quantum
196 circuit. This measure is also applicable to mixed state, albeit it
197 might me not fully accurate in this simplified case.
199 As the relative entropy is generally defined as the smallest relative
200 entropy from the state in question to the set of separable states.
201 However, as computing the nearest separable state is NP-hard, we select
202 n_sigmas of random separable states to compute the distance to, which
203 is not necessarily the nearest. Thus, this measure of entanglement
204 presents an upper limit of entanglement.
206 As the relative entropy is not necessarily between zero and one, this
207 function also normalises by the relative entroy to the GHZ state.
209 Args:
210 model (Model): The quantum circuit model.
211 n_samples (int): Number of samples per qubit.
212 If <= 0, the current parameters of the model are used.
213 n_sigmas (int): Number of random separable pure states to compare against.
214 seed (Optional[int]): Seed for the random number generator.
215 scale (bool): Whether to scale the number of samples.
216 kwargs (Any): Additional keyword arguments for the model function.
218 Returns:
219 float: Entangling capacity of the given circuit, guaranteed
220 to be between 0.0 and 1.0.
221 """
222 dim = np.power(2, model.n_qubits)
223 if scale:
224 n_samples = dim * n_samples
225 n_sigmas = dim * n_sigmas
227 rng = np.random.default_rng(seed)
229 # Random separable states
230 log_sigmas = sample_random_separable_states(
231 model.n_qubits, n_samples=n_sigmas, rng=rng, take_log=True
232 )
234 if n_samples is not None and n_samples > 0:
235 assert seed is not None, "Seed must be provided when samples > 0"
236 model.initialize_params(rng=rng, repeat=n_samples)
237 else:
238 if seed is not None:
239 log.warning("Seed is ignored when samples is 0")
241 if len(model.params.shape) <= 2:
242 model.params = model.params.reshape(*model.params.shape, 1)
243 else:
244 log.info(f"Using sample size of model params: {model.params.shape[-1]}")
246 ghz_model = Model(model.n_qubits, 1, "GHZ", data_reupload=False)
248 normalised_entropies = np.zeros((n_sigmas, model.params.shape[-1]))
249 for j, log_sigma in enumerate(log_sigmas):
251 # Entropy of GHZ states should be maximal
252 ghz_entropy = Entanglement._compute_rel_entropies(
253 ghz_model,
254 log_sigma,
255 )
257 rel_entropy = Entanglement._compute_rel_entropies(
258 model, log_sigma, **kwargs
259 )
261 normalised_entropies[j] = rel_entropy / ghz_entropy
263 # Average all iterated states
264 entangling_capability = normalised_entropies.min(axis=0).mean()
265 log.debug(f"Variance of measure: {normalised_entropies.var()}")
267 return entangling_capability
269 @staticmethod
270 def _compute_rel_entropies(
271 model: Model,
272 log_sigma: np.ndarray,
273 **kwargs,
274 ) -> np.ndarray:
275 """
276 Compute the relative entropy for a given model.
278 Args:
279 model (Model): The model for which to compute entanglement
280 log_sigma (np.ndarray): Density matrix of next separable state
282 Returns:
283 np.ndarray: Relative Entropy for each sample
284 """
285 # implicitly set input to none in case it's not needed
286 kwargs.setdefault("inputs", None)
287 # explicitly set execution type because everything else won't work
288 rho = model(execution_type="density", **kwargs)
289 rho = rho.reshape(-1, 2**model.n_qubits, 2**model.n_qubits)
290 log_rho = logm_v(rho) / np.log(2)
292 rel_entropies = np.abs(np.trace(rho @ (log_rho - log_sigma), axis1=1, axis2=2))
294 return rel_entropies
296 @staticmethod
297 def entanglement_of_formation(
298 model: Model,
299 n_samples: int,
300 seed: Optional[int],
301 scale: bool = False,
302 always_decompose: bool = False,
303 **kwargs: Any,
304 ) -> float:
305 """
306 This function implements the entanglement of formation for mixed
307 quantum systems.
308 In that a mixed state gets decomposed into pure states with respective
309 probabilities using the eigendecomposition of the density matrix.
310 Then, the Meyer-Wallach measure is computed for each pure state,
311 weighted by the eigenvalue.
312 See e.g. https://doi.org/10.48550/arXiv.quant-ph/0504163
314 Note that the decomposition is *not unique*! Therefore, this measure
315 presents the entanglement for *some* decomposition into pure states,
316 not necessarily the one that is anticipated when applying the Kraus
317 channels.
318 If a pure state is provided, this results in the same value as the
319 Entanglement.meyer_wallach function if `always_decompose` flag is not set.
321 Args:
322 model (Model): The quantum circuit model.
323 n_samples (int): Number of samples per qubit.
324 seed (Optional[int]): Seed for the random number generator.
325 scale (bool): Whether to scale the number of samples.
326 always_decompose (bool): Whether to explicitly compute the
327 entantlement of formation for the eigendecomposition of a pure
328 state.
329 kwargs (Any): Additional keyword arguments for the model function.
331 Returns:
332 float: Entangling capacity of the given circuit, guaranteed
333 to be between 0.0 and 1.0.
334 """
336 if scale:
337 n_samples = np.power(2, model.n_qubits) * n_samples
339 rng = np.random.default_rng(seed)
340 if n_samples is not None and n_samples > 0:
341 assert seed is not None, "Seed must be provided when samples > 0"
342 model.initialize_params(rng=rng, repeat=n_samples)
343 else:
344 if seed is not None:
345 log.warning("Seed is ignored when samples is 0")
347 if len(model.params.shape) <= 2:
348 model.params = model.params.reshape(*model.params.shape, 1)
349 else:
350 log.info(f"Using sample size of model params: {model.params.shape[-1]}")
352 # implicitly set input to none in case it's not needed
353 kwargs.setdefault("inputs", None)
354 rhos = model(execution_type="density", **kwargs)
355 rhos = rhos.reshape(-1, 2**model.n_qubits, 2**model.n_qubits)
356 entanglement = np.zeros(len(rhos))
357 for i, rho in enumerate(rhos):
358 entanglement[i] = Entanglement._compute_entanglement_of_formation(
359 rho, model.n_qubits, always_decompose
360 )
361 entangling_capability = min(max(entanglement.mean(), 0.0), 1.0)
362 return float(entangling_capability)
364 @staticmethod
365 def _compute_entanglement_of_formation(
366 rho: np.ndarray, n_qubits: int, always_decompose: bool
367 ) -> float:
368 """
369 Computes the entanglement of formation for a given density matrix rho.
371 Args:
372 rho (np.ndarray): The density matrix
373 n_qubits (int): Number of qubits
374 always_decompose (bool): Whether to explicitly compute the
375 entantlement of formation for the eigendecomposition of a pure
376 state.
378 Returns:
379 float: Entanglement for the provided state.
380 """
381 eigenvalues, eigenvectors = np.linalg.eigh(rho)
382 if any(np.isclose(eigenvalues, 1.0)) and not always_decompose: # Pure state
383 return Entanglement._compute_meyer_wallach_meas(rho, n_qubits)
384 ent = 0
385 for prob, ev in zip(eigenvalues, eigenvectors):
386 ev = ev.reshape(-1, 1)
387 rho = ev @ np.conjugate(ev).T
388 measure = Entanglement._compute_meyer_wallach_meas(rho, n_qubits)
389 ent += prob * measure
390 return ent
392 @staticmethod
393 def concentratable_entanglement(
394 model: Model, n_samples: int, seed: int, scale: bool = False, **kwargs: Any
395 ) -> float:
396 """
397 Computes the concentratable entanglement of a given model.
399 This method utilizes the Concentratable Entanglement measure from
400 https://arxiv.org/abs/2104.06923.
402 Args:
403 model (Model): The quantum circuit model.
404 n_samples (int): The number of samples to compute the measure for.
405 seed (int): The seed for the random number generator.
406 scale (bool): Whether to scale the number of samples according to
407 the number of qubits.
408 **kwargs (Any): Additional keyword arguments for the model function.
410 Returns:
411 float: Entangling capability of the given circuit, guaranteed
412 to be between 0.0 and 1.0.
413 """
414 if "noise_params" in kwargs:
415 log.warning(
416 "Concentratable entanglement is not suitable for noisy circuits.\
417 Consider 'relative_entropy' instead."
418 )
420 n = model.n_qubits
422 if scale:
423 n_samples = np.power(2, model.n) * n_samples
425 def _circuit(
426 params: np.ndarray,
427 inputs: np.ndarray,
428 enc_params: Optional[np.ndarray] = None,
429 ) -> List[np.ndarray]:
430 """
431 Constructs a circuit to compute the concentratable entanglement using the
432 swap test by creating two copies of the models circuit and map the output
433 wires accordingly
435 Args:
436 params (np.ndarray): The model parameters.
437 inputs (np.ndarray): The input data for the model.
438 enc_params (Optional[np.ndarray]): Optional encoding parameters.
440 Returns:
441 List[np.ndarray]: Probabilities obtained from the swap test circuit.
442 """
444 qml.map_wires(model._variational, {i: i + n for i in range(n)})(
445 params, inputs, enc_params
446 )
447 qml.map_wires(model._variational, {i: i + 2 * n for i in range(n)})(
448 params, inputs, enc_params
449 )
451 # Perform swap test
452 for i in range(n):
453 qml.H(i)
455 for i in range(n):
456 qml.CSWAP([i, i + n, i + 2 * n])
458 for i in range(n):
459 qml.H(i)
461 return qml.probs(wires=[i for i in range(n)])
463 model.circuit = qml.QNode(
464 _circuit,
465 qml.device(
466 "default.qubit",
467 shots=model.shots,
468 wires=n * 3,
469 ),
470 )
472 rng = np.random.default_rng(seed)
473 if n_samples is not None and n_samples > 0:
474 assert seed is not None, "Seed must be provided when samples > 0"
475 model.initialize_params(rng=rng, repeat=n_samples)
476 params = model.params
477 else:
478 if seed is not None:
479 log.warning("Seed is ignored when samples is 0")
481 if len(model.params.shape) <= 2:
482 params = model.params.reshape(*model.params.shape, 1)
483 else:
484 log.info(f"Using sample size of model params: {model.params.shape[-1]}")
485 params = model.params
487 n_samples = params.shape[-1]
489 # implicitly set input to none in case it's not needed
490 kwargs.setdefault("inputs", None)
492 samples_probs = model(params=params, execution_type="probs", **kwargs)
493 if n_samples == 1:
494 samples_probs = [samples_probs]
496 ce_measure = np.zeros(len(samples_probs))
498 for i, probs in enumerate(samples_probs):
499 ce_measure[i] = 1 - probs[0]
501 # Average all iterated states
502 entangling_capability = min(max(ce_measure.mean(), 0.0), 1.0)
503 log.debug(f"Variance of measure: {ce_measure.var()}")
505 # catch floating point errors
506 return float(entangling_capability)
509def sample_random_separable_states(
510 n_qubits: int, n_samples: int, rng: np.random.Generator, take_log: bool = False
511) -> np.ndarray:
512 """
513 Sample random separable states (density matrix).
515 Args:
516 n_qubits (int): number of qubits in the state
517 n_samples (int): number of states
518 rng (np.random.Generator): random number generator
519 take_log (bool): if the matrix logarithm of the density matrix should be taken.
521 Returns:
522 np.ndarray: Density matrices of shape (n_samples, 2**n_qubits, 2**n_qubits)
523 """
524 model = Model(n_qubits, 1, "No_Entangling", data_reupload=False)
525 model.initialize_params(rng=rng, repeat=n_samples)
526 # explicitly set execution type because everything else won't work
527 sigmas = model(execution_type="density", inputs=None)
528 if take_log:
529 sigmas = logm_v(sigmas) / np.log(2)
531 return sigmas