Coverage for qml_essentials/ansaetze.py: 96%

1from abc import ABC, abstractmethod 

2from typing import Any, Optional, List, Union, Dict 

3import numbers 

4import pennylane.numpy as np 

5import pennylane as qml 

6import jax 

7from jax import numpy as jnp 

8import itertools 

9from contextlib import contextmanager 

10import logging 

11 

12jax.config.update("jax_enable_x64", True) 

13log = logging.getLogger(__name__) 

14 

15 

16class Circuit(ABC): 

17 def __init__(self): 

18 pass 

19 

20 @abstractmethod 

21 def n_params_per_layer(n_qubits: int) -> int: 

22 raise NotImplementedError("n_params_per_layer method is not implemented") 

23 

24 def n_pulse_params_per_layer(n_qubits: int) -> int: 

25 """ 

26 Return the number of pulse parameters per layer. 

27 

28 Subclasses that do not use pulse-level simulation do not need to override this. 

29 If called and not overridden, this will raise NotImplementedError. 

30 """ 

31 raise NotImplementedError("n_pulse_params_per_layer method is not implemented") 

32 

33 @abstractmethod 

34 def get_control_indices(self, n_qubits: int) -> List[int]: 

35 """ 

36 Returns the indices for the controlled rotation gates for one layer. 

37 Indices should slice the list of all parameters for one layer as follows: 

38 [indices[0]:indices[1]:indices[2]] 

39 

40 Parameters 

41 ---------- 

42 n_qubits : int 

43 Number of qubits in the circuit 

44 

45 Returns 

46 ------- 

47 Optional[np.ndarray] 

48 List of all controlled indices, or None if the circuit does not 

49 contain controlled rotation gates. 

50 """ 

51 raise NotImplementedError("get_control_indices method is not implemented") 

52 

53 def get_control_angles(self, w: np.ndarray, n_qubits: int) -> Optional[np.ndarray]: 

54 """ 

55 Returns the angles for the controlled rotation gates from the list of 

56 all parameters for one layer. 

57 

58 Parameters 

59 ---------- 

60 w : np.ndarray 

61 List of parameters for one layer 

62 n_qubits : int 

63 Number of qubits in the circuit 

64 

65 Returns 

66 ------- 

67 Optional[np.ndarray] 

68 List of all controlled parameters, or None if the circuit does not 

69 contain controlled rotation gates. 

70 """ 

71 indices = self.get_control_indices(n_qubits) 

72 if indices is None: 

73 return np.array([]) 

74 

75 return w[indices[0] : indices[1] : indices[2]] 

76 

77 def _build(self, w: np.ndarray, n_qubits: int, **kwargs): 

78 """ 

79 Builds one layer of the circuit using either unitary or pulse-level parameters. 

80 

81 Parameters 

82 ---------- 

83 w : np.ndarray 

84 Array of parameters for the current layer. 

85 n_qubits : int 

86 Number of qubits in the circuit. 

87 **kwargs 

88 Additional keyword arguments. Supports: 

89 - gate_mode : str, optional 

90 "unitary" (default) or "pulse" to use pulse-level simulation. 

91 - pulse_params : jnp.ndarray, optional 

92 Array of pulse parameters to use if gate_mode="pulse". 

93 - noise_params : dict, optional 

94 Dictionary of noise parameters. 

95 

96 Raises 

97 ------ 

98 ValueError 

99 If the number of provided pulse parameters does not match the expected 

100 number per layer. 

101 """ 

102 gate_mode = kwargs.get("gate_mode", "unitary") 

103 

104 if gate_mode == "pulse" and "pulse_params" in kwargs: 

105 pulse_params_per_layer = self.n_pulse_params_per_layer(n_qubits) 

106 

107 if len(kwargs["pulse_params"]) != pulse_params_per_layer: 

108 raise ValueError( 

109 f"Pulse params length {len(kwargs['pulse_params'])} " 

110 f"does not match expected {pulse_params_per_layer} " 

111 f"for {n_qubits} qubits" 

112 ) 

113 

114 with Gates.pulse_manager_context(kwargs["pulse_params"]): 

115 return self.build(w, n_qubits, **kwargs) 

116 else: 

117 return self.build(w, n_qubits, **kwargs) 

118 

119 @abstractmethod 

120 def build(self, n_qubits: int, n_layers: int): 

121 raise NotImplementedError("build method is not implemented") 

122 

123 def __call__(self, *args: Any, **kwds: Any) -> Any: 

124 self._build(*args, **kwds) 

125 

126 

127class UnitaryGates: 

128 rng = np.random.default_rng() 

129 batch_gate_error = True 

130 

131 @staticmethod 

132 def init_rng(seed: int): 

133 """ 

134 Initializes the random number generator with the given seed. 

135 

136 Parameters 

137 ---------- 

138 seed : int 

139 The seed for the random number generator. 

140 """ 

141 UnitaryGates.rng = np.random.default_rng(seed) 

142 

143 @staticmethod 

144 def NQubitDepolarizingChannel(p, wires): 

145 """ 

146 Generates the Kraus operators for an n-qubit depolarizing channel. 

147 

148 The n-qubit depolarizing channel is defined as: 

149 E(rho) = sqrt(1 - p * (4^n - 1) / 4^n) * rho 

150 + sqrt(p / 4^n) * ∑_{P ≠ I^{⊗n}} P rho P† 

151 where the sum is over all non-identity n-qubit Pauli operators 

152 (i.e., tensor products of {I, X, Y, Z} excluding the identity operator I^{⊗n}). 

153 Each Pauli error operator is weighted equally by p / 4^n. 

154 

155 This operator-sum (Kraus) representation models uniform depolarizing noise 

156 acting on n qubits simultaneously. It is useful for simulating realistic 

157 multi-qubit noise affecting entangling gates in noisy quantum circuits. 

158 

159 Parameters 

160 ---------- 

161 p : float 

162 The total probability of an n-qubit depolarizing error occurring. 

163 Must satisfy 0 ≤ p ≤ 1. 

164 

165 wires : Sequence[int] 

166 The list of qubit indices (wires) on which the channel acts. 

167 Must contain at least 2 qubits. 

168 

169 Returns 

170 ------- 

171 qml.QubitChannel 

172 A PennyLane QubitChannel constructed from the Kraus operators representing 

173 the n-qubit depolarizing noise channel acting on the specified wires. 

174 """ 

175 

176 def n_qubit_depolarizing_kraus(p: float, n: int) -> List[np.ndarray]: 

177 if not (0.0 <= p <= 1.0): 

178 raise ValueError(f"Probability p must be between 0 and 1, got {p}") 

179 if n < 2: 

180 raise ValueError(f"Number of qubits must be >= 2, got {n}") 

181 

182 Id = np.eye(2) 

183 X = qml.matrix(qml.PauliX(0)) 

184 Y = qml.matrix(qml.PauliY(0)) 

185 Z = qml.matrix(qml.PauliZ(0)) 

186 paulis = [Id, X, Y, Z] 

187 

188 dim = 2**n 

189 all_ops = [] 

190 

191 # Generate all n-qubit Pauli tensor products: 

192 for indices in itertools.product(range(4), repeat=n): 

193 P = np.eye(1) 

194 for idx in indices: 

195 P = np.kron(P, paulis[idx]) 

196 all_ops.append(P) 

197 

198 # Identity operator corresponds to all zeros indices (Id^n) 

199 K0 = np.sqrt(1 - p * (4**n - 1) / (4**n)) * np.eye(dim) 

200 

201 kraus_ops = [] 

202 for i, P in enumerate(all_ops): 

203 if i == 0: 

204 # Skip the identity, already handled as K0 

205 continue 

206 kraus_ops.append(np.sqrt(p / (4**n)) * P) 

207 

208 return [K0] + kraus_ops 

209 

210 return qml.QubitChannel(n_qubit_depolarizing_kraus(p, len(wires)), wires=wires) 

211 

212 @staticmethod 

213 def Noise( 

214 wires: Union[int, List[int]], noise_params: Optional[Dict[str, float]] = None 

215 ) -> None: 

216 """ 

217 Applies noise to the given wires. 

218 

219 Parameters 

220 ---------- 

221 wires : Union[int, List[int]] 

222 The wire(s) to apply the noise to. 

223 noise_params : Optional[Dict[str, float]] 

224 A dictionary of noise parameters. The following noise gates are 

225 supported: 

226 -BitFlip: Applies a bit flip error to the given wires. 

227 -PhaseFlip: Applies a phase flip error to the given wires. 

228 -Depolarizing: Applies a depolarizing channel error to the 

229 given wires. 

230 -MultiQubitDepolarizing: Applies a two-qubit depolarizing channel 

231 error to the given wires. 

232 

233 All parameters are optional and default to 0.0 if not provided. 

234 """ 

235 if noise_params is not None: 

236 if isinstance(wires, int): 

237 wires = [wires] # single qubit gate 

238 

239 # noise on single qubits 

240 for wire in wires: 

241 bf = noise_params.get("BitFlip", 0.0) 

242 if bf > 0: 

243 qml.BitFlip(bf, wires=wire) 

244 

245 pf = noise_params.get("PhaseFlip", 0.0) 

246 if pf > 0: 

247 qml.PhaseFlip(pf, wires=wire) 

248 

249 dp = noise_params.get("Depolarizing", 0.0) 

250 if dp > 0: 

251 qml.DepolarizingChannel(dp, wires=wire) 

252 

253 # noise on two-qubits 

254 if len(wires) > 1: 

255 p = noise_params.get("MultiQubitDepolarizing", 0.0) 

256 if p > 0: 

257 UnitaryGates.NQubitDepolarizingChannel(p, wires) 

258 

259 @staticmethod 

260 def GateError( 

261 w: float, noise_params: Optional[Dict[str, float]] = None 

262 ) -> np.ndarray: 

263 """ 

264 Applies a gate error to the given rotation angle(s). 

265 

266 Parameters 

267 ---------- 

268 w : Union[float, np.ndarray, List[float]] 

269 The rotation angle in radians. 

270 noise_params : Optional[Dict[str, float]] 

271 A dictionary of noise parameters. The following noise gates are 

272 supported: 

273 -GateError: Applies a normal distribution error to the rotation 

274 angle. The standard deviation of the noise is specified by 

275 the "GateError" key in the dictionary. 

276 

277 All parameters are optional and default to 0.0 if not provided. 

278 

279 Returns 

280 ------- 

281 float 

282 The modified rotation angle after applying the gate error. 

283 """ 

284 if noise_params is not None and noise_params.get("GateError", None) is not None: 

285 w += UnitaryGates.rng.normal( 

286 0, 

287 noise_params["GateError"], 

288 ( 

289 w.shape 

290 if isinstance(w, np.ndarray) and UnitaryGates.batch_gate_error 

291 else None 

292 ), 

293 ) 

294 return w 

295 

296 @staticmethod 

297 def Rot(phi, theta, omega, wires, noise_params=None): 

298 """ 

299 Applies a rotation gate to the given wires and adds `Noise`. 

300 

301 Parameters 

302 ---------- 

303 phi : Union[float, np.ndarray, List[float]] 

304 The first rotation angle in radians. 

305 theta : Union[float, np.ndarray, List[float]] 

306 The second rotation angle in radians. 

307 omega : Union[float, np.ndarray, List[float]] 

308 The third rotation angle in radians. 

309 wires : Union[int, List[int]] 

310 The wire(s) to apply the rotation gate to. 

311 noise_params : Optional[Dict[str, float]] 

312 A dictionary of noise parameters. The following noise gates are 

313 supported: 

314 -BitFlip: Applies a bit flip error to the given wires. 

315 -PhaseFlip: Applies a phase flip error to the given wires. 

316 -Depolarizing: Applies a depolarizing channel error to the 

317 given wires. 

318 

319 All parameters are optional and default to 0.0 if not provided. 

320 """ 

321 if noise_params is not None and "GateError" in noise_params: 

322 phi = UnitaryGates.GateError(phi, noise_params) 

323 theta = UnitaryGates.GateError(theta, noise_params) 

324 omega = UnitaryGates.GateError(omega, noise_params) 

325 qml.Rot(phi, theta, omega, wires=wires) 

326 UnitaryGates.Noise(wires, noise_params) 

327 

328 @staticmethod 

329 def RX(w, wires, noise_params=None): 

330 """ 

331 Applies a rotation around the X axis to the given wires and adds `Noise` 

332 

333 Parameters 

334 ---------- 

335 w : Union[float, np.ndarray, List[float]] 

336 The rotation angle in radians. 

337 wires : Union[int, List[int]] 

338 The wire(s) to apply the rotation gate to. 

339 noise_params : Optional[Dict[str, float]] 

340 A dictionary of noise parameters. The following noise gates are 

341 supported: 

342 -BitFlip: Applies a bit flip error to the given wires. 

343 -PhaseFlip: Applies a phase flip error to the given wires. 

344 -Depolarizing: Applies a depolarizing channel error to the 

345 given wires. 

346 

347 All parameters are optional and default to 0.0 if not provided. 

348 """ 

349 w = UnitaryGates.GateError(w, noise_params) 

350 qml.RX(w, wires=wires) 

351 UnitaryGates.Noise(wires, noise_params) 

352 

353 @staticmethod 

354 def RY(w, wires, noise_params=None): 

355 """ 

356 Applies a rotation around the Y axis to the given wires and adds `Noise` 

357 

358 Parameters 

359 ---------- 

360 w : Union[float, np.ndarray, List[float]] 

361 The rotation angle in radians. 

362 wires : Union[int, List[int]] 

363 The wire(s) to apply the rotation gate to. 

364 noise_params : Optional[Dict[str, float]] 

365 A dictionary of noise parameters. The following noise gates are 

366 supported: 

367 -BitFlip: Applies a bit flip error to the given wires. 

368 -PhaseFlip: Applies a phase flip error to the given wires. 

369 -Depolarizing: Applies a depolarizing channel error to the 

370 given wires. 

371 

372 All parameters are optional and default to 0.0 if not provided. 

373 """ 

374 w = UnitaryGates.GateError(w, noise_params) 

375 qml.RY(w, wires=wires) 

376 UnitaryGates.Noise(wires, noise_params) 

377 

378 @staticmethod 

379 def RZ(w, wires, noise_params=None): 

380 """ 

381 Applies a rotation around the Z axis to the given wires and adds `Noise` 

382 

383 Parameters 

384 ---------- 

385 w : Union[float, np.ndarray, List[float]] 

386 The rotation angle in radians. 

387 wires : Union[int, List[int]] 

388 The wire(s) to apply the rotation gate to. 

389 noise_params : Optional[Dict[str, float]] 

390 A dictionary of noise parameters. The following noise gates are 

391 supported: 

392 -BitFlip: Applies a bit flip error to the given wires. 

393 -PhaseFlip: Applies a phase flip error to the given wires. 

394 -Depolarizing: Applies a depolarizing channel error to the 

395 given wires. 

396 

397 All parameters are optional and default to 0.0 if not provided. 

398 """ 

399 w = UnitaryGates.GateError(w, noise_params) 

400 qml.RZ(w, wires=wires) 

401 UnitaryGates.Noise(wires, noise_params) 

402 

403 @staticmethod 

404 def CRX(w, wires, noise_params=None): 

405 """ 

406 Applies a controlled rotation around the X axis to the given wires 

407 and adds `Noise` 

408 

409 Parameters 

410 ---------- 

411 w : Union[float, np.ndarray, List[float]] 

412 The rotation angle in radians. 

413 wires : Union[int, List[int]] 

414 The wire(s) to apply the controlled rotation gate to. 

415 noise_params : Optional[Dict[str, float]] 

416 A dictionary of noise parameters. The following noise gates are 

417 supported: 

418 -BitFlip: Applies a bit flip error to the given wires. 

419 -PhaseFlip: Applies a phase flip error to the given wires. 

420 -Depolarizing: Applies a depolarizing channel error to the 

421 given wires. 

422 

423 All parameters are optional and default to 0.0 if not provided. 

424 """ 

425 w = UnitaryGates.GateError(w, noise_params) 

426 qml.CRX(w, wires=wires) 

427 UnitaryGates.Noise(wires, noise_params) 

428 

429 @staticmethod 

430 def CRY(w, wires, noise_params=None): 

431 """ 

432 Applies a controlled rotation around the Y axis to the given wires 

433 and adds `Noise` 

434 

435 Parameters 

436 ---------- 

437 w : Union[float, np.ndarray, List[float]] 

438 The rotation angle in radians. 

439 wires : Union[int, List[int]] 

440 The wire(s) to apply the controlled rotation gate to. 

441 noise_params : Optional[Dict[str, float]] 

442 A dictionary of noise parameters. The following noise gates are 

443 supported: 

444 -BitFlip: Applies a bit flip error to the given wires. 

445 -PhaseFlip: Applies a phase flip error to the given wires. 

446 -Depolarizing: Applies a depolarizing channel error to the 

447 given wires. 

448 

449 All parameters are optional and default to 0.0 if not provided. 

450 """ 

451 w = UnitaryGates.GateError(w, noise_params) 

452 qml.CRY(w, wires=wires) 

453 UnitaryGates.Noise(wires, noise_params) 

454 

455 @staticmethod 

456 def CRZ(w, wires, noise_params=None): 

457 """ 

458 Applies a controlled rotation around the Z axis to the given wires 

459 and adds `Noise` 

460 

461 Parameters 

462 ---------- 

463 w : Union[float, np.ndarray, List[float]] 

464 The rotation angle in radians. 

465 wires : Union[int, List[int]] 

466 The wire(s) to apply the controlled rotation gate to. 

467 noise_params : Optional[Dict[str, float]] 

468 A dictionary of noise parameters. The following noise gates are 

469 supported: 

470 -BitFlip: Applies a bit flip error to the given wires. 

471 -PhaseFlip: Applies a phase flip error to the given wires. 

472 -Depolarizing: Applies a depolarizing channel error to the 

473 given wires. 

474 

475 All parameters are optional and default to 0.0 if not provided. 

476 """ 

477 w = UnitaryGates.GateError(w, noise_params) 

478 qml.CRZ(w, wires=wires) 

479 UnitaryGates.Noise(wires, noise_params) 

480 

481 @staticmethod 

482 def CX(wires, noise_params=None): 

483 """ 

484 Applies a controlled NOT gate to the given wires and adds `Noise` 

485 

486 Parameters 

487 ---------- 

488 wires : Union[int, List[int]] 

489 The wire(s) to apply the controlled NOT gate to. 

490 noise_params : Optional[Dict[str, float]] 

491 A dictionary of noise parameters. The following noise gates are 

492 supported: 

493 -BitFlip: Applies a bit flip error to the given wires. 

494 -PhaseFlip: Applies a phase flip error to the given wires. 

495 -Depolarizing: Applies a depolarizing channel error to the 

496 given wires. 

497 

498 All parameters are optional and default to 0.0 if not provided. 

499 """ 

500 qml.CNOT(wires=wires) 

501 UnitaryGates.Noise(wires, noise_params) 

502 

503 @staticmethod 

504 def CY(wires, noise_params=None): 

505 """ 

506 Applies a controlled Y gate to the given wires and adds `Noise` 

507 

508 Parameters 

509 ---------- 

510 wires : Union[int, List[int]] 

511 The wire(s) to apply the controlled Y gate to. 

512 noise_params : Optional[Dict[str, float]] 

513 A dictionary of noise parameters. The following noise gates are 

514 supported: 

515 -BitFlip: Applies a bit flip error to the given wires. 

516 -PhaseFlip: Applies a phase flip error to the given wires. 

517 -Depolarizing: Applies a depolarizing channel error to the 

518 given wires. 

519 

520 All parameters are optional and default to 0.0 if not provided. 

521 """ 

522 qml.CY(wires=wires) 

523 UnitaryGates.Noise(wires, noise_params) 

524 

525 @staticmethod 

526 def CZ(wires, noise_params=None): 

527 """ 

528 Applies a controlled Z gate to the given wires and adds `Noise` 

529 

530 Parameters 

531 ---------- 

532 wires : Union[int, List[int]] 

533 The wire(s) to apply the controlled Z gate to. 

534 noise_params : Optional[Dict[str, float]] 

535 A dictionary of noise parameters. The following noise gates are 

536 supported: 

537 -BitFlip: Applies a bit flip error to the given wires. 

538 -PhaseFlip: Applies a phase flip error to the given wires. 

539 -Depolarizing: Applies a depolarizing channel error to the 

540 given wires. 

541 

542 All parameters are optional and default to 0.0 if not provided. 

543 """ 

544 qml.CZ(wires=wires) 

545 UnitaryGates.Noise(wires, noise_params) 

546 

547 @staticmethod 

548 def H(wires, noise_params=None): 

549 """ 

550 Applies a Hadamard gate to the given wires and adds `Noise` 

551 

552 Parameters 

553 ---------- 

554 wires : Union[int, List[int]] 

555 The wire(s) to apply the Hadamard gate to. 

556 noise_params : Optional[Dict[str, float]] 

557 A dictionary of noise parameters. The following noise gates are 

558 supported: 

559 -BitFlip: Applies a bit flip error to the given wires. 

560 -PhaseFlip: Applies a phase flip error to the given wires. 

561 -Depolarizing: Applies a depolarizing channel error to the 

562 given wires. 

563 

564 All parameters are optional and default to 0.0 if not provided. 

565 """ 

566 qml.Hadamard(wires=wires) 

567 UnitaryGates.Noise(wires, noise_params) 

568 

569 

570class PulseInformation: 

571 """ 

572 Stores pulse parameter counts and optimized pulse parameters for quantum gates. 

573 """ 

574 

575 PULSE_PARAM_COUNTS: Dict[str, int] = {"RX": 3, "RY": 3, "RZ": 1, "CZ": 1, "H": 3} 

576 PULSE_PARAM_COUNTS["Rot"] = 2 * PULSE_PARAM_COUNTS["RZ"] + PULSE_PARAM_COUNTS["RY"] 

577 PULSE_PARAM_COUNTS["CX"] = 2 * PULSE_PARAM_COUNTS["H"] + PULSE_PARAM_COUNTS["CZ"] 

578 PULSE_PARAM_COUNTS["CY"] = 2 * PULSE_PARAM_COUNTS["RZ"] + PULSE_PARAM_COUNTS["CX"] 

579 PULSE_PARAM_COUNTS["CRZ"] = 2 * PULSE_PARAM_COUNTS["RZ"] + PULSE_PARAM_COUNTS["CZ"] 

580 PULSE_PARAM_COUNTS["CRY"] = 2 * PULSE_PARAM_COUNTS["RX"] + PULSE_PARAM_COUNTS["CRZ"] 

581 PULSE_PARAM_COUNTS["CRX"] = 2 * PULSE_PARAM_COUNTS["H"] + PULSE_PARAM_COUNTS["CRZ"] 

582 

583 OPTIMIZED_PULSES: Dict[str, Optional[jnp.ndarray]] = { 

584 "Rot": jnp.array( 

585 [0.5, 7.857992399021039, 21.57270102638842, 0.9000668764608991, 0.5] 

586 ), 

587 "RX": jnp.array([15.70989327341467, 29.5230665326707, 0.7499810441330634]), 

588 "RY": jnp.array([7.8787724942614235, 22.001319411513432, 1.098524473819202]), 

589 "RZ": jnp.array([0.5]), 

590 "CRX": jnp.array( 

591 [ 

592 9.345887537573672, 

593 12.785220434787014, 

594 0.7109351566377278, 

595 0.5, 

596 15.102609209445896, 

597 0.5, 

598 2.9162064326095, 

599 0.019005851299126367, 

600 10.000000000000078, 

601 ] 

602 ), 

603 "CRY": jnp.array( 

604 [ 

605 19.113133239181412, 

606 23.385853735839447, 

607 1.2499994641504941, 

608 0.5, 

609 1.0796514845999126, 

610 0.5, 

611 12.313295392726795, 

612 17.310360723575805, 

613 0.8499715424933506, 

614 ] 

615 ), 

616 "CRZ": jnp.array([0.5, 1.7037270017441872, 0.5]), 

617 "CX": jnp.array( 

618 [ 

619 7.951920934692106, 

620 21.655479574101687, 

621 0.8929524493211076, 

622 0.9548359253748596, 

623 7.94488020182026, 

624 21.61729834699293, 

625 0.9067943033364354, 

626 ] 

627 ), 

628 "CY": jnp.array( 

629 [ 

630 0.5, 

631 13.679990291069169, 

632 6.86497650976022, 

633 1.0547555119435108, 

634 14.96056469588421, 

635 13.040583781891456, 

636 0.33844677502596704, 

637 0.8709563476069772, 

638 0.5, 

639 ] 

640 ), 

641 "CZ": jnp.array([0.962596375687258]), 

642 "H": jnp.array([7.857992398977854, 21.572701026008765, 0.9000668764548863]), 

643 } 

644 

645 @staticmethod 

646 def num_params(gate: str) -> int: 

647 """Return the number of pulse parameters for a given gate.""" 

648 if gate not in PulseInformation.PULSE_PARAM_COUNTS: 

649 raise ValueError(f"Unknown gate '{gate}'") 

650 return PulseInformation.PULSE_PARAM_COUNTS[gate] 

651 

652 @staticmethod 

653 def optimized_params(gate: str) -> Optional[jnp.ndarray]: 

654 """Return the optimized pulse parameters for a given gate.""" 

655 if gate not in PulseInformation.OPTIMIZED_PULSES: 

656 raise ValueError(f"Unknown gate '{gate}'") 

657 return PulseInformation.OPTIMIZED_PULSES[gate] 

658 

659 

660class PulseGates: 

661 # NOTE: Implementation of S, RX, RY, RZ, CZ, CNOT/CX and H pulse level 

662 # gates closely follow https://doi.org/10.5445/IR/1000184129 

663 # TODO: Mention deviations from the above? 

664 omega_q = 10 * jnp.pi 

665 omega_c = 10 * jnp.pi 

666 

667 H_static = jnp.array( 

668 [[jnp.exp(1j * omega_q / 2), 0], [0, jnp.exp(-1j * omega_q / 2)]] 

669 ) 

670 

671 Id = jnp.eye(2, dtype=jnp.complex64) 

672 X = jnp.array([[0, 1], [1, 0]]) 

673 Y = jnp.array([[0, -1j], [1j, 0]]) 

674 Z = jnp.array([[1, 0], [0, -1]]) 

675 

676 @staticmethod 

677 def S(p, t, phi_c): 

678 """ 

679 Generates a shaped pulse envelope modulated by a carrier. 

680 

681 The pulse is a Gaussian envelope multiplied by a cosine carrier, commonly 

682 used in implementing rotation gates (e.g., RX, RY). 

683 

684 Parameters 

685 ---------- 

686 p : sequence of float 

687 Pulse parameters `[A, sigma]`: 

688 - A : float, amplitude of the Gaussian 

689 - sigma : float, width of the Gaussian 

690 t : float or sequence of float 

691 Time or time interval over which the pulse is applied. If a sequence, 

692 `t_c` is taken as the midpoint `(t[0] + t[1]) / 2`. 

693 phi_c : float 

694 Phase of the carrier cosine. 

695 

696 Returns 

697 ------- 

698 jnp.ndarray 

699 The shaped pulse at each time step `t`. 

700 """ 

701 A, sigma = p 

702 t_c = (t[0] + t[1]) / 2 if isinstance(t, (list, tuple)) else t / 2 

703 

704 f = A * jnp.exp(-0.5 * ((t - t_c) / sigma) ** 2) 

705 x = jnp.cos(PulseGates.omega_c * t + phi_c) 

706 

707 return f * x 

708 

709 @staticmethod 

710 def Rot(phi, theta, omega, wires, pulse_params=None): 

711 """ 

712 Applies a general single-qubit rotation using a decomposition. 

713 

714 Decomposition: 

715 Rot(phi, theta, omega) = RZ(phi) · RY(theta) · RZ(omega) 

716 

717 Parameters 

718 ---------- 

719 phi : float 

720 The first rotation angle. 

721 theta : float 

722 The second rotation angle. 

723 omega : float 

724 The third rotation angle. 

725 wires : List[int] 

726 The wire(s) to apply the rotation to. 

727 pulse_params : np.ndarray, optional 

728 Pulse parameters for the composing gates. Defaults 

729 to optimized parameters if None. 

730 """ 

731 n_RZ = PulseInformation.num_params("RZ") 

732 n_RY = PulseInformation.num_params("RY") 

733 

734 idx1 = n_RZ 

735 idx2 = idx1 + n_RY 

736 idx3 = idx2 + n_RZ 

737 

738 if pulse_params is None: 

739 opt = PulseInformation.optimized_params("Rot") 

740 params_RZ_1 = opt[:idx1] 

741 params_RY = opt[idx1:idx2] 

742 params_RZ_2 = opt[idx2:idx3] 

743 else: 

744 params_RZ_1 = pulse_params[:idx1] 

745 params_RY = pulse_params[idx1:idx2] 

746 params_RZ_2 = pulse_params[idx2:idx3] 

747 

748 PulseGates.RZ(phi, wires=wires, pulse_params=params_RZ_1) 

749 PulseGates.RY(theta, wires=wires, pulse_params=params_RY) 

750 PulseGates.RZ(omega, wires=wires, pulse_params=params_RZ_2) 

751 

752 @staticmethod 

753 def RX(w, wires, pulse_params=None): 

754 """ 

755 Applies a rotation around the X axis pulse to the given wires. 

756 

757 Parameters 

758 ---------- 

759 w : float 

760 The rotation angle in radians. 

761 wires : Union[int, List[int]] 

762 The wire(s) to apply the rotation to. 

763 pulse_params : np.ndarray, optional 

764 Array containing pulse parameters `A`, `sigma` and time `t` for the 

765 Gaussian envelope. Defaults to optimized parameters and time. 

766 """ 

767 n_RX = PulseInformation.num_params("RX") 

768 idx = n_RX - 1 

769 if pulse_params is None: 

770 opt = PulseInformation.optimized_params("RX") 

771 pulse_params, t = opt[:idx], opt[idx] 

772 else: 

773 pulse_params, t = pulse_params[:idx], pulse_params[idx] 

774 

775 def Sx(p, t): 

776 return PulseGates.S(p, t, phi_c=jnp.pi) * w 

777 

778 _H = PulseGates.H_static.conj().T @ PulseGates.X @ PulseGates.H_static 

779 _H = qml.Hermitian(_H, wires=wires) 

780 H_eff = Sx * _H 

781 

782 return qml.evolve(H_eff)([pulse_params], t) 

783 

784 @staticmethod 

785 def RY(w, wires, pulse_params=None): 

786 """ 

787 Applies a rotation around the Y axis pulse to the given wires. 

788 

789 Parameters 

790 ---------- 

791 w : float 

792 The rotation angle in radians. 

793 wires : Union[int, List[int]] 

794 The wire(s) to apply the rotation to. 

795 pulse_params : np.ndarray, optional 

796 Array containing pulse parameters `A`, `sigma` and time `t` for the 

797 Gaussian envelope. Defaults to optimized parameters and time. 

798 """ 

799 n_RY = PulseInformation.num_params("RY") 

800 idx = n_RY - 1 

801 if pulse_params is None: 

802 opt = PulseInformation.optimized_params("RY") 

803 pulse_params, t = opt[:idx], opt[idx] 

804 else: 

805 pulse_params, t = pulse_params[:idx], pulse_params[idx] 

806 

807 def Sy(p, t): 

808 return PulseGates.S(p, t, phi_c=-jnp.pi / 2) * w 

809 

810 _H = PulseGates.H_static.conj().T @ PulseGates.Y @ PulseGates.H_static 

811 _H = qml.Hermitian(_H, wires=wires) 

812 H_eff = Sy * _H 

813 

814 return qml.evolve(H_eff)([pulse_params], t) 

815 

816 @staticmethod 

817 def RZ(w, wires, pulse_params=None): 

818 """ 

819 Applies a rotation around the Z axis to the given wires. 

820 

821 Parameters 

822 ---------- 

823 w : float 

824 The rotation angle in radians. 

825 wires : Union[int, List[int]] 

826 The wire(s) to apply the rotation to. 

827 pulse_params : float, optional 

828 Duration of the pulse. Rotation angle = w * 2 * t. 

829 Defaults to 0.5 if None. 

830 """ 

831 idx = PulseInformation.num_params("RZ") - 1 

832 if pulse_params is None: 

833 t = PulseInformation.optimized_params("RZ")[idx] 

834 elif isinstance(pulse_params, (float, int)): 

835 t = pulse_params 

836 else: 

837 t = pulse_params[idx] 

838 

839 _H = qml.Hermitian(PulseGates.Z, wires=wires) 

840 

841 # TODO: Put comment why p, t has no effect here 

842 def Sz(p, t): 

843 return w 

844 

845 H_eff = Sz * _H 

846 

847 return qml.evolve(H_eff)([0], t) 

848 

849 @staticmethod 

850 def CRX(w, wires, pulse_params=None): 

851 """ 

852 Applies a controlled-RX(w) gate using a decomposition. 

853 

854 Decomposition: 

855 CRX(w) = H_t · CRZ(w) · H_t 

856 

857 Parameters 

858 ---------- 

859 w : float 

860 Rotation angle. 

861 wires : List[int] 

862 The control and target wires. 

863 pulse_params : np.ndarray 

864 Pulse parameters for the composing gates. Defaults 

865 to optimized parameters if None. 

866 """ 

867 n_H = PulseInformation.num_params("H") 

868 n_CRZ = PulseInformation.num_params("CRZ") 

869 

870 idx1 = n_H 

871 idx2 = idx1 + n_CRZ 

872 idx3 = idx2 + n_H 

873 

874 if pulse_params is None: 

875 opt = PulseInformation.optimized_params("CRX") 

876 params_H_1 = opt[:idx1] 

877 params_CRZ = opt[idx1:idx2] 

878 params_H_2 = opt[idx2:idx3] 

879 else: 

880 params_H_1 = pulse_params[:idx1] 

881 params_CRZ = pulse_params[idx1:idx2] 

882 params_H_2 = pulse_params[idx2:idx3] 

883 

884 target = wires[1] 

885 

886 PulseGates.H(wires=target, pulse_params=params_H_1) 

887 PulseGates.CRZ(w, wires, pulse_params=params_CRZ) 

888 PulseGates.H(wires=target, pulse_params=params_H_2) 

889 

890 return 

891 

892 @staticmethod 

893 def CRY(w, wires, pulse_params=None): 

894 """ 

895 Applies a controlled-RY(w) gate using a decomposition. 

896 

897 Decomposition: 

898 CRY(w) = RX(-π/2)_t · CRZ(w) · RX(π/2)_t 

899 

900 Parameters 

901 ---------- 

902 w : float 

903 Rotation angle. 

904 wires : List[int] 

905 The control and target wires. 

906 pulse_params : np.ndarray 

907 Pulse parameters for the composing gates. Defaults 

908 to optimized parameters if None. 

909 """ 

910 n_RX = PulseInformation.num_params("RX") 

911 n_CRZ = PulseInformation.num_params("CRZ") 

912 

913 idx1 = n_RX 

914 idx2 = idx1 + n_CRZ 

915 idx3 = idx2 + n_RX 

916 

917 if pulse_params is None: 

918 opt = PulseInformation.optimized_params("CRY") 

919 params_RX_1 = opt[:idx1] 

920 params_CRZ = opt[idx1:idx2] 

921 params_RX_2 = opt[idx2:idx3] 

922 else: 

923 params_RX_1 = pulse_params[:idx1] 

924 params_CRZ = pulse_params[idx1:idx2] 

925 params_RX_2 = pulse_params[idx2:idx3] 

926 

927 target = wires[1] 

928 

929 PulseGates.RX(-np.pi / 2, wires=target, pulse_params=params_RX_1) 

930 PulseGates.CRZ(w, wires=wires, pulse_params=params_CRZ) 

931 PulseGates.RX(np.pi / 2, wires=target, pulse_params=params_RX_2) 

932 

933 return 

934 

935 @staticmethod 

936 def CRZ(w, wires, pulse_params=None):