The Transactional Interpretation of Quantum Mechanics http://www
... wave function passes through two slits, producing interference. The observer can choose to either: (a) measure the interference pattern (wavelength) at E or (b) measure the slit position with telescopes T1 and T2. He decides which to do after the photon has passed the slits. ...
... wave function passes through two slits, producing interference. The observer can choose to either: (a) measure the interference pattern (wavelength) at E or (b) measure the slit position with telescopes T1 and T2. He decides which to do after the photon has passed the slits. ...
Probabilistic instantaneous quantum computation
... qubits 1 and 2. In (1/4) n cases the whole state of qubits 3 is projected onto the state resulting from the correct input and she does not have to perform any additional transformation on qubits 3. In the remaining 1⫺(1/4) n cases, the result of the engineer’s Bell-state analysis will not be the rig ...
... qubits 1 and 2. In (1/4) n cases the whole state of qubits 3 is projected onto the state resulting from the correct input and she does not have to perform any additional transformation on qubits 3. In the remaining 1⫺(1/4) n cases, the result of the engineer’s Bell-state analysis will not be the rig ...
Liquid State NMR Quantum Computing
... We start from a familiar place for many NMR spectroscopists, the INEPT pulse sequence (see INEPT, Volume 4). This sequence was designed to transfer polarization from a high γ nucleus to a low γ nucleus. However, it can also be viewed as a logic gate (Figure 1) which flips one spin conditioned upon t ...
... We start from a familiar place for many NMR spectroscopists, the INEPT pulse sequence (see INEPT, Volume 4). This sequence was designed to transfer polarization from a high γ nucleus to a low γ nucleus. However, it can also be viewed as a logic gate (Figure 1) which flips one spin conditioned upon t ...
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... each may be given to arbitrary precision. These numbers can encode a long string of bits. For example, 011101101... could be encoded as a state with latitude 01 degrees, 11 minutes and 01.101... seconds. This reasoning, though plausible, is incorrect. One can encode an infinite amount of classical i ...
... each may be given to arbitrary precision. These numbers can encode a long string of bits. For example, 011101101... could be encoded as a state with latitude 01 degrees, 11 minutes and 01.101... seconds. This reasoning, though plausible, is incorrect. One can encode an infinite amount of classical i ...
Two types of potential functions and their use in the
... Real and Quantum Potentials can be used in Lux’s Noise Trader Infection Model The “noise trader/infection” model was developed by Lux (1997) and we use it here to highlight the applications we can make, in a financial economics framework, of the potentials we have treated in our paper. From Equation ...
... Real and Quantum Potentials can be used in Lux’s Noise Trader Infection Model The “noise trader/infection” model was developed by Lux (1997) and we use it here to highlight the applications we can make, in a financial economics framework, of the potentials we have treated in our paper. From Equation ...
Chapter 2. Mind and the Quantum
... slit. Furthermore, this determination destroys the interference pattern and results in a distribution equal to the sum of the distributions from each slit. Thus, although an electron is always detected as a point-like entity, it appears to manifest itself as a nonlocalized wave function under circum ...
... slit. Furthermore, this determination destroys the interference pattern and results in a distribution equal to the sum of the distributions from each slit. Thus, although an electron is always detected as a point-like entity, it appears to manifest itself as a nonlocalized wave function under circum ...
