Quantum Communication Research at Harish-Chandra Institute, India

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Explore the world of quantum communication through the research work of Aditi Sen at the Harish-Chandra Research Institute in India. The research covers topics like secure communication, quantum cryptography, classical information transmission, and more.

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  1. QUANTUM COMMUNICATION Aditi Sen(De) Harish-Chandra Research Institute, India

  2. OUTLINE Communication Communication Secure Communication Quantum Cryptography

  3. OUTLINE Classical info transmission Communication Without security Quantum state transmission Communication Secure Communication Quantum Cryptography

  4. OUTLINE Classical info transmission Communication Without security Quantum state transmission Communication Secure Communication Quantum Cryptography

  5. OUTLINE Classical info transmission Communication Without security Quantum state transmission Communication Secure Communication Quantum Cryptography

  6. COMMUNICATION

  7. COMMUNICATION

  8. WHATIS COMMUNICATION? At least 2 parties Sender Receiver Bob Alice Communication is a process by which information is sent by a sender to a receiver via some medium.

  9. WHATIS COMMUNICATION? At least 2 parties Sender Receiver Bob Alice Communication is a process by which information is sent by a sender to a receiver via some medium.

  10. WHATIS COMMUNICATION? At least 2 parties Sender Receiver Bob Alice Communication is a process by which information is sent by a sender to a receiver via some medium.

  11. WHATIS COMMUNICATION? At least 2 parties Sender Receiver Bob Alice Communication is a process by which information is sent by a sender to a receiver via some medium.

  12. WHATIS COMMUNICATION? At least 2 parties Sender Receiver Bob Alice a process by which information is sent by a sender to a receiver via some medium.

  13. WHATIS COMMUNICATION? encodes Alice (Encoder) Sends Bob (Decoder) receives & decodes

  14. WHATIS COMMUNICATION? Information is physical ---Landauer information must be encoded in, and decoded from a physical system. Classical World encoding/Decoding red-green balls, sign of charge of a particle. Only orthogonal states Quantum World: Nonorthogonal states

  15. WHATIS COMMUNICATION? Information is physical ---Landauer information must be encoded in, and decoded from a physical system. Classical World encoding/Decoding red-green balls, sign of charge of a particle. Only orthogonal states Quantum World: Nonorthogonal states

  16. WHATIS COMMUNICATION? Information is physical ---Landauer information must be encoded in, and decoded from a physical system. Classical World encoding/decoding red-green balls, sign of charge of a particle. Only orthogonal states Quantum World: Nonorthogonal states

  17. WHATIS COMMUNICATION? Information is physical ---Landauer information must be encoded in, and decoded from a physical system. Classical World encoding/decoding red-green balls, sign of charge of a particle. Only orthogonal states Quantum World: Nonorthogonal states

  18. WHATIS COMMUNICATION? Information is physical ---Landauer information must be encoded in, and decoded from a physical system. Classical World encoding/decoding red-green balls, sign of charge of a particle. Do quantum states advantageous? Only orthogonal states Quantum World: Nonorthogonal states

  19. Classical Information Transmission via Quantum States Part 1

  20. Quantum Dense Coding Bennett & Wiesner, PRL 1992

  21. CLASSICAL PROTOCOL Sunny Windy Snowing Raining

  22. CLASSICAL PROTOCOL Sunny Windy Snowing Raining

  23. CLASSICAL PROTOCOL Sunny Windy

  24. CLASSICAL PROTOCOL Sunny Windy Snowing Raining

  25. CLASSICAL PROTOCOL Sunny Windy Snowing Raining

  26. CLASSICAL PROTOCOL Sunny 2 bits Windy Snowing Raining

  27. CLASSICAL PROTOCOL Sunny 2 bits Windy Classical computer unit: Snowing Bit = one of {0, 1} Raining

  28. CLASSICAL PROTOCOL Alice Bob Message Encoding Decoding Sunny 00 Snowing Distinguishable by color 01 Windy 10 Raining 11

  29. CLASSICAL PROTOCOL Alice Bob Message Encoding Decoding Sunny Snowing 2 bits 4 dimension Distinguishable by color Windy Raining

  30. What abt Quantum?

  31. QUANTUM PROTOCOL Alice Bob Message Sunny B A Snowing Windy Singlet state Raining

  32. Bob B Alice A U Message Alice performs unitary on her particle I Sunny Snowing Windy Raining

  33. Bob B Alice A U Message Alice performs unitary on her particle I Sunny Snowing Creates 4 orthogonal states Singlet, Triplets Windy Raining

  34. Bob B Alice A U Message I Sunny Alice sends her particle to Bob Snowing Windy Raining

  35. Bob Alice B A Message I Sunny Bob has 2 particles: one of the triplets or singlet Snowing Windy Raining

  36. B A Alice Bob Decoding Message I Sunny Snowing 4 orthogonal states Possible to distinguish Windy Raining

  37. B A Alice Bob Decoding Message I Sunny Snowing 4 orthogonal states Possible to distinguish Windy Decodes message Raining

  38. B A Alice Bob Decoding Message I Sunny Snowing 2 bits 2 dimension 4 orthogonal states Possible to distinguish Windy Raining

  39. MORAL Classical Quantum Vs. Task: sending 2 bits Encoding: 2 Dimensions Encoding: 4 Dimensions

  40. MORAL Classical Quantum Vs. Task: sending 2 bits Encoding: 2 Dimensions Encoding: 4 Dimensions Bennett & Weisner, PRL 69, 2881 ( 92).

  41. DENSE CODING FORARBITRARYSTATE Hiroshima, J. Phys. A 01; Ziman & Buzek, PRA 03, Bruss, D Ariano, Lewenstein, Macchiavello, ASD, Sen, PRL 04

  42. B A Alice & Bob share a state

  43. Encoding B A Alice s aim: to send classical info i

  44. Encoding B A Alice s aim: to send classical info i which occurs with probability pi

  45. Encoding Ui A B Alice performs pi , Ui

  46. Encoding Ui A B Alice performs pi , Ui she produces the ensemble E E = {pi, i}

  47. Encoding Ui A B Alice performs pi , Ui she produces the ensemble E E = {pi, i}

  48. Sending Ui A B Alice performs pi , Ui she produces the ensemble E E = {pi, i} Alice sends her particle to Bob

  49. Decoding A B Bob Alice

  50. Decoding A B Bob s task: Gather info abt i Alice

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