| 2008 |
|---|
| 12 | EE | John Robert Burger:
Explaining the Logical Nature of Electrical Solitons in Neural Circuits
CoRR abs/0804.4237: (2008) |
| 11 | EE | John Robert Burger:
Cognitive Architecture for Direction of Attention Founded on Subliminal Memory Searches, Pseudorandom and Nonstop
CoRR abs/0805.3126: (2008) |
| 2006 |
|---|
| 10 | EE | John Robert Burger:
Associative Memory For Reversible Programming and Charge Recovery
CoRR abs/cs/0602078: (2006) |
| 2005 |
|---|
| 9 | EE | John Robert Burger:
Quantum Algorithm Processor For Finding Exact Divisors
CoRR abs/cs/0508038: (2005) |
| 8 | EE | John Robert Burger:
Quantum Algorithm Processors to Reveal Hamiltonian Cycles
CoRR abs/cs/0508116: (2005) |
| 7 | EE | John Robert Burger:
Reversible CAM Processor Modeled After Quantum Computer Behavior
CoRR abs/cs/0512104: (2005) |
| 2004 |
|---|
| 6 | | John Robert Burger:
Novel Quantum Computer Emulator Chip.
ESA/VLSI 2004: 309-315 |
| 5 | EE | John Robert Burger:
Data-stationary Architecture to Execute Quantum Algorithms Classically
CoRR abs/cs/0412040: (2004) |
| 2003 |
|---|
| 4 | EE | John Robert Burger:
Symmetric and Antisymmeteric Functions, a New Way to Test a Quantum Computer
CoRR cs.CE/0304016: (2003) |
| 3 | EE | John Robert Burger:
Note on Needle in a Haystack
CoRR cs.CE/0308043: (2003) |
| 2 | EE | John Robert Burger:
New Approachs to Quantum Computer Simulaton in a Classical Supercomputer
CoRR quant-ph/0308158: (2003) |
| 1983 |
|---|
| 1 | | John Robert Burger:
Data-Stationary Instructions as a Way to Minimize Long Distance Communications in VLSI.
ICPP 1983: 547-553 |
