Abstract: An encryption protocol is provided that can be implemented within a single clock cycle of an integrated circuit chip while still providing unbreakable encryption. The protocol of the present invention is so small that it can co-exist on any integrated circuit chip with other functions, including a general purpose central processing unit, general processing unit, or application specific integrated circuits with other communication related functionality.

Abstract: An anonymous authentication service for an invulnerable secret key authentication and encryption token distribution service. Applications place a small code segment within their communications protocol, thereby allowing network participants the full benefit of perfectly secure authenticated and encrypted message traffic without concern for third party key management. This is the world's first participant-managed, independent-trust secure messaging key distribution capability.

Abstract: An encryption protocol is provided that can be implemented within a single clock cycle of an integrated circuit chip while still providing unbreakable encryption. The protocol of the present invention is so small that it can co-exist on any integrated circuit chip with other functions, including a general purpose central processing unit, general processing unit, or application specific integrated circuits with other communication related functionality.

Abstract: An authentication and encryption protocol is provided that can be implemented within a single clock cycle of an integrated circuit chip while still providing unbreakable encryption. The protocol of the present invention is so small that it can co-exist on any integrated circuit chip with other functions, including a general purpose central processing unit, general processing unit, or application specific integrated circuits with other communication related functionality.

Abstract: An authentication and encryption protocol is provided that can be implemented within a single clock cycle of an integrated circuit chip while still providing unbreakable encryption. The protocol of the present invention is so small that it can co-exist on any integrated circuit chip with other functions, including a general purpose central processing unit, general processing unit, or application specific integrated circuits with other communication related functionality.

Abstract: In a plasma compression fusion device, two electrical grids used to ionize the Deuterium gas (or other fusion fuel in gaseous form). The two grids are kept at different oppositely charged voltages so as to electrostatically accelerate either electrons or ions into the plasma core, depending on desired physical effect. Each of the grids are driven by an electrical signal—one positive and one negative. The two signals are controlled by a spread spectrum modulator that outputs the desired electrical signal, which is modulated by the spread spectrum modulator under the control of a pseudo random (PN) sequence. To achieve the desired electrical effect, the two signals must be matched exactly in phase and amplitude. One signal, e.g., the positive signal, is controlled by a PN sequence from outside the device, whereas the opposite signal is controlled by a PN sequence built into the device.

Abstract: An authentication and encryption protocol is provided that can be implemented within a single clock cycle of an integrated circuit chip while still providing unbreakable encryption. The protocol of the present invention is so small that it can co-exist on any integrated circuit chip with other functions, including a general purpose central processing unit, general processing unit, or application specific integrated circuits with other communication related functionality.

Abstract: An anonymous authentication service for an invulnerable secret key authentication and encryption token distribution service. Applications place a small code segment within their communications protocol, thereby allowing network participants the full benefit of perfectly secure authenticated and encrypted message traffic without concern for third party key management. This is the world's first participant-managed, independent-trust secure messaging key distribution capability.

Abstract: An authentication and encryption protocol is provided that can be implemented within a single clock cycle of an integrated circuit chip while still providing unbreakable encryption. The protocol of the present invention is so small that it can co-exist on any integrated circuit chip with other functions, including a general purpose central processing unit, general processing unit, or application specific integrated circuits with other communication related functionality.

Abstract: Qwyit® Authentication and Encryption Service serves as a direct replacement of Transport Layer Security. Applications can place a small code segment within their communications protocol, resulting in authenticated and encrypted message traffic with the features of TLS while adding additional improvements as set forth herein. QAES provides a direct next generation replication and enhancement of the current, only global secure communications framework. QAES provides the same features, benefits, authentication (embedded) and data security (stream cipher) for communications traffic using the Qwyit® Directory Service key store. The combination of features and properties provide a simple, straightforward way for any application to incorporate secure communications. The unique, superior Qwyit® protocol delivers where TLS fails: embedded security without any need for additional bandwidth, processing power or cumbersome user requirements.

Abstract: Qwyit® Authentication and Encryption Service serves as a direct replacement of Transport Layer Security. Applications can place a small code segment within their communications protocol, resulting in authenticated and encrypted message traffic with the features of TLS while adding additional improvements as set forth herein. QAES provides a direct next generation replication and enhancement of the current, only global secure communications framework. QAES provides the same features, benefits, authentication (embedded) and data security (stream cipher) for communications traffic using the Qwyit® Directory Service key store. The combination of features and properties provide a simple, straightforward way for any application to incorporate secure communications. The unique, superior Qwyit® protocol delivers where TLS fails: embedded security without any need for additional bandwidth, processing power or cumbersome user requirements.

Abstract: Qwyit® Authentication and Encryption Service serves as a direct replacement of Transport Layer Security. Applications can place a small code segment within their communications protocol, resulting in authenticated and encrypted message traffic with the features of TLS while adding additional improvements as set forth herein. QAES provides a direct next generation replication and enhancement of the current, only global secure communications framework. QAES provides the same features, benefits, authentication (embedded) and data security (stream cipher) for communications traffic using the Qwyit® Directory Service key store. The combination of features and properties provide a simple, straightforward way for any application to incorporate secure communications. The unique, superior Qwyit® protocol delivers where TLS fails: embedded security without any need for additional bandwidth, processing power or cumbersome user requirements.

Abstract: A method and apparatus for a streamlined electronic credit transaction that provides more security in a streamlined transaction process than any current deferred net settlement system. The removal of the physical credit card restores the proper risk balance to all participants and performs processing in real time, faster than any current system. The method relies on secure authentication and encryption security communications, based on the provably secure unbreakable mathematics of underdetermined systems of equations, which are maintained everywhere throughout the transaction process.

Abstract: A method for obtaining an encryption/authentication key uses multiple return channels over which to send parts of the key, which parts are then combined to form the actual key. A method includes receiving an open request for a first key which is a trusted key wrapped in a public key. The open request includes an authentication request value that identifies the open request as a verified setup directory service, the public key, an email address and a specified out-of-band channel. The server sends a first reply sent directly back with a first half of the first key offset by a unique value and wrapped using the public key. The second reply is sent via email which includes a second half of the first key offset by the first half of the first key. The third reply is sent over the out-of-band channel, which includes the unique value.