Abstract: Protecting the security of an entity by using passcodes is disclosed. A passcode device generates a passcode. In an embodiment, the passcode is generated in response to receipt of user information. The passcode is received by another system, which authenticates the passcode by at least generating a passcode from a passcode generator, and comparing the generated passcode with the received passcode. The passcode is temporary. At a later use a different passcode is generated from a different passcode generator.

Abstract: In an embodiment, a secure module is provided that provides access keys to an unsecured system. In an embodiment, the secure module may generate passcodes and supply the passcodes to the unsecured system. In an embodiment, the access keys are sent to the unsecured system after the receiving the passcode from the unsecured system. In an embodiment, after authenticating the passcode, the secure module does not store the passcode in its memory. In an embodiment, the unsecured module requires the access key to execute a set of instructions or another entity. In an embodiment, the unsecured system does not store access keys. In an embodiment, the unsecured system erases the acccess key once the unsecured system no longer requires the access key. In an embodiment, the unsecured system receives a new passcode to replace the stored passcode after using the stored passcode. Each of these embodiments may be used separately.

Abstract: In an embodiment, a secure module is provided that provides access keys to an unsecured system. In an embodiment, the secure module may generate passcodes and supply the passcodes to the unsecured system. In an embodiment, the access keys are sent to the unsecured system after the receiving the passcode from the unsecured system. In an embodiment, after authenticating the passcode, the secure module does not store the passcode in its memory. In an embodiment, the unsecured module requires the access key to execute a set of instructions or another entity. In an embodiment, the unsecured system does not store access keys. In an embodiment, the unsecured system erases the acccess key once the unsecured system no longer requires the access key. In an embodiment, the unsecured system receives a new passcode to replace the stored passcode after using the stored passcode. Each of these embodiments may be used separately.

Abstract: In an embodiment, a secure module is provided that provides access keys to an unsecured system. In an embodiment, the secure module may generate passcodes and supply the passcodes to the unsecured system. In an embodiment, the access keys are sent to the unsecured system after the receiving the passcode from the unsecured system. In an embodiment, after authenticating the passcode, the secure module does not store the passcode in its memory. In an embodiment, the unsecured module requires the access key to execute a set of instructions or another entity. In an embodiment, the unsecured system does not store access keys. In an embodiment, the unsecured system erases the acccess key once the unsecured system no longer requires the access key. In an embodiment, the unsecured system receives a new passcode to replace the stored passcode after using the stored passcode. Each of these embodiments may be used separately.

Abstract: The present invention discloses the existence of two novel proteins UspA1 and UspA2, and their respective genes uspA1 and uspA2. Each protein encompasses a region that is conserved between the two proteins and comprises an epitope that is recognized by the MAb 17C7. One or more than one of these species may aggregate to form the very high molecular weight form (i.e. greater than 200 kDa) of the UspA antigen. Compositions and both diagnostic and therapeutic methods for the treatment and study of M. catarrhalis are disclosed.

Abstract: The present invention discloses the existence of two novel proteins UspA1 and UspA2, and their respective genes uspA1 and uspA2. Each protein encompasses a region that is conserved between the two proteins and comprises an epitope that is recognized by the MAb 17C7. One or more than one of these species may aggregate to form the very high molecular weight form (ie. greater than 200 kDa) of the UspA antigen. Compositions and both diagnostic and therapeutic methods for the treatment and study of M catarrhalis are disclosed.

Abstract: NADO is a process for encrypting and decrypting information in a variety of cryptographic devices. The underlying process is a fast stream-like cipher that can be implemented efficiently in analog or digital hardware or in software. The NADO process makes use of three novel methods in cryptography: 1) A sequence of permutations which scrambles and spreads out the encrypted information; (2) A state generator built with a non-autonomous dynamical system to generate an unpredictable sequence of states; (3) One or more perturbators which perturb both the non-autonomous dynamical system and the sequence of permutations in a non-periodic way.