Abstract: A system and method for creating a trusted workspace on a commercial mobile device using a cryptographic security token having a secure microprocessor, a secure bus connected to said secure microprocessor, a bus isolation microcontroller connected to said secure bus wherein said bus isolation microcontroller comprises firmware for controlling communications through said secure bus to said secure microprocessor, a first NFC antenna connected to said bus isolation microcontroller, and a second NFC antenna connected to said secure microprocessor. The secure microprocessor and said bus isolation microprocessor are powered by energy received through said first NFC antenna and said second NFC antenna. The cryptographic security token receives data from outside said cryptographic security token only through said first NFC antenna. The token or module may further have a bi-state or bi-stable display and a secure memory, each connected to the secure microprocessor by a secure bus.

Abstract: A cryptographic security token having a secure microprocessor, a secure bus connected to said secure microprocessor, a bus isolation microcontroller connected to said secure bus wherein said bus isolation microcontroller comprises firmware for controlling communications through said secure bus to said secure microprocessor, a first NFC antenna connected to said bus isolation microcontroller, and a second NFC antenna connected to said secure microprocessor. The secure microprocessor and said bus isolation microprocessor are powered by energy received through said first NFC antenna and said second NFC antenna. The cryptographic security token receives data from outside said cryptographic security token only through said first NFC antenna. The token or module may further have a bi-state or bi-stable display and a secure memory, each connected to the secure microprocessor by a secure bus.

Abstract: A cryptographic security token having a secure microprocessor, a secure bus connected to said secure microprocessor, a bus isolation microcontroller connected to said secure bus wherein said bus isolation microcontroller comprises firmware for controlling communications through said secure bus to said secure microprocessor, a first NFC antenna connected to said bus isolation microcontroller, and a second NFC antenna connected to said secure microprocessor. The secure microprocessor and said bus isolation microprocessor are powered by energy received through said first NFC antenna and said second NFC antenna. The cryptographic security token receives data from outside said cryptographic security token only through said first NFC antenna. The token or module may further have a bi-state or bi-stable display and a secure memory, each connected to the secure microprocessor by a secure bus.

Abstract: A cryptographic security token having a secure microprocessor, a secure bus connected to said secure microprocessor, a bus isolation microcontroller connected to said secure bus wherein said bus isolation microcontroller comprises firmware for controlling communications through said secure bus to said secure microprocessor, a first NFC antenna connected to said bus isolation microcontroller, and a second NFC antenna connected to said secure microprocessor. The secure microprocessor and said bus isolation microprocessor are powered by energy received through said first NFC antenna and said second NFC antenna. The cryptographic security token receives data from outside said cryptographic security token only through said first NFC antenna. The token or module may further have a bi-state or bi-stable display and a secure memory, each connected to the secure microprocessor by a secure bus.

Abstract: A cryptographic security token having a secure microprocessor, a secure bus connected to said secure microprocessor, a bus isolation microcontroller connected to said secure bus wherein said bus isolation microcontroller comprises firmware for controlling communications through said secure bus to said secure microprocessor, a first NFC antenna connected to said bus isolation microcontroller, and a second NFC antenna connected to said secure microprocessor. The secure microprocessor and said bus isolation microprocessor are powered by energy received through said first NFC antenna and said second NFC antenna. The cryptographic security token receives data from outside said cryptographic security token only through said first NFC antenna. The token or module may further have a bi-state or bi-stable display and a secure memory, each connected to the secure microprocessor by a secure bus.

Abstract: A system and method for creating a trusted workspace on a commercial mobile device using a cryptographic security token having a secure microprocessor, a secure bus connected to said secure microprocessor, a bus isolation microcontroller connected to said secure bus wherein said bus isolation microcontroller comprises firmware for controlling communications through said secure bus to said secure microprocessor, a first NFC antenna connected to said bus isolation microcontroller, and a second NFC antenna connected to said secure microprocessor. The secure microprocessor and said bus isolation microprocessor are powered by energy received through said first NFC antenna and said second NFC antenna. The cryptographic security token receives data from outside said cryptographic security token only through said first NFC antenna. The token or module may further have a bi-state or bi-stable display and a secure memory, each connected to the secure microprocessor by a secure bus.

Abstract: A system and method for secure peer-to-peer mobile communications using cryptographic mobile unlock tokens (“CK tokens”) in conjunction with mobile devices. Each CK token integrates an entire cryptosystem. Executing these cryptographic based functions entirely in the token have significant operational advantages over the typically memory-only tokens. A more secure, scalable, and lower overall system cost are just a few advantages of the CK token over executing these functions within the smartphone. Of the many uses discussed for the CK token, mobile phone enabling, stored value and medical applications, most have centered on the use of the card in conjunction with a smartphone as the touch point in the transaction.

Abstract: A system and method for secure peer-to-peer mobile communications using cryptographic mobile unlock tokens (“CK tokens”) in conjunction with mobile devices. Each CK token integrates an entire cryptosystem. Executing these cryptographic based functions entirely in the token have significant operational advantages over the typically memory-only tokens. A more secure, scalable, and lower overall system cost are just a few advantages of the CK token over executing these functions within the smartphone. Of the many uses discussed for the CK token, mobile phone enabling, stored value and medical applications, most have centered on the use of the card in conjunction with a smartphone as the touch point in the transaction.

Abstract: A self-boarding pass having a batteryless thin flexible display inlay and a housing encapsulating the batteryless thin flexible display inlay. The batteryless thin flexible display inlay has a bi-state display, display control circuitry, a secure processor and an antenna. The housing has a composite layer having front and back faces and a window aligned with the display in the batteryless thin flexible display inlay, printing on the front face of the composite later and a transparent polyester plastic layer encapsulating the composite layer, the printing and the window.

Abstract: A method for storing medical data on a secure ID card and retrieving the medical data from the card using an authentication device. The method comprises the steps of verifying the card and the authentication device, unlocking in the card a user password template stored in the card in response to verification of the card and authentication device, inputting a password, transmitting the password to the card, comparing the inputted password to the unlocked password template, unlocking a biometric template stored in the card in response to a positive comparison, capturing biometric data a person with the biometric sensor, generating in the authentication device a biometric template through processing of the captured biometric data, transmitting the template to the card, comparing the biometric template to the unlocked template, generating a decryption key, and using the decryption key to unlock a medical application on the authentication device.

Abstract: A self-boarding pass having a batteryless thin flexible display inlay and a housing encapsulating the batteryless thin flexible display inlay. The batteryless thin flexible display inlay has a bi-state display, display control circuitry, a secure processor and an antenna. The housing has a composite layer having front and back faces and a window aligned with the display in the batteryless thin flexible display inlay, printing on the front face of the composite later and a transparent polyester plastic layer encapsulating the composite layer, the printing and the window.

Abstract: A secure identification card having a batteryless thin flexible display inlay and a housing encapsulating the batteryless thin flexible display inlay. The batteryless thin flexible display inlay has a bi-state display, display control circuitry, a secure processor and an antenna. The housing has a composite layer having front and back faces and a window aligned with the display in the batteryless thin flexible display inlay, printing on the front face of the composite later and a transparent polyester plastic layer encapsulating the composite layer, the printing and the window.