Abstract: Spatially Enabled Communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. A data block can be securely communicated by interspersing the data between an short range communication (SRC) device for near field magnetic induction (NFMI) communication within the proximity boundary and a radio frequency (RF) radio for RF communication. Data received on the SRC device and the RF radio can be reassembled to form the data block.

Abstract: Spatially enabled secure communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. Secure data can be selected for NFMI communication on a spatially secure NFMI data link between the one or more SRC devices. Non-secure data can be selected for communication on one of a wireless local area network or a wireless wide area network.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device, wherein at least one of the first and second SRC devices includes at least two antennas to provide magnetic induction diversity. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device and the second SRC device using NFMI when the proximity signal is detected between the first SRC device and the second SRC device.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device in the proximity boundary when the proximity signal is detected between the first SRC device and the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard.

Abstract: Spatially Enabled Communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. A data block can be securely communicated by interspersing the data between an short range communication (SRC) device for near field magnetic induction (NFMI) communication within the proximity boundary and a radio frequency (RF) radio for RF communication. Data received on the SRC device and the RF radio can be reassembled to form the data block.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device, wherein at least one of the first and second SRC devices includes at least two antennas to provide magnetic induction diversity. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device and the second SRC device using NFMI when the proximity signal is detected between the first SRC device and the second SRC device.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device, wherein at least one of the first and second SRC devices includes at least two antennas to provide magnetic induction diversity. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device and the second SRC device using NFMI when the proximity signal is detected between the first SRC device and the second SRC device.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device in the proximity boundary when the proximity signal is detected between the first SRC device and the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard. An RF link can be established between the first SRC device and the second SRC device to enable selected data communications to continue between the first SRC device and the second SRC device even after one or more of the first SRC device or the second SRC device exits the proximity boundary.

Abstract: Spatially enabled secure communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. Secure data can be selected for NFMI communication on a spatially secure NFMI data link between the one or more SRC devices. Non-secure data can be selected for communication on one of a wireless local area network or a wireless wide area network.

Abstract: Spatially Enabled Communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. A data block can be securely communicated by interspersing the data between an short range communication (SRC) device for near field magnetic induction (NFMI) communication within the proximity boundary and a radio frequency (RF) radio for RF communication. Data received on the SRC device and the RF radio can be reassembled to form the data block.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard. An RF link can be established between the first SRC device and the second SRC device to enable selected data communications to continue between the first SRC device and the second SRC device even after one or more of the first SRC device or the second SRC device exits the proximity boundary.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device in the proximity boundary when the proximity signal is detected between the first SRC device and the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard.

Abstract: Technology for a spatially aware wireless network is disclosed. One embodiment comprises a plurality of near field magnetic induction nodes. One or more nodes is configured to communicate a polarized spatial position signal using near field magnetic induction (NFMI) to determine one or more of a position and an orientation of one or more nodes in the spatially aware wireless network. A detection module is operable to configure the spatially aware wireless network based one or more of a position and an orientation of one or more nodes in the plurality of nodes.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device in the proximity boundary when the proximity signal is detected between the first SRC device and the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard.

Abstract: Spatially enabled secure communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. Secure data can be selected for NFMI communication on a spatially secure NFMI data link between the one or more SRC devices. Non-secure data can be selected for communication on one of a wireless local area network or a wireless wide area network.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. The first SRC device and the second SRC device can be configured to communicate using near field magnetic induction (NFMI). A proximity signal can be communicated in the proximity boundary between the first SRC device and the second SRC device, wherein at least one of the first and second SRC devices includes at least two antennas to provide magnetic induction diversity. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device and the second SRC device using NFMI when the proximity signal is detected between the first SRC device and the second SRC device.

Abstract: Technology is described for proximity based communications. A proximity boundary can be defined with dimensions defined, in part, by a communication range of one of a first Short Range Communication (SRC) device and a second SRC device. A security permission can be provided to enable selected data to be communicated from one or more of the first SRC device or the second SRC device. The selected data can be communicated from one or more of the first SRC device or the second SRC device using a radio frequency (RF) communication standard. An RF link can be established between the first SRC device and the second SRC device to enable selected data communications to continue between the first SRC device and the second SRC device even after one or more of the first SRC device or the second SRC device exits the proximity boundary.

Abstract: Spatially Enabled Communication technologies are disclosed. A proximity boundary can be defined by a communication range of one or more SRC devices configured to communicate using near field magnetic induction (NFMI) using at least two antennas to provide magnetic induction diversity. A data block can be securely communicated by interspersing the data between an short range communication (SRC) device for near field magnetic induction (NFMI) communication within the proximity boundary and a radio frequency (RF) radio for RF communication. Data received on the SRC device and the RF radio can be reassembled to form the data block.

Abstract: Mutant ras oncogene peptides may induce specific anti-ras cellular immune responses in vaccinated patients. Moreover, a human CD8+ CTL epitope(s) reflecting a specific point mutation in the K-ras oncogene at codon 12 was identified. The mutant ras peptide has implications for both active and passive immunotherapies in selected carcinoma patients. A nested 10-mer peptide was identified [i.e., ras5-14(Asp12)], which was shown to bind to HLA-A2 and display specific functional capacity for expansion of the in vivo-primed CD8+ CTL precursors.