Abstract: A wireless server-to-server datacenter network architecture uses wireless links to eliminate the need for power-hungry switching fabric of traditional fat-tree based datacenter networks. The server-to-server wireless datacenter network (S2S-WiDCN) requires Line-of-Sight (LoS) between servers to establish direct communication links. Utilizing this LoS links, a horizontal-first routing algorithm is developed which, will establish fast communication links between any pair of communicating servers in the data center. The wireless links can be realized in millimeter-wave (such as 30, 60, 120 GHz) or THz (such as 300 GHz) frequency bands. The use of antenna-arrays to create beam-steering towards communicating servers is necessary to establish the direct server-to-server links. In the presence of an obstruction such as an IT technician, the LoS between communicating servers may be blocked. To address this issue, an obstruction-aware adaptive routing algorithm for the S2S-WiDCN is proposed.

Abstract: A wireless communication system and method for allowing two or more wireless networks to operate simultaneously in the same geographical area and through the same radio frequency (RF) spectrum band includes a plurality of wireless networks each network having at least one radio frequency (RF) transmitting node, capable of estimating the effect of its transmission on another, separate, wireless network of the plurality of wireless networks, each transmitting node having a modulation classifier that estimates from a received wireless signal, a modulation scheme used in the transmission of a wireless link that is received in the highest power in a secondary network of the plurality of wireless networks; and a throughput estimator which predicts, without the need to exchange information between a primary and secondary networks of the plurality of wireless networks, the adaptive modulation and coding configuration for the primary link that is received with highest power at the secondary network transmitting node.

Abstract: A wireless communication system and method for allowing two or more wireless networks to operate simultaneously in the same geographical area and through the same radio frequency (RF) spectrum band includes a plurality of wireless networks each network having at least one radio frequency (RF) transmitting node, capable of estimating the effect of its transmission on another, separate, wireless network of the plurality of wireless networks, each transmitting node having a modulation classifier that estimates from a received wireless signal, a modulation scheme used in the transmission of a wireless link that is received in the highest power in a secondary network of the plurality of wireless networks; and a throughput estimator which predicts, without the need to exchange information between a primary and secondary networks of the plurality of wireless networks, the adaptive modulation and coding configuration for the primary link that is received with highest power at the secondary network transmitting node.

Abstract: A wireless server-to-server datacenter network architecture uses wireless links to eliminate the need for power-hungry switching fabric of traditional fat-tree based datacenter networks. The server-to-server wireless datacenter network (S2S-WiDCN) requires Line-of-Sight (LoS) between servers to establish direct communication links. Utilizing this LoS links, a horizontal-first routing algorithm is developed which, will establish fast communication links between any pair of communicating servers in the data center. The wireless links can be realized in millimeter-wave (such as 30, 60, 120 GHz) or THz (such as 300 GHz) frequency bands. The use of antenna-arrays to create beam-steering towards communicating servers is necessary to establish the direct server-to-server links. In the presence of an obstruction such as an IT technician, the LoS between communicating servers may be blocked. To address this issue, an obstruction-aware adaptive routing algorithm for the S2S-WiDCN is proposed.

Abstract: A method, system and apparatus for generating a constant amplitude zero autocorrelation (CAZAC) sequence to be transmitted on a wireless communication channel between a user equipment and a base station within a cellular communication network includes iteratively calculating elements of the CAZAC sequence according to a CAZAC sequence formula until a number of iterations has reached a predetermined iteration value determined in accordance with a number of subcarriers associated with the channel; obtaining a value of particular elements of the CAZAC sequence from a table of stored values at predetermined reset iteration values in order to limit error propagation; and generating the reference signal based upon the elements of the CAZAC sequence. The CAZAC sequence formula is one of a Chu sequence, Frank-Zadoff sequence, Zadoff-Chu (ZC) sequence, and Generalized Chirp-Like (GCL) Sequence.

Abstract: A method, system and apparatus for generating a constant amplitude zero autocorrelation (CAZAC) sequence to be transmitted on a wireless communication channel between a user equipment and a base station within a cellular communication network includes iteratively calculating elements of the CAZAC sequence according to a CAZAC sequence formula until a number of iterations has reached a predetermined iteration value determined in accordance with a number of subcarriers associated with the channel; obtaining a value of particular elements of the CAZAC sequence from a table of stored values at predetermined reset iteration values in order to limit error propagation; and generating the reference signal based upon the elements of the CAZAC sequence. The CAZAC sequence formula is one of a Chu sequence, Frank-Zadoff sequence, Zadoff-Chu (ZC) sequence, and Generalized Chirp-Like (GCL) Sequence.