In this paper, we employ a time-domain channel estimation, equalization and phase correction scheme for single carrier single input multiple output (SIMO) underwater acoustic communications. In this scheme, Doppler shift, which is caused by relative motion between transducer (source) and hydrophones (receiver), is estimated and compensated in the received baseband signals. Then the channel is estimated using a small training block at the front of a transmitted data package, in which the data is artificially partitioned into consecutive data blocks. The estimated channel is utilized to equalize a block of received data, then the equalized data is processed by a group-wise phase correction before data detection. At the end of the detected dat...
International audienceDesigning transmission systems often requires to account for possible fast var...
This paper proposes a new iterative receiver for single-carrier multiple-input-multiple-output (SC-M...
Underwater wireless (sensor) networks would vastly improve man's ability to explore and exploit remo...
In this paper, we employ a time-domain channel estimation, equalization and phase correction scheme ...
This paper presents a new channel estimation, equalization, and phase correction scheme to combat th...
A frequency-domain channel equalization and phase correction method was proposed in a previous work ...
A new frequency-domain channel estimation and equalization (FDE) scheme is proposed for single carri...
The present report assesses the performance of several receiver schemes that attempt to recover as b...
Multiple-input multiple-output (MIMO) underwater acoustic (UWA) channels introduce both space-time ...
The present dissertation presents new developments in the signal processing of receiver structures f...
This dissertation focuses on data communication over shallow, long-range underwater acoustic (UWA) c...
In underwater acoustic (UWA) communication, Doppler effect is particularly severe due to the slow ve...
Abstract — In this paper, we propose a time-domain receiver design scheme for high data rate single ...
This paper investigates a low-complexity frequency-domain turbo equalization (FDTE) based on linear ...
It is known that small changes in source and receiver locations can cause significant changes in und...
International audienceDesigning transmission systems often requires to account for possible fast var...
This paper proposes a new iterative receiver for single-carrier multiple-input-multiple-output (SC-M...
Underwater wireless (sensor) networks would vastly improve man's ability to explore and exploit remo...
In this paper, we employ a time-domain channel estimation, equalization and phase correction scheme ...
This paper presents a new channel estimation, equalization, and phase correction scheme to combat th...
A frequency-domain channel equalization and phase correction method was proposed in a previous work ...
A new frequency-domain channel estimation and equalization (FDE) scheme is proposed for single carri...
The present report assesses the performance of several receiver schemes that attempt to recover as b...
Multiple-input multiple-output (MIMO) underwater acoustic (UWA) channels introduce both space-time ...
The present dissertation presents new developments in the signal processing of receiver structures f...
This dissertation focuses on data communication over shallow, long-range underwater acoustic (UWA) c...
In underwater acoustic (UWA) communication, Doppler effect is particularly severe due to the slow ve...
Abstract — In this paper, we propose a time-domain receiver design scheme for high data rate single ...
This paper investigates a low-complexity frequency-domain turbo equalization (FDTE) based on linear ...
It is known that small changes in source and receiver locations can cause significant changes in und...
International audienceDesigning transmission systems often requires to account for possible fast var...
This paper proposes a new iterative receiver for single-carrier multiple-input-multiple-output (SC-M...
Underwater wireless (sensor) networks would vastly improve man's ability to explore and exploit remo...