Download G-Rake White Paper here !
Download G-Rake White Paper
Download G-Rake White Paper here!
The G-Rake receiver, which resides in the demodulator, produces estimates of the modulation symbols from the received signal. Because the G-...
G-Rake receiver
The G-Rake receiver, which resides in the demodulator, produces estimates of the modulation symbols from the received signal. Because the G-Rake receiver is similar
to a traditional Rake receiver, let us also briefly review Rake reception.
Signal energy is collected from different delayed versions of a transmitted signal. As seen in Figure 2, the channel response creates multiple images of the transmitted signal (that is, the dispersive, multipath channel gives rise to different versions). The “fingers” of the Rake receiver extract signal energy from delayed signal images by despreading and combining them – the Rake receiver coherently combines the finger outputs using complex conjugates of estimated channel coefficients to estimate the modulation symbol. Figure 3 shows a simple example
in which two despread values are combined (x1 and x2, which correspond to
two signal paths). Each despread value consists of a signal component (s), an interference component (i), and a noise component (n). When combining the values, the Rake
to a traditional Rake receiver, let us also briefly review Rake reception.
Signal energy is collected from different delayed versions of a transmitted signal. As seen in Figure 2, the channel response creates multiple images of the transmitted signal (that is, the dispersive, multipath channel gives rise to different versions). The “fingers” of the Rake receiver extract signal energy from delayed signal images by despreading and combining them – the Rake receiver coherently combines the finger outputs using complex conjugates of estimated channel coefficients to estimate the modulation symbol. Figure 3 shows a simple example
in which two despread values are combined (x1 and x2, which correspond to
two signal paths). Each despread value consists of a signal component (s), an interference component (i), and a noise component (n). When combining the values, the Rake
WCDMA continues to evolve to support high-bit-rate applications. High-speed downlink packet access (HSDPA) technology, for example, substant...
G-Rake reception
WCDMA continues to evolve to support high-bit-rate applications. High-speed downlink packet access (HSDPA) technology, for example, substantially increases data rates in the downlink. As data rates increase, however, greater self-interference from the dispersive radio channel limits performance. As a consequence, Ericsson has developed advanced receivers for WCDMA terminal platforms and base stations.
The authors describe an advanced receiver approach known as generalized Rake (G-Rake) reception. The G-Rake receiver functions like an equalizer, suppressing self-interference. To minimize cost and time-to-market, the receiver architecture builds on the traditional Rake receiver architecture. Tests show that the G-Rake receiver can significantly improve throughput and system capacity for high-bit-rate applications. Ericsson will include G-Rake for HSDPA services starting with its U350 and U360 WCDMA platforms.
G-Rake reception is also being considered for other applications. For voice service, for instance, it can increase downlink capacity by 30%. Data and voice applications improve when G-Rake reception is used in conjunction with the two-antenna terminal platforms that are part of EMP's technology roadmap. G-Rake will also significantly improve performance on the uplink when data rates exceed 2Mbps in later phases of the enhanced uplink (EUL).
The authors describe an advanced receiver approach known as generalized Rake (G-Rake) reception. The G-Rake receiver functions like an equalizer, suppressing self-interference. To minimize cost and time-to-market, the receiver architecture builds on the traditional Rake receiver architecture. Tests show that the G-Rake receiver can significantly improve throughput and system capacity for high-bit-rate applications. Ericsson will include G-Rake for HSDPA services starting with its U350 and U360 WCDMA platforms.
G-Rake reception is also being considered for other applications. For voice service, for instance, it can increase downlink capacity by 30%. Data and voice applications improve when G-Rake reception is used in conjunction with the two-antenna terminal platforms that are part of EMP's technology roadmap. G-Rake will also significantly improve performance on the uplink when data rates exceed 2Mbps in later phases of the enhanced uplink (EUL).
Subscribe to:
Comments (Atom)
Follow Us
Were this world an endless plain, and by sailing eastward we could for ever reach new distances