} :radio-cfg-set-odu-txfreq:$odubid,255,$tx_freq sleep 3 set check_set [:radio-cfg-get-odu-rfreq:$odubid,255] set flag_pos [string first $tx_freq $check_set] if {$flag_pos == -1} { puts "Error:

Frequency setting failed!" puts $record_file ",,Error: Frequency setting failed!" continue

The transmitter transmits two signals with the same frequency over a horizontal polarization wave and a vertical polarization wave. Due to XPD of the antenna and channel degradation, cross-polarization interferen ce exists in the signals received by the ODU and also in the IF signals transmit ted from the ODU to the IF boards of XPIC. The XPIC module on the XPIC board receives the IF signal from the ODU and also t he IF signal from the other IF board of XPIC, and processes the IF signals, for example, A/D conversion. The XPIC module on the XPIC board controls the coefficient of the feed forward e qualizer filters (FFF) of the two IF signals by using the decision feedback equa lizer (DFE). As a result, after filtering and combination, the interference is c ancelled in the two IF signals. The transmitter transmits two signals with the same frequency over a horizontal polarization wave and a vertical polarization wave. Due to XPD of the antenna and channel degradation, cross-polarization interferen ce exists in the signals received by the ODU and also in the IF signals transmit ted from the ODU to the IF boards of XPIC. The XPIC module on the XPIC board receives the IF signal from the ODU and also t he IF signal from the other IF board of XPIC, and processes the IF signals, for example, A/D conversion. The XPIC module on the XPIC board controls the coefficient of the feed forward e qualizer filters (FFF) of the two IF signals by using the decision feedback equa lizer (DFE). As a result, after filtering and combination, the interference is c ancelled in the two IF signals.

The IF boards of XPIC receive signals in the horizontal and vertical directions. The signals in the two directions are then processed and the original signals a re recovered. The IF boards of XPIC receive signals in the horizontal and vertical directions. The signals in the two directions are then processed and the original signals a re recovered. The IF boards of XPIC receive signals in the horizontal and vertical directions. The signals in the two directions are then processed and the original signals a re recovered. The IF boards of XPIC receive signals in the horizontal and vertical directions. The signals in the two directions are then processed and the original signals a re recovered. The IF boards of XPIC receive signals in the horizontal and vertical directions. The signals in the two directions are then processed and the original signals a re recovered. The IF boards of XPIC receive signals in the h

This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the

bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) This topic considers the application of the XPIC as an example to describe the X PIC feature. The application of the XPIC technology enables using the same channel bandwidth to transmit service signals whose capacity is two times the capacity of applicat ion without XPIC. The transmission of 2xSTM-1 signals in one direction of the ra dio link is considered as an example. When the XPIC technology is not used, the adjacent channel alternate polarization (ACAP) technology should be used in chan nel configuration. Thus, the bandwidth of two RF channels should be used to tran smit these 2xSTM-1 signals. See Figure 1. When the XPIC technology is used, the bandwidth of one RF channel can transmit 2xSTM-1 signals by using the CCDP chann el configuration mode. See Figure 2. Figure 1 Channel configuration in ACAP mode (without the application of the XPIC technology) P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface.

Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when

TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet

services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet

services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface.

As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification

IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching.

Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane

Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa

me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps

ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte

d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports.

Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces.

Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave.

Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p

lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services,

and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat

ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface.

Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when

TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet

services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet

services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface.

As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.P Microwave Classification IP microwave can transmit packet services and support the AM function. The packe t services transmitted can be Native Ethernet services or packet services encaps ulated in PWE3. Conventional IP microwave is divided into two different types: H ybrid microwave and Packet microwave. Hybrid microwave: Native TDM services and Native Ethernet services can be transm itted through the air interface. Packet microwave: TDM services, ATM/IMA services, and Ethernet services after PW E3 encapsulation are transmitted through the air interface. As IP microwave evolves, the OptiX RTN 950A supports Integrated IP radio. As a r esult, the equipment can support Hybrid microwave and Packet microwave at the sa me time, and can simultaneously transmit multiple types of services at air inter faces. Integrated IP radio To achieve flexible grooming of TDM services and packet services on the Integrat ed IP radio, the OptiX RTN 950A is embedded with dual service planes: TDM servic e processing plane and packet service processing plane. TDM services and packet services can be flexibly transmitted over the Integrated IP radio.. TDM service processing plane Performs cross-connections on the incoming TDM services (E1 services or STM-1 se rvices), and transmits the services to the microwave ports. Packet service processing plane Performs PWE3 emulation on the incoming services (E1 services, ATM/IMA services, and Ethernet services), encapsulates them into the MPLS packets, and transmits the Ethernet frames that bear the MPLS packets to the microwave ports. Ethernet services are directly transmitted to the microwave ports in Native mode after La yer 2 switching. Native TDM services, MPLS packets, or Native Ethernet services need to be groome d to the microwave port, encapsulated into microwave frames, and then transmitte d on microwave links. The Integrated IP radio serves as Hybrid microwave when TD M services are scheduled to the microwave port over the TDM service processing p lane and Ethernet services are scheduled to the microwave port over the packet s ervice processing plane; the Integrated IP radio serves as Packet microwave when TDM services are encapsulated into MPLS/PWE3 packets on the packet service proc essing plane and then scheduled to the microwave port.

vorizontal and vertical directions. The signals in the two directions are then p rocessed and the original signals are recovered. The IF boards of XPIC receive signals in the horizontal and vertical directions. The signals in the two directions are then processed and the original signals a re recovered.