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E6719J Datasheet, PDF (10/16 Pages) Keysight Technologies – E6706G 1xEV-DO Lab Application
10 | Keysight | E6706G 1xEV-DO Lab Application - Technical Overview
1xEV-DO multi-flow packet application
Multi-flow packet application
Protocol stack
Multi-flow packet application opera-
tion
Air interface support
IP flows
RLP flows
RTC MAC subtype 3 flows
Mapping rules
Forward mapping rule parameters
Reverse mapping rule parameters
Forward RLP flow parameters
Reverse RLP flow parameters
Data throughput monitor
Session application
pre-configurations
Traffic channel MAC
pre-configurations
1xEV-DO Release A only
Allows the test set to emulate a complete data network
by providing transparent connectivity to a 1xEV-DO AT.
Supports multiple IP flows in both the forward and reverse
links to support quality of service. Requires that the test
be connected to an external server via the rear panel LAN
connector
Supports all physical layer subtype 2 parameters and
functionality
Supports up to 16 forward and reverse IP flows
Supports 5 forward RLP flows and 5 reverse RLP flows
Supports 4 user-configurable RTCMAC subtype 3 flows
Supports a default mapping rule and 6 user-configurable
mapping rules. When a phone requests an IP flow, the test
set searches the user-defined mapping rules to find a match
for the requested profile ID. If a match is found, then the test
set maps the IP flow according to the user-defined rule. If
no match is found, the test set applies the default rule and
maps the IP flow to the best effort flow
For each of the 6 user-configurable mapping rules: User
settable profile ID (hex input), RLP flow mapping (RLP flow 0
through 4), reservation idle state behavior (no change, close
with connection, or follow connection), and AN scheduler
priority (0 through 7 with 0 being the lowest priority)
For each of the 6 user-configurable mapping rules: User
settable profile ID (hex input), RLP flow mapping (RLP flow 0
through 4), and reservation idle state behavior (no change,
close with connection, or follow connection)
For each of the 5 RLP flows: MFPA NAK enable (on or Off),
MFPA abort timer (ms), MFPA flush timer (ms), MFPA header
size (14 or 22 bits), MFPA RLP ID (binary)
For each of the 5 RLP flows: MFPA NAK enable (On or Off),
MFPA physical layer NAK enable (On or Off), MFPA abort
timer (ms), MFPA flush timer (ms), MFPA header size (14
or 22 bits), MFPA RLP ID (binary), MFPA RTC MAC flow
mapping (flows 1 through 4), and MFPA data over signaling
allowed (On or Off)
Supports four user-definable data throughput monitor
(DTM) contexts in both the forward and reverse links that
can be assigned to any of the mapping rules. Each context
appears on the data throughput monitor as a trace allowing
analysis of data throughput for a specific IP flow
Supports four pre-configurations that set all related MFPA
parameters of specific applications: Preset values (return
to power-up state), IS-856 protocol default values, MFPA
maximum throughput best effort with video telephony at 64
kbps, and MFPA best effort with video telephony at
64 kbps
Supports for each of the 4 RTC MAC subtype 3 flows
the following pre-configurations: Preset with maximum
throughput, IS-856 protocol default values, SIP/RTCP, video
64 kbps, audio for video at 64 kbps, best effort, gaming, and
voice over IP