QorIQ™ Communications Platforms
P2 Platform Series
Ideal for networking infrastructure, telecom,
industrial control, medical imaging,
telehealth, aerospace and defense and test
and measurement applications, Freescale
QorIQ™ communications platforms are the
next-generation evolution of our leading
PowerQUICC
®
communications processors.
Based on high-performance e500 cores built
on Power Architecture
®
technology, QorIQ
platforms enable a new era of networking
innovation that meets reliability, security
and quality of service needs for the most
demanding networking and industrial
applications.
The QorIQ P2 platform series, which includes
the P2020 and P2010 communications
processors, delivers unprecedented
performance per watt for a wide variety of
applications at a low price point. The series
Dual core performance in a single core power envelope
delivers dual- and single-core frequencies
from 800 MHz to 1.2 GHz.
The QorIQ P2 series is pin-compatible with
the QorIQ P1 platform products, offering
five interchangeable cost-effective solutions.
Scaling from a single core at 533 MHz (P1011)
to a dual core at 1.2 GHz (P2020), the
two QorIQ platforms deliver an impressive
4.5x aggregate frequency range within the
same pinout.
The devices in the P1 and P2 series are also
software compatible, sharing the e500 core
and peripherals, as well as being fully software
compatible with existing PowerQUICC
processors. This enables you to create a
product with multiple performance points from
a single board design, which provides great
flexibility and scalability.
Freescale provides highly integrated
evaluation boards, software and drivers for the
P2020 and P2010 as well as CodeWarrior™
tools that will help speed your design to
market. The P2020 family provides the
horsepower, integration and scalability needed
whether you are building a high-performance
router or an industrial platform.
QorIQ™ P2 Processors
Features
Comprehensive development tools including reference design boards,
Linux
®
and third-party tools
Migration path
Benefits
Helps decrease time to revenue by getting designs up and
running efficiently
Improved performance/watt/cost migrating from PowerQUICC III and
other Power Architecture-, x86- and MIPs-based architectures
High performance and efficient cores means fewer cores to get the
job done
Enables fanless, energy-efficient designs for improved reliability and
lower system costs
Flexibility to address a wide range of applications and reduced
system cost by eliminating the need for external bridge chips
Common hardware platform to enable a wide range of
system performance
High-performance e500 2.4 MIPS/MHz Power Architecture
®
core
Best-in-class power
Integrated Ethernet, USB, eSDHC flash controller, eSPI, eLBU,
IEEE
®
1588, PCI Express
®
and Serial RapidIO
®
4.5x performance range in a single package
Telecom
Features for the market:
• Dual Gigabit Ethernet on SGMII
(for redundancy) or Serial RapidIO
®
interface for implementing backhaul
• Serial RapidIO interface for direct
connection to digital signal processors
(DSPs)—for Layer 1 processing
• Security engine handles the secure network
termination requirement
• Advanced quality of service (QoS) for
Gigabit Ethernet to assist in scheduling
Layer 2 baseband processing
LTE and WiMAX Baseband
Serial RapidIO x1/x4
(up to 3.125 GHz)
• MAC
• Scheduler
500
Mbps
Backplane
Gigabit
Ethernet
control and
data,
redundant
Serial RapidIO
Serial
RapidIO
QorIQ™
P2 Series
Low
latency
Serial RapidIO
®
DSP
DSP
Serial
RapidIO
x1/x4
Switch
Applications:
• AdvancedMC™ card
• Controller on AdvancedTCA
carrier card
®
• Serial RapidIO
messaging unit
• Multiple mailboxes
• Port read/write to
configure switch
• Messaging
(inbound/outbound)
local and remote
DSP
xn DSPs
FPGA
OBSAI/CPRI
LTE and WiMAX Baseband
The P2020 and P2010 communications
processors are well-suited for Long-Term
Evolution (LTE) and WiMAX channel card
applications. There are two factors that drive
the need for dual-core performance without
breaking out of a single-core power budget:
• Increased bandwidth per subscriber
• Flattening of the infrastructure hierarchy
Together, these factors increase the
processing requirements of the channel
card. P2 series processors, with dual-
core performance in single-core power
budgets, can increase performance in Layer
2 baseband processing and implementing
network interfaces.
Layer 2 baseband processing implements
the RLC layer that controls the base station
and subscriber access to air interface
resources. The advanced QoS features of the
Gigabit Ethernet ports assist in scheduling
these resources. This Layer 2 processing
includes the medium access control
(MAC), which controls the base station and
subscriber access to air interface resources.
Resources are scheduled according to QoS
requirements using packet concatenation
and segmentation, retransmission through
automatic repeat request (ARQ) and
hybrid automatic repeat request (HARQ) in
combination with Layer 1.
Typically backhaul is implemented with
either dual Gigabit Ethernet on SGMII (for
redundancy) or Serial RapidIO interface, both
of which are supported in the QorIQ P2 series
processors. The Serial Rapid IO interface also
allows direct connection to the DSPs—such
as Freescale’s MSC8144 and MSC8156 four-
and six-core DSPs—that implement the Layer
1 processing. The security block handles the
secure network termination requirement.
This solution performs network backhaul
transport and interworking with internal
interfaces. This includes processing the
network layers up to OSI Layer 3, including
IPsec secure network termination, header
compression and traffic classification
(QoS). The network interface card (NIC)
can optionally support 3G LTE radio link
encryption—however, depending upon the
selected architecture, this could be partitioned
to the channel card.
• Channel and control card for 3G NodeB,
2G/2.5G BTS IP upgrades, WCDMA,
4G LTE and WiMAX
• General purpose compute blade
3
freescale.com/QorIQ
Compute Blades
RS232
Front Panel
Micro-SD Flash
FPGA
RJ45
Compute Blades
Blade servers have been widely adopted in
data centers because they cost less to deploy
and less to operate—due to savings in power
and cooling—than rack-optimized servers.
Gigabit
Ethernet
PHY
Blade servers are also more easily scaled
than fixed-capacity monolithic servers to meet
workload growth and are easier to service
with their field-replaceable blades.
Serial
DDR
SDRAM
QorIQ™
P2020
DDR2/3
RGMII
Blades process and move a large amount of
data. Historically, designers have incorporated
more processors and more processor types.
Systems could include any number of CPUs,
DSPs, microcontrollers, network processors
and application-specific processors.
Embedding switches into blade servers
provides further infrastructure integration,
eSDHC
RGMII
RGMII
Serial
RapidIO
®
PCI
Express
®
PMM
Gigabit
Ethernet
PHY
Gigabit
Ethernet
PHY
simplified management, greater scalability,
PCI Express1 x2 @ 2.5Gbaud/
SRIO1 (x1) @1.25 Gbaud /
SRIO2 (x1) @1.25 Gbaud
improved power and cooling efficiency and
increased application availability.
As enterprises begin to migrate to next-
AMC Connector
generation data centers, blade server switches
are evolving to meet the new demands with
advanced functions such as application-aware
networking, low latency line-rate switching
at Gigabit (Gb) speeds, advanced QoS,
support for virtualization and advanced
security features.
QorIQ processors can help designers reap the
benefit of using highly integrated processors
with the I/O needed for application/content-
aware processing. Freescale partner
companies such as 6WIND provide an open
framework to ease the transition from a
single core to many cores. Multicore-aware
network middleware from 6WIND can boost
performance, placing configuration and
management at the heart of the software. This
solves real business issues of time and cost
savings associated with software integration,
interface, configuration and network
management of multicore machines.
The P2020 processor can manage control
and dataplane functions in blade systems.
This reduces the cost of integrating additional
bridge chips to perform these functions.
freescale.com/QorIQ
4
Networking
Features for the Market:
• SD/MMC interface enables modularity by
supporting booting from flash cards
• PCI Express interfaces enable multiple
flexible I/O options
• USB port for front-panel code uploads
when connecting directly to a PC for
maintenance
• Triple Gigabit Ethernet (dual on SGMII for
redundancy for backplane interconnect)
and one Gigabit Ethernet interface for
high-performance debug and maintenance
The primary functions of a linecard
controller are:
• Exception handling: Packets that cannot be
interpreted by the typically more hardwired
datapath are kicked up to the control
plane processor. These may be older or
esoteric protocols which are not worth
accommodating in ASICs, but can be
handled with software with low performance
impact because they occur infrequently.
• Board housekeeping: The control plane
processor may be used to configure,
provision and control other devices on the
board. It also will collect statistics. It can
implement a command line interface.
• Table maintenance: A line card controller
may, especially in a distributed system,
manage the forwarding tables. The tables
are created by implementing a variety of
interior routing protocols (such as Open
Shortest Path First or Routing Information
Protocol) and external routing protocols
(such as Border Gateway Protocol). The
tables are then exported to the forwarding
path for per-packet access.
In the case of centralized processing, these
functions are performed by a centralized
processor, which can tolerate higher power
and associated increased cooling costs
because there are fewer of those cards per
system. In these cases, the line card has little
intelligence.
Implementing a line card in a distributed
processing system provides several
advantages. You may be able to forgo
the costly centralized services card,
which consumes a valuable slot in the
chassis. You have the opportunity to
perform local switching at the line card, thus
conserving system resources. And the system
becomes more scalable—as you add a line
card, you automatically get the increased
processing that it requires. However, in
this system, the costs of high-volume line
cards are critically important. Because of
that, thermal budgets are very tight. The
need for high performance at low power is a
requirement that the P2 family fulfills.
Applications:
• Line card controller
• Mid-range line card control plane
• Low-end line card combined control and
data plane
• Shelf controller
Line Card Control Plane for
Enterprise Routers
One of the primary applications for the QorIQ
P2020 communications processor is as a line
card control plane processor. Typically the
P2020 will sit to the side of the main datapath,
which has I/O processors on the front panel
connected to a backplane interface device.
The P2020 processor will communicate with
these components using standard interfaces
such as PCI Express or the local bus. The
P2020 will often have front panel interfaces as
well. One Gigabit Ethernet interface may be
used for high-performance debug: the DUART
can be used for a low-level command line
interface and the USB port may be used for
front-panel code uploads when connecting
directly to a PC for maintenance. Redundant
Gigabit Ethernet ports to the backplane are
used as a management interface, which can
be used to communicate with a centralized
resource for receiving table updates, for
instance. The eSDHC interface enables
modularity by supporting booting from
flash memory cards.
Line Card Control Plane for Enterprise Routers
I/O
Devices
Ethernet
Switch
I/O
Devices
I/O
Devices
Backplane
Enhanced Local Bus
Gigabit Ethernet-
Management Interfaces
Exception handling
Route table maintenance
Line card control
DRAM
Flash
PCI Express
®
Gigabit Ethernet-
Debug I/F
DUART-CLI
USB-Code Upload
QorIQ™
P2020
5
freescale.com/QorIQ
Multiservice Routers
A multiservice router or business gateway
requires a combination of high performance
and a rich set of peripherals to support the
datapath throughputs and required system
functionality. The P2 series of single- and
dual-core devices offer a scalable platform to
develop a range of products that can support
the same feature set. Integrated 10/100/1000
Ethernet controllers with classification and
QoS capabilities are ideal for managing
the datapath traffic between the local area
network (LAN) and wide area network (WAN)
interface. PCI Express ports can provide
connectivity to IEEE
®
802.11n radio cards
for wireless support and TDM for legacy
phone interfaces to support voice. USB or
eSDHC interfaces can be used to support
local storage; the second USB interface
is also available to support USB-attached
printers or as a console port. The integrated
security engine can provide encrypted secure
communications for remote users with
VPN support.
Multiservice Routers
DRAM
Flash
PCI Express
®
x1/x4
(up to 5 GHz)
Low
latency
QorIQ™
P2020
Gigabit Ethernet (SGMII)
Management Ports
• Multiple mailboxes
• Port read/write to
configure switch
• Messaging (inbound/
outbound) local and
remote
Gigabit
Ethernet
Control
and Data
DMZ
Server
LAN
Switch
WAN Interface
WAN Interface
freescale.com/QorIQ
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