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Building Resilient IT Infrastructure for the 21st Century

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Title: Building Resilient IT Infrastructure for the 21st Century


1
Building Resilient IT Infrastructure for the
21st Century
  • Jack Pressman
  • Chief Technology OfficerCyber Development Group
    International
  • March 7, 2007

2
The Problem
  • IT decision makers of enterprise level
    companies face the daunting task of
  • Providing a survival IT Platform
  • Providing a durable IT Platform
  • Providing an adaptable IT Platform
  • Providing a compliant IT Platform
  • Providing a cost effective IT Platform

3
The Challenge
  • Building a true resilient IT infrastructure
    requires significant
  • Planning
  • Resource allocation
  • Underlying CxO / Board commitment

4
a Methodology for Success.
  • Fundamental Steps
  • SETUP a dedicated IT Infrastructure Resiliency
    Planning Team
  • PLANNING is key to defining the Enterprise / Data
    Center Platform Critical Goals
  • Develop a fundamental corporate IT Infrastructure
    STRATEGY for achieving the Critical Goals
  • Acquire CxO / Board SUPPORT for Team, Goals and
    Strategy

5
PLANNING The Data Center
  • Building a true resilient Data Center platform
    requires addressing 4 Fundamental Components
  • Capacity Planning
  • Floor Plan Layout
  • MEP Load Distribution Strategy
  • Efficient / Value Based Procurement and
    Infrastructure Deployment

6
Step One Capacity Planning
  • Define the current and FUTURE capacity for both
    MEP and DATACOM requirements of the Data Center
  • Key Capacity Constants
  • 1) One Rack takes up 40 SF of Raised Floor
  • 40 SF of MEP Equipment Space
    (Medium Density)
  • 2) One 20 amp 120 VAC circuit 2 kW (approx)
  • 3) One Single Phase 30 amp 208 VAC circuit
    5.77 kW
  • 4) BTUs kWh 3,412
  • 5) One Ton of Cooling 12,000 BTUs per Hour
  • Example One (1) 20 Ton CRAC provides cooling
    for 80 kW of
  • electricity i.e. 20 racks _at_ 4 kW/
    Rack

7
Step One Capacity Planning
  • KEY CAPACITY VARIABLES
  • Total Data Center Floor (in SF)
  • Kilowatts per Rack (kW / Rack)
  • Production Balance ( of Total Load _at_ each
    facility)
  • Production Capacity Processing Storage (MIPS
    / TB)

8
Step One Capacity Planning
  • KEY CAPACITY FORMULAS for Current and Future
    MEP and DATACOM Requirements
  • 1a CURRENT (Data Center Floor) Existing DC
    Foot Print 1.2
  • 1b CURRENT (Kilowatts per Rack) Existing kW
    per Rack 1.2
  • 1c FUTURE (Data Center Floor) Existing DC
    Foot Print 2.0
  • 1d FUTURE (Kilowatts per Rack) Existing kW per
    Rack 2.0
  • 1e CURRENT (Bandwidth) Existing Bandwidth
    1.4
  • 1f FUTURE (Bandwidth) Existing Bandwidth
    10.0
  • 1g FUTURE (Load Dispersion / Site)
    Existing Production 0.33
  • 1h FUTURE (Production Capacity / Site)
    Existing Production 4.0

9
Step One Capacity Planning
  • EXAMPLES
  • 1a IF CURRENT (Data Center Floor) 2,000 SF
    48 Racks
  • THEN near term growth will most likely exceed
    2,400 SF 60 Racks
  • AND long term growth will require a minimum of
    4,000 SF 80 Racks
  • 1b IF CURRENT (Kilowatts per Rack) 3.0 kW per
    average rack usage
  • THEN near term growth will most likely exceed
    3.6 kW per rack
  • AND long term growth will require a minimum of
    6.0 kW per rack
  • 1e IF CURRENT (Bandwidth) 1.5 Gigabits per
    Second (GBS)
  • THEN near term growth will most likely exceed
    3.0 GBS
  • AND long term growth will require a minimum of
    15.0 GBS
  • 1g IF CURRENT (Production Load) 100 MIPS / 4
    TB _at_ one Site
  • THEN long term CAPACITY PLANNING should assume
    a LOAD BALANCED platform of 3 sites capable
    of 400 MIPS/ 16 TB per site

10
Step Two Floor Plan Layout
  • KEY DESIGN CONCEPT Compartmentalize
  • Define the specific Floor Plan based on
    PRIORITIES
  • Security / Access and Control Parameter
  • Power / Cooling (Heat Dissipation) Densities
  • Business Unit

11
Step Two Floor Plan Layout
  • EXAMPLES
  • Security / Access and Control can be addressed
    through multiple levels of physical separation
  • Highest Level Separate Rooms with 4 hour fire
    walls and Man Traps
  • Medium Level Physically demised rooms using
    bonded drywall with a wire fence center from slab
    to ceiling
  • Moderate Level Steel Cage demising each
    specified Business Unit from slab to ceiling

12
Step Two Floor Plan Layout
  • EXAMPLES
  • Power Densities can be addressed through 3
    physical zones
  • High Density Racks requiring in excess of 10 kW
    - Specifically focused on supporting Blade
    Chassis Chilled Water infrastructure required
  • Medium Density Racks requiring 6 to 10 kW
    Blade Servers, Storage Devises Significant
    increase in SF allocation per rack for
    under-floor air-cooled distribution
  • Moderate Density Racks requiring 2 to 6 kW
    Light Server distribution, Tape Devices, Network
    Devices Traditional under-floor air cooling
    acceptable

13
Step Three MEP Load Distribution
  • KEY STARTING POINT Defining the MEP Fork in
    the Road Under floor air cooling vs. in-row
    chilled water based CRAC systems.
  • Rack densities (in excess of 6 10 racks)
    requiring 8 kW /rack will require a chilled water
    based CRAC system
  • Three Build Options to supporting High Density (8
    kW / Rack )
  • CHEAP and SHORT-SIDED Spread out rack based
    devices to lower energy consumption per rack
  • EXPENSIVE and COST INEFFICIENT Build the Data
    Center with a chilled water based MEP
    infrastructure to support in-row cooling
  • REASONABLE Separate LOW / MEDIUM Density Racks
    into a separate MEP ZONE (/ room) from HIGH
    DENSITY Racks

14
Step Four Efficient / Value Based Procurement
and Deployment
  • KEY Efficient and Cost Effective components to
    building a better IT Data Center Facility
  • Build / lease (w/option) facilities with adequate
    physical shell space to support future expansion.
  • Physically separate High Density Racks that
    require expensive in row based chilled water
    solutions from Medium / Moderate racks that can
    be cooled with traditional under floor air
  • Look carefully at developing a load balanced /
    mirrored multi-site platform vs. a one on-site
    production facility with an off-site D/R
    facility
  • NOTE COST OF MOVING A PRIMARY PRODUCTION SITE
    AT A LATER DATE IS AN EXTREME EXPENSE AND
    SIGNIFICANT DISRUPTION
  • Only enter in Datacom contracts that provide
    roll-up options to more bandwidth at
    substantially lower cost per unit at a future
    date.
  • 5. Build networks that provides scalable /
    gigabit (lambda) bridges to key metro NAPs

15
Building Resilient IT Infrastructure
  • Thank You.
  • Jack Pressman
  • Chief Technology Officer
  • Cyber Development Group International, LLC
  • 877-996-2999
  • www.cyberdevgroup.com

Disclaimer Examples and information provided
are for estimates and discussion only.
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