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E-raamat: Cisco Digital Network Architecture: Intent-based Networking for the Enterprise

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  • Formaat: 300 pages
  • Sari: Networking Technology
  • Ilmumisaeg: 27-Dec-2018
  • Kirjastus: Cisco Press
  • Keel: eng
  • ISBN-13: 9780134723983
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Cisco Digital Network Architecture: Intent-based Networking for the EnterpriseSuurem pilt
  • Formaat: 300 pages
  • Sari: Networking Technology
  • Ilmumisaeg: 27-Dec-2018
  • Kirjastus: Cisco Press
  • Keel: eng
  • ISBN-13: 9780134723983
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This guide systematically introduces Cisco’s Digital Network Architecture (DNA), the enterprise network architecture for the next decade. Combining indispensable new insider information with content previously scattered through multiple technical documents, Cisco Digital Network Architecture combines technical depth, coherence, and comprehensiveness. This “living book” will be supported with regular online updates at a Cisco Press DNA website, offering a single authoritative source for everyone involved with DNA planning, implementation, and operation. Authored by insiders responsible for helping Cisco’s largest customers succeed with DNA, it:

  • Addresses emerging trends now driving business transformation
  • Explains why networks must become radically more intelligent, flexible, and adaptable
  • Shows how DNA empowers businesses by coherently integrating virtualization, automation, analytics, and cloud services.

Authoritative and fully up-to-date, Cisco Digital Network Architecture will help technical professionals, decision-makers, and consultants prepare to drive maximum value from next-generation networking.

Foreword xxxiv
Introduction xxxvi
Part I Introduction to Cisco DNA
Chapter 1 Why Transform Your Business Digitally?
1(18)
Opportunities and Threats
1(2)
Digitally Transforming Industries
3(4)
Digital Advertising
3(1)
Digital Media and Entertainment
3(1)
Digital Finance
4(1)
Digital Communications
4(1)
Digital Transportation Services
5(2)
Digitally Transforming Businesses
7(9)
Transforming the Customer Experience
8(1)
Burberry
8(1)
Starbucks
9(2)
UPS
11(1)
Transforming the Employee Experience
11(1)
Air France
12(1)
RehabCare
13(1)
Cisco
13(1)
Transforming Business Operations
14(1)
Boeing
14(1)
Codelco
15(1)
BC Hydro
16(1)
Driving Digital Transformation with the Internet of Things
16(1)
Are You Ready?
17(1)
Summary
18(1)
Further Reading
18(1)
Chapter 2 The Business Value of Cisco DNA
19(12)
Business Requirements of the Network Architecture
19(4)
Cost Reduction
20(1)
Risk Mitigation
20(1)
Actionable Insights
21(1)
Business Agility
22(1)
Intent-Based Networking
23(1)
Business Value of Cisco Digital Network Architecture
24(4)
Reducing Costs Through Automation, Virtualization, and Programmable Hardware
25(1)
Mitigating Risks with Integrated Security and Compliance
26(1)
Revealing Actionable Insights Through Analytics
26(1)
Accelerating Business Agility Through Open APIs
26(2)
Adding It All Up
28(1)
Summary
29(1)
Further Reading
29(2)
Chapter 3 Designing for Humans
31(24)
Technology Versus User-Experience
31(2)
Design Thinking Philosophy and Principles
33(1)
Cisco Design Thinking Framework
34(6)
Discover Phase
35(1)
Opportunity Statement
36(1)
Define Phase
37(1)
Problem to Be Solved Statement
38(1)
Explore Phase
39(1)
The Cisco Design Thinking Journey for Cisco DNA
40(13)
Cisco DNA Discovery Phase
41(1)
The Front-Line Engineer
42(2)
The Firefighter
44(1)
The Expert
45(3)
The Planner
48(1)
Cisco DNA Definition Phase
49(4)
Cisco DNA Exploration Phase
53(1)
Summary
53(1)
Further Reading
54(1)
Chapter 4 Introducing the Cisco Digital Network Architecture
55(32)
Requirements for Cisco DNA
56(4)
Requirements to Reduce Complexity and Costs
57(1)
Requirement to Increase Operational Flexibility
58(1)
Flexibility
58(1)
Intelligent Feedback Mechanism
59(1)
Application, User, and Device Awareness
59(1)
Security and Compliance Requirements
59(1)
Cloud-Enablement Requirement
60(1)
Architectural Principles
60(6)
Openness
61(1)
Extensibility
62(1)
Programmability
62(1)
Policy-based Networking
63(1)
Security
63(1)
Software Driven
64(1)
Cloud Integrated
65(1)
Conflicting Principles?
65(1)
Overview of the Cisco DNA Components
66(18)
Infrastructure
66(1)
Cisco DNA Infrastructure Domains
67(2)
Extending the Concept of Network Fabrics in Cisco DNA
69(1)
Virtualization
70(2)
Policy
72(1)
Automation
73(1)
Controllers
73(2)
Orchestrators
75(2)
Analytics Platform
77(1)
Data Collection
77(1)
Data Reporting
78(1)
Cisco DNA Analysis
78(1)
Feedback and Control
79(1)
The Role of the Cloud in Cisco DNA
80(1)
Cloud for Applications
81(1)
Cloud for Automation and Management
82(1)
Cloud for Analytics
82(1)
Connecting the Building Blocks: APIs
83(1)
Outcomes
84(1)
Summary
85(1)
Further Reading
86(1)
Chapter 5 The Cisco Digital Network Architecture Blueprint
87(36)
Cisco DNA Services
88(5)
Cisco DNA Services---Transport
90(1)
Cisco DNA Services---Policy
91(1)
Relationship Between Cisco DNA Policies and Business Intent
92(1)
Cisco DNA Infrastructure
93(6)
Transport Functions
94(2)
Supporting Network Functions
96(2)
Fabrics
98(1)
Automating Cisco DNA---Controllers
99(8)
Automating Transport and Network Functions Infrastructure
99(1)
Maintaining a View of the Infrastructure Functions and Connected Endpoints
100(1)
Instantiating and Maintaining Cisco DNA Services
100(2)
Relationships in Cisco DNA: Revisiting Domains, Scopes, and Fabrics
102(3)
Cisco DNA Interfaces
105(2)
Service Definition and Orchestration
107(5)
Relationship Between the Controllers and the Service Definition and Orchestration Component
110(2)
Analytics Platform
112(3)
Data Collection
113(1)
Data Extraction
113(1)
Data Ingestion
114(1)
Data Export
114(1)
On-Premises and Off-Premises Agnosticism---Revisiting the Cloud
115(5)
Application Hosting in the Cloud and the Evolution of the DMZ
116(2)
Leveraging the Cloud for Cisco DNA Controllers and Analytics
118(2)
Summary
120(3)
Part II Cisco DNA Programmable Infrastructure
Chapter 6 Introduction to Cisco DNA Infrastructure
123(12)
Picturing the Modern Network
124(1)
Exploring Cisco DNA Infrastructure
125(1)
The Evolving Network, and Why It Matters
126(4)
Requirements: The Need for Change
126(1)
Requirements: The Need for Speed (of Change)
127(1)
Requirements: The Need for Simplicity
128(1)
Requirements: The Need for Continuity
129(1)
Cisco DNA Infrastructure Solutions
130(3)
Flexible Hardware
130(1)
Flexible Software
131(1)
New and Evolving Protocols
132(1)
The Emergence of Virtualization
133(1)
Bringing It All Together
133(1)
Summary
134(1)
Chapter 7 Hardware Innovations
135(54)
The Importance of Hardware in a Software-Defined World
135(1)
The Making of a Chip
136(12)
Delving Deeper: How Chips Are Designed and Built
136(7)
Drivers of Chip Design and Density
143(2)
When Good Chips Go Bad: What Can Go Wrong in Chip Design
145(1)
When Good Chips Need to Get Better: Designing the Next Generation
146(1)
Now We Speak the Same Language!
147(1)
What's Happening in the World of Networks
148(1)
How Traditional Network ASICs Process Packets
149(1)
Traffic Handling with CPUs and FPGAs
150(2)
Introducing Flexible Silicon
152(2)
Flexible Switching Silicon: UADP
154(19)
UADP Use Cases---Current, and Future
163(2)
Introducing the Future: UADP 2.0 and 3.0
165(6)
So What's Common Across All of These Variants of UADP?
171(1)
UADP---Summing Up
172(1)
Flexible Routing Silicon: QFP
173(8)
QFP---An Introduction
174(2)
QFP---Diving Deeper
176(4)
QFP---Use in Platforms
180(1)
UADP and QFP---Summing Up
181(1)
Wireless: Providing Innovation for Mobility
182(4)
Flexible Radio Assignment
183(2)
Intelligent Capture
185(1)
Summary
186(1)
Further Reading
187(2)
Chapter 8 Software Innovations
189(36)
The Importance and Evolution of Networking Software
189(1)
Cisco IOS: Origins and Evolution
190(6)
Evolution of the Cisco IOS Data Plane
191(3)
Evolution of the Cisco IOS Control Plane
194(1)
Evolution of the Cisco IOS Management Plane
195(1)
Evolution of Cisco Networking Software
196(2)
The Evolution of Cisco IOS to IOS XE
198(1)
Cisco IOS XE in a Nutshell
199(2)
Cisco IOS XE: Delving Deeper
201(6)
IOS XE Subsystems
202(1)
IOS XE Database
203(2)
Container Framework and Application Hosting
205(2)
Cisco IOS XE: Bringing It All Together
207(5)
Cisco IOS XE: Simplification with a Single Release Train
209(1)
Cisco IOS XE: Software Maintenance Upgrades
209(1)
The Issue with Software Upgrades
210(1)
Types of SMUs---Cold, and Hot
211(1)
Installing a SMU
211(1)
Benefits of SMUs
212(1)
Cisco IOS XE: Platform Support
212(1)
Cisco IOS XE: Summary
213(1)
Protecting Platforms and Networks: Trustworthy Systems
214(8)
Trustworthy Systems: An Overview
215(1)
Possible Attacks: IOS Modifications
215(1)
Attack Mitigation with Trustworthy Systems
216(1)
Defense: Image Validation and Signing
217(1)
Defense: Runtime Defenses
217(1)
Defense: Secure Boot
218(1)
Understanding Boot Sequence Attacks
218(1)
Protecting Device Integrity from the Ground Up with Secure Boot
219(1)
Ensuring Device Identity with the Secure Unique Device Identifier
220(1)
Cisco Secure Boot and Trust Anchor Module: Validating the Integrity of Software, Followed by Hardware
221(1)
The Move to Intuitive Networking
222(1)
Summary
223(1)
Further Reading
223(2)
Chapter 9 Protocol Innovations
225(42)
Networking Protocols: Starting at the Bottom with Ethernet
226(9)
Power Protocols: Power over Ethernet, to 60 Watts and Beyond!
227(3)
The Future of Power over Ethernet
230(1)
Multiple-Speed Protocols over Copper: Multigigabit Ethernet, Squeezing More Life Out of Existing Cabling Infrastructures
230(4)
25G Ethernet---The New Kid on the Block
234(1)
Ethernet Evolving: This Is Not Your Father's Ethernet!
235(1)
Moving Up the Stack
235(7)
Networking Protocols: Moving Up the Stack to Layer 2
235(2)
Networking Protocols: Moving Up the Stack to Layer 3
237(1)
First-Hop Reachability Protocols: HSRP and VRRP
237(1)
Routing Protocols
238(2)
Virtual Routing
240(1)
Layer 2 over Layer 3
241(1)
Networking Protocols Today: Summary
242(1)
Networking Protocols for the New Era of Networking
242(22)
VXLAN: A Next-Generation Encapsulation Technology
243(4)
UDP Encapsulation
247(1)
Virtual Network Support
248(1)
Scalable Group Tag Support
248(1)
Summary: Why VXLAN?
248(1)
IS-IS: The Evolution of Underlay Routing
249(1)
LISP: The Evolution of Overlay Host Reachability
249(3)
The Need for Host Mobility
252(1)
The Need for Host Scale
252(1)
LISP to Address the Host Mobility and Scale Needs of the Next-Generation Network
253(2)
Examination of LISP Roaming Operation
255(2)
Summing Up: LISP As a Next-Generation Overlay Control Plane
257(1)
Scalable Group Tags: The Evolution of Grouping and Policy
257(4)
Scalable Group Tags for Group-Based Policies
261(2)
SGT Transport End-to-End Across the Network
263(1)
Bringing It All Together: What Next-Generation Protocols Within the Network Allow Us To Build
264(1)
Summary
264(1)
Further Reading
265(2)
Chapter 10 Cisco DNA Infrastructure---Virtualization
267(40)
Benefits of Network Function Virtualization
268(4)
CAPEX Benefits of NFV
268(2)
OPEX Benefits of NFV
270(1)
Architectural Benefits of NFV
271(1)
Use Cases for Network Function Virtualization
272(6)
Control Plane Virtualization
272(2)
Branch Virtualization
274(1)
Virtualization to Connect Applications in VPCs
275(1)
Virtualization of Multicloud Exchanges
276(2)
Overview of an NFV System Architecture
278(11)
Hypervisor Scheduling and NUMA
281(2)
Input/Output Technologies for Virtualization
283(6)
Challenges and Deployment Considerations of Network Function Virtualization
289(7)
Performance
289(1)
Oversubscribing the Physical Hardware Resources
290(1)
Optimizing Server Configurations
290(1)
Selecting the Right I/O Technique
291(1)
VNF Footprint Considerations
292(1)
Multi-tenancy and Multi-function VNFs
293(3)
Transport Virtualization
296(9)
Network Segmentation Architecture
297(1)
Network Access Control
298(1)
Network Path Virtualization
298(1)
Network Services Edge
299(1)
Policy-based Path Segmentation
299(3)
Control Plane-based Segmentation
302(1)
Multihop Path Isolation Techniques
302(1)
Single-Hop Path Isolation Techniques
303(2)
Summary
305(2)
Chapter 11 Cisco DNA Cloud
307(18)
Introduction to the Cloud
308(7)
Cloud Service Models
311(1)
Cloud Deployment Models
312(1)
It's a Multicloud World!
313(2)
Cisco DNA for the Cloud
315(8)
Cisco DNA Cloud for Applications
316(2)
Cisco DNA Cloud for Automation
318(1)
Cisco DNA Cloud for Analytics
319(4)
Summary
323(1)
Further Reading
323(2)
Part III Cisco DNA Automation
Chapter 12 Introduction to Cisco DNA Automation
325(12)
Why Automate?
325(5)
Reduce Total Cost of Ownership
326(1)
Lower Risk
326(2)
Move Faster
328(1)
Scale Your Infrastructure, Not Your IT Department
328(1)
Think "Out of the Box"
329(1)
Simplify Like Never Before
330(1)
Enable Applications to Directly Interact with the Network
330(1)
Is Cisco DNA Automation the Same as SDN?
330(2)
Centralized Versus Distributed Systems
331(1)
Imperative Versus Declarative Control
331(1)
The Cisco SDN Strategy
332(1)
Automation Elements
332(3)
Network Programmability
332(1)
Network Controller
333(1)
Network Orchestrator
334(1)
Summary
335(1)
Further Reading
336(1)
Chapter 13 Device Programmability
337(24)
Current State of Affairs
338(2)
CLI Automation
338(2)
SNMP
340(1)
Model-Based Data
340(4)
YANG
341(3)
Protocols
344(8)
Encoding
345(1)
Network Protocols
346(1)
Netconf
347(3)
Restconf
350(1)
gRPC
351(1)
Telemetry
352(2)
gRPC Telemetry
353(1)
Tools
354(3)
Application Hosting
357(2)
Summary
359(1)
Further Reading
359(2)
Chapter 14 Cisco DNA Automation
361(36)
The Increasing Importance of Automation
362(2)
Allow the Network to Scale
363(1)
Reduce Errors in the Network
363(1)
Time to Perform an Operation
363(1)
Security and Compliance
364(1)
Current Impediments to Automation
364(3)
Classifying Network Automation Tasks
367(4)
Infrastructure and Cisco DNA Service Automation
368(1)
Standard and Nonstandard Automation Tasks
369(2)
The Role of Controllers in Cisco DNA Automation
371(6)
Leveraging Abstractions in Cisco DNA to Deliver Intent-Based Networking
372(3)
Domain Controllers Versus Control Plane Protocols
375(2)
Automating Your Network with Cisco DNA Center
377(18)
Cisco DNA Center Basics
377(3)
Device Discovery, Inventory, and Topology
380(2)
Day 0 Operations---Standardizing on Network Designs
382(2)
Standardizing Settings for Supporting Network Functions
384(1)
Automating Device Credentials
384(1)
Reserving and Managing IP Address Pools
385(1)
Standardizing Service Provider QoS Profiles
386(1)
Characterizing Wireless LAN Profiles
387(1)
Standardizing on Network Designs
388(2)
Automating the Deployment of Network Elements and Functions
390(4)
Day N Operations---Automating Lifecycle Operations
394(1)
Summary
395(1)
Further Reading
396(1)
Part IV Cisco DNA Analytics
Chapter 15 Introduction to Cisco DNA Analytics
397(8)
A Definition of Analytics
397(1)
Cisco DNA Analytics
398(2)
Cisco DNA Analytics, Opportunities and Challenges
399(1)
Brief History of Network Analytics
400(1)
Why Cisco DNA Analytics?
401(1)
The Role of Network Analytics in Cisco DNA
402(2)
Summary
404(1)
Chapter 16 Cisco DNA Analytics Components
405(18)
Analytics Data Sources
405(2)
Cisco DNA Instrumentation
407(1)
Distributed Network Analytics
408(3)
Telemetry
411(5)
Why Telemetry?
412(1)
The Cisco DNA Telemetry Architecture
413(1)
Limitations of Today's Telemetry Protocols
413(1)
The Evolution of Cisco DNA Telemetry: Model-Driven Telemetry
414(2)
Analytics Engine
416(4)
The Traditional Analytics Approach
416(2)
The Need for Analytics Engines
418(1)
Data Scalability
419(1)
Analytics Efficiency
419(1)
Application Development Simplification
420(1)
The Role of the Cloud for Analytics
420(2)
Summary
422(1)
Further Reading
422(1)
Chapter 17 Cisco DNA Analytics Engines
423(28)
Why a Cisco DNA Analytics Engine?
425(2)
Cisco DNA Analytics Engines
427(1)
Cisco Network Data Platform
428(11)
Telemetry Quotient
430(1)
NDP Architecture
430(1)
NDP Architecture Principles
430(1)
NDP Architecture Layers
431(2)
NDP Architecture Components
433(3)
NDP Deployments Modes
436(1)
On-Premises Deployments
436(1)
Cloud Deployments
437(1)
NDP Security and High Availability
438(1)
Cisco Tetration Analytics
439(9)
It's All About Quality of Data
440(2)
Data Center Visibility with Cisco Tetration Analytics
442(2)
Cisco Tetration Analytics Architecture
444(1)
Data Collection Layer
444(1)
Analytics Layer
445(1)
Enforcement Layer
446(1)
Visualization Layer
446(1)
The Benefits of Cisco Tetration Analytics
446(2)
Summary
448(1)
Further Reading
449(2)
Part V Cisco DNA Solutions
Chapter 18 Cisco DNA Virtualization Solutions: Enterprise Network Functions Virtualization and Secure Agile Exchange
451(46)
The Cisco Strategy for Virtualization in the Enterprise
452(1)
Cisco Enterprise Network Functions Virtualization
453(35)
Details on Virtualization Hardware
455(4)
NFVIS: An Operating System Optimized for Enterprise Virtualization
459(4)
Virtualized Network Functions
463(1)
Cisco Integrated Services Virtual Router
463(1)
Cisco Adaptive Security Virtual Appliance
464(1)
Cisco Firepower NGFW Virtual
464(1)
Cisco Virtual Wide Area Application Services
464(1)
Cisco Prime Virtual Network Analysis Module
465(1)
Cisco Virtual Wireless LAN Controller
465(1)
Third-party VNF Support
466(2)
Service Chaining and Sample Packet Flows
468(3)
Transparent Versus Routed Service Chains
471(2)
Orchestration and Management
473(1)
NFVIS GUI (Per System)
473(5)
Cisco DNA Center (Network Level)
478(7)
Configuring and Monitoring of an NFVIS Host Using Traditional Mechanisms
485(3)
Virtualizing Connectivity to Untrusted Domains: Secure Agile Exchange
488(5)
Motivation for the Cisco SAE Solution
489(3)
Cisco SAE Building Blocks
492(1)
Running Virtualized Applications and VNFs Inside IOS XE
493(3)
Summary
496(1)
Further Reading
496(1)
Chapter 19 Cisco DNA Software-Defined Access
497(72)
The Challenges of Enterprise Networks Today
497(2)
Software-Defined Access: A High-Level Overview
499(1)
SD-Access: A Fabric for the Enterprise
500(42)
What Is a Fabric?
500(1)
Why Use a Fabric?
501(4)
Capabilities Offered by SD-Access
505(1)
Virtual Networks
505(1)
Scalable Groups
506(2)
Stretched Subnets
508(4)
SD-Access High-Level Architecture and Attributes
512(1)
SD-Access Building Blocks
513(1)
Cisco DNA Center in SD-Access
514(1)
SD-Access Fabric Capabilities
515(1)
IP Host Pools
515(1)
Virtual Networks
516(1)
Scalable Groups
517(1)
SD-Access Device Roles
518(2)
SD-Access Control Plane Nodes, a Closer Look
520(3)
SD-Access Fabric Border Nodes, a Closer Look
523(4)
SD-Access Fabric Edge Nodes
527(4)
SD-Access Extended Nodes
531(1)
SD-Access Wireless Integration
532(10)
SD-Access Case Study
542(23)
SD-Access Case Study, Summing Up
565(1)
Summary
565(2)
Further Reading
567(2)
Chapter 20 Cisco DNA Application Policy
569(62)
Managing Applications in Cisco DNA Center
570(15)
Application Registry
570(4)
Application Sets
574(2)
Application Policy
576(1)
Required Steps
576(6)
Optional Steps
582(1)
Queuing Profile
582(1)
Marking Profile
583(1)
Service Provider Profile
584(1)
What Happens "Under the Hood"?
585(1)
Translating Business Intent into Application Policy
586(3)
Cisco DNA Infrastructure Software Requirements for Application Policy
589(12)
NBAR2
589(3)
NBAR2 Operation
592(2)
QoS Attributes
594(2)
"Holy Grail" Classification and Marking Policy
596(3)
SD-AVC
599(2)
Cisco DNA Infrastructure Platform-Specific Requirements for Application Policy
601(27)
Routing Platform Requirements
602(1)
Application Classification and Marking Policies
602(1)
Queuing and Dropping Policies
603(2)
Sub-Line Rate Hierarchical QoS Policies
605(1)
Enterprise-to-Service Provider Mapping
606(3)
Hardware Queuing
609(3)
Internal System QoS
612(1)
Switching Platform Requirements
613(1)
Application Classification and Marking Policies
613(1)
Hardware Queuing Policies
614(4)
Internal System QoS
618(3)
Wireless Platform Requirements
621(1)
Application Classification and Marking Policies
621(1)
DSCP-to-UP Mapping
622(2)
Hardware QoS
624(2)
Internal System QoS (Wireless Access Points)
626(2)
Summary
628(1)
Further Reading
629(2)
Chapter 21 Cisco DNA Analytics and Assurance
631(80)
Introduction to Cisco DNA Assurance
631(8)
Context
633(5)
Learning
638(1)
The Architectural Requirements of a Self-Healing Network
639(8)
Instrumentation
640(1)
Distributed On-Device Analytics
641(1)
Telemetry
642(1)
Scalable Storage
643(1)
Analytics Engine
643(1)
Machine Learning
644(1)
Guided Troubleshooting and Remediation
645(1)
Automated Troubleshooting and Remediation
645(2)
Cisco DNA Center Analytics and Assurance
647(63)
Network Data Platform
647(2)
NDP Contextual Correlation and Time Machine
649(1)
NDP Complex Event Processing
650(1)
NDP Time Series Analysis
650(1)
NDP Architecture
650(2)
NDP Operation
652(1)
NDP Extensibility
653(1)
Cisco DNA Assurance
653(2)
Network Health
655(8)
Client Health
663(8)
Application Health
671(17)
Path Trace
688(7)
Sensor-Driven Tests
695(2)
Intelligent Capture
697(7)
Machine Learning
704(6)
Summary
710(1)
Further Reading
710(1)
Chapter 22 Cisco DNA Encrypted Traffic Analytics
711(10)
Encrypted Malware Detection: Defining the Problem
712(2)
Encrypted Malware Detection: Defining the Solution
714(2)
ETA: Use of IDP for Encrypted Malware Detection
714(1)
ETA: Use of SPLT for Encrypted Malware Detection
715(1)
Encrypted Malware Detection: The Solution in Action
716(3)
Encrypted Malware Detection: Putting It All Together
719(1)
Summary
720(1)
Part VI Cisco DNA Evolution
Chapter 23 Cisco DNA Evolution
721(4)
Index 725
Tim Szigeti, CCIE No. 9794, is a principal technical marketing engineer within the Cisco Enterprise Networking Business (ENB) team. In this role, he collaborates with customers, the field, engineering, Cisco IT, and third-party technology partners to drive the development of industry-leading network analytics solutions. In his more than 20 years with Cisco, Tim has authored/co-authored five generations of Cisco QoS Design Guides, four Cisco Press books, an IETF standard (RFC 8325), and multiple patents. Additionally, Tim has been inducted into the Cisco Distinguished Speaker Hall of Fame Elite, representing the Top 1 percent of Cisco speakers of all time.







Outside of Cisco, Tims passion is on-track performance driving; as such, you may at times catch a glimpse of him taking corners at high speeds on the spectacular Sea-to-Sky Highway between his hometown of Vancouver and Whistler, British Columbia.







Additional information on Tim can be found on the Cisco Innovators website in the feature story Cisco Innovators: Tim Szigeti, at https://newsroom.cisco.com/featurecontent?type=webcontent&articleId=1845902.







Dave Zacks is a distinguished technical marketing engineer within the Cisco ENB team, focused on network architectures and fabrics, network hardware and ASIC design, switching, wireless, and the many and diverse technologies under the enterprise networking umbrella. Dave is based in Vancouver, Canada, and has been with Cisco for 19 years.







Prior to his employment with Cisco, Dave traces his roots in computing to 1979, and has been involved in the datacomm and networking industry since 1985.







Dave is a Cisco Live Distinguished Speaker, having scored in the top 10 percent of all speakers at Cisco Live events worldwide as rated by the attendees. In addition, Dave is recognized as one of only a handful of such speakers to earn the Cisco Live Distinguished Speaker Elite designation, an honor awarded to speakers who have achieved Cisco Live Distinguished Speaker status ten times or more (Daves total is currently 15).







In addition to his abiding focus on data communications, Dave maintains a deep and broad interest in many additional topic areas, including (but not limited to) particle and quantum physics, astrophysics, biology, genetics, chemistry, history, mathematics, cryptology, and many other topics. Dave has a special passion for rocketry, aeronautics, space travel, and advanced aircraft and spacecraft design, engineering, and operation.







Additional background on Dave can be reviewed on the Cisco Innovators website in the feature story Cisco Innovators: Dave Zacks, at https://newsroom.cisco.com/featurecontent?type=webcontent&articleId=1851941.







Dr. Matthias Falkner is a distinguished technical marketing engineer within the Cisco ENB team. He currently focuses on the evolution of enterprise and service provider network architectures, and in particular on end-to-end architecture solutions involving virtualization. Matthias is currently helping to drive the Cisco automation strategy for enterprise networks (including DNA Center). Matthias also holds responsibilities in branch virtualization and in the definition of the cloud exchange architecture. Prior to his role within ENB, Matthias was the lead TME architect for the Cisco ASR 1000 Series routers. He has also held positions in product management, and served as a product line manager for the Cisco 10000 Series routers. From 2000 to 2005, Matthias was a consulting systems engineer in the Deutsche Telekom account team with Cisco Germany. Matthias holds a PhD in Systems and Computer engineering from Carleton University, Canada, and an MSc in Operations Research & Information Systems from the London School of Economics and Political Science, UK. His technical interests are in the area of performance characterization of virtualized networks, high availability, and service chaining.







Simone Arena is a principal technical marketing engineer (TME) within the Cisco ENB team and is primarily focused on enterprise network architecture and on all things related to wireless and mobility. Simone is based in Italy and is a Cisco veteran, having joined Cisco in 1999. Throughout the years, Simone has covered multiple roles at Cisco, starting as a software engineer working with Catalyst switching platforms, to consulting system engineer in the field, to TME within different teams (Enterprise Solution Engineering, Wireless Business Unit, and now ENB).







Today Simone is the lead TME architect for DNA Wireless, and his time is split between helping customers and partners design the best solution that fits their needs and engineering and product management, trying to evolve and improve the products and solutions.







Simone is a Distinguished Speaker at Cisco Live and has spoken at Cisco Live events all over the world for several years. He consistently is rated as an excellent speaker by attendees for his deep technical knowledge and ability to impart this information in a meaningful way.







Besides wireless, Simone has two passions: his two daughters, Viola and Anita, and his hometown soccer team, Fiorentina.







In his spare time Simone enjoys listening to music, especially through his new tube amplifier (simply awesome!).







More information on Simone can be found on the Cisco Innovators website in the feature story Cisco Innovators: Simone Arena, at https://newsroom.cisco.com/feature-content?type=webcontent&articleId=1849095.
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