Innovative Capacity Allocations for All-IP Networks: A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem
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Format: | Elektronisch E-Book |
Sprache: | English |
Veröffentlicht: |
Baden-Baden
Nomos Verlagsgesellschaft
2020
|
Ausgabe: | 1st ed |
Schriftenreihe: | Freiburger Studien zur Netzökonomie
v.22 |
Online-Zugang: | HWR01 |
Beschreibung: | Description based on publisher supplied metadata and other sources |
Beschreibung: | 1 Online-Ressource (450 Seiten) |
ISBN: | 9783748902607 |
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245 | 1 | 0 | |a Innovative Capacity Allocations for All-IP Networks |b A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
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490 | 0 | |a Freiburger Studien zur Netzökonomie |v v.22 | |
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505 | 8 | |a Cover -- Acknowledgements -- Papers -- List of Abbreviations -- 1 Introduction -- Part I The Internet Ecosystem: Evolution, Innovation, and Heterogeneity -- 2 The Internet from a Disaggregated Network Economic Perspective -- 2.1 The Economic Side of Layering: Disaggregating the Value Chain -- 2.2 The Technical Side of Layering: Modularity and the OSI and TCP/IP Reference Models -- 2.3 Reconciling the Economic and the Technical Sides of Layering: Towards a Layer Scheme for All-IP Networks -- 3 Internet Evolution: Towards Heterogeneity -- 3.1 From ARPANET to the Internet: A Historical Perspective -- 3.2 From Narrowband Access to the Broadband Internet -- 3.3 Broadband Evolution and the "Fiberization" of Access Networks -- 3.3.1 Broadband Network Evolution: A Dual Lineage -- 3.3.2 Upgrading the PSTN: From First-Generation xDSL to "Future-Proof" FTTH -- 3.3.3 Upgrading CATV Networks: From First-Generation Broadband to RFoG -- 3.3.4 Wireless Broadband Access: Towards 5G -- 3.3.4.1 (Cellular) Mobile Broadband: Fiberization and the Road Towards 5G -- 3.3.4.2 (Fixed) Wireless Broadband Access: WLAN, WiMAX, and Satellite Access -- 3.4 Evolution in the Broadband Access Ecosystem: A Brief Summary -- 4 Network Performance and Quality of Service -- 4.1 Quality of Service and Quality of Experience -- 4.2 Network Performance and Quality of Service -- 4.2.1 Why Location Matters: End-to-End Network Performance and the Role of the Geographical and Virtual Location -- 4.2.2 Delay -- 4.2.3 Jitter -- 4.2.4 Packet Loss Rate -- 4.2.5 Throughput, Bandwidth, and Data Rates -- 4.3 Heterogeneous QoS Requirements and the Evolution of Application Services -- 5 TCP/IP and the Best Effort Service Model -- 5.1 The End-to-End Arguments and the Best Effort Service Model -- 5.2 The Internet Protocol (IP) -- 5.2.1 The IP Packet Header: Beyond Addressing | |
505 | 8 | |a 5.2.2 IP Packet Forwarding and Routing -- 5.3 Some Fundamentals on Intra-Domain Routing -- 5.4 Some Fundamentals on Inter-Domain Routing: The Border Gateway Protocol (BGP) -- 5.5 An Introduction to the Transmission Control Protocol (TCP) -- 5.5.1 Flow Control -- 5.5.2 Congestion Control -- 5.5.3 TCP and Network Performance -- 5.6 An Alternative to TCP: The User Datagram Protocol (UDP) -- 5.7 Transport Layer Protocols: A Brief Summary -- 5.8 The Interconnection Ecosystem -- 5.8.1 Peering, Transit, and the Hierarchical Structure of the Traditional Interconnection Ecosystem -- 5.8.2 Innovations in Interconnection Agreements -- 6 Enhancing Performance in a Best Effort Internet -- 6.1 Over-Provisioning Strategies -- 6.2 Usage Constraints: Ad Hoc Quantity Rationing -- 6.3 Data Compression and Endpoint-Based Upper Layer Mechanisms -- 6.4 Overlay Networks and Location-Based Traffic Management -- 6.4.1 Overlay Networks and Content Delivery Networks -- 6.4.2 Edge Computing and Distributed Cloud Infrastructures -- 6.4.3 Internet Exchange Points, Remote Peering, and Growing Interconnection Diversity -- 6.5 The Limits of Enhancing Performance in a Best Effort Internet -- 7 Active Traffic Management and Enhanced Services on the Internet -- 7.1 Guaranteed Services and Flow-Based QoS: The Integrated Services Architecture and the Resource Reservation Protocol -- 7.2 Predictive Services and Class-Based QoS: The Differentiated Services Architecture -- 7.2.1 Per-Hop Behaviors (PHBs) -- 7.2.2 QoS Differentiations and the DiffServ Architecture: A Closer Look -- 7.3 Multiprotocol Label Switching, MPLS-TE and DS-TE -- 7.3.1 Some MPLS Basics -- 7.3.2 MPLS TE -- 7.3.3 DS-TE -- 7.4 The Generalized DiffServ Architecture -- Part II Congestion, Capacity Allocation, and Pricing in All-IP Networks | |
505 | 8 | |a The evolving demand for heterogeneous QoS levels is the key driver for the introduction of QoS differentiations. As described in Sections 6 and 7, a wide variety of technologically complementary traffic management mechanisms is available to facilitate the implementation of required service differentiations for the Internet. On the one hand, there are some mechanisms located at upper layers of the Internet protocol stack that can provide (scalable) QoS differentiations without requiring modificat -- 8 Scarcity, Network Externalities, and Two-Sided Markets -- 8.1 An Introduction to Scarcity and Economic Efficiency on the Internet -- 8.2 Network Externalities -- 8.2.1 Rivalry, Congestion, and Negative Externalities -- 8.2.2 Direct (Positive) Network Effects -- 8.2.3 Indirect Network Effects and Two-Sided Markets -- 9 Congestion and Pricing in the Internet -- 9.1 A Closer Look at Scarcity and Congestion on the Internet -- 9.1.1 Internet Congestion from an Economic Perspective -- 9.1.2 Algorithm-Based Capacity Rationing by the TCP -- 9.1.3 M/M/1 Queueing Models -- 9.1.4 Bandwidth Partitioning Approaches -- 9.1.5 Preliminary Conclusions on Congestion Modeling in Two-Sided Market Models -- 9.2 Internet Pricing and the Economics of Internet Congestion -- 9.2.1 A Primer on Usage-Independent versus Usage-Dependent Pricing -- 9.2.2 A Brief Survey of Traditional Internet Pricing Models -- 10 Economically Efficient Single-Channel Congestion Pricing -- 10.1 Some Basics on Optimal Congestion Pricing and Capacity Expansions -- 10.2 A Simple Model of Congestion Pricing for a Single-Class Internet -- 11 Towards Optimal Capacity Allocation in all-IP Networks -- 11.1 Paris Metro Pricing and its Implications for Multi-Channel Congestion Pricing -- 11.2 Pure Prioritization and Interclass Externality Pricing | |
505 | 8 | |a 11.2.1 Incentive Compatible Pricing and Optimal Investment: Social Welfare Maximization -- 11.2.2 Incentive Compatible Pricing and Optimal Investment: Profit Maximization -- 11.2.3 Interclass Externality Pricing -- 11.2.4 A Brief Assessment -- 12 Optimal Capacity Allocations in All-IP Networks -- 12.1 The Basic Idea -- 12.2 Capacity Reservation versus Packet Prioritization: On the Provision of Deterministic and Stochastic QoS Guarantees -- 12.3 Interclass Externalities and the Opportunity Costs of Different Types of Network Usage -- 12.4 Opportunity Costs and Interclass Externality Pricing for All-IP Networks -- 12.5 Optimal Capacity Allocations in All-IP Networks: Incentive Compatible Price and QoS Differentiations and Optimal Network Investment -- 12.6 A Brief Summary -- 12.7 An Example of a Price and QoS Differentiation Based on the Introduction of a Deterministic Traffic Class -- 12.8 Model Implications and Limitations: Extensions and Future Research -- 13 Implications for QoS-Based Interconnections and the Interconnection Ecosystem -- 13.1 Legacy Interconnections for an All-IP Ecosystem: A Growing Mismatch? -- 13.2 Challenges and Evolution in the Interconnection Ecosystem -- 13.3 A Summary and (Forward-Looking) Discussion -- Part III Ecosystem Evolution, Optimal Capacity Allocations and Network Neutrality Regulations -- 14 A Primer on Competition and Regulation of the Internet -- 14.1 The Many Facets of Competition in Network Industries -- 14.2 Remedying Market Power Problems: Regulatory Policy versus Active Competition Policy -- 15 A Sector-Specific Regulatory Framework for the Internet -- 15.1 Disaggregated Market Power Regulation for the Internet -- 15.2 Technical Regulations and Consumer Protection Measures -- 15.3 Universal Service Regulations -- 16 Network Neutrality Regulations and Optimal Capacity Allocations for the Internet | |
505 | 8 | |a 16.1 Network Neutrality: Normative Proposition and Regulatory Paradigm -- 16.2 On the Need for a Market-Driven Network Neutrality Concept -- 16.3 Network Neutrality Regulations in the U.S. and the EU -- 16.3.1 Network Neutrality Regulation in the U.S. -- 16.3.2 Network Neutrality Regulation in the EU -- 16.3.3 A Brief Summary of the Regulations in the U.S. and the EU -- 17 A Network Economic Analysis of Network Neutrality Regulations -- 17.1 Brief Overview of the Two-Sided Market Literature on Network Neutrality -- 17.2 A Critical Appraisal of Network Neutrality Regulations from A Network Economic Perspective -- 17.2.1 The Many Facets of Network Neutrality Regulations and Their Impact on Optimal Capacity Allocations and Innovation -- 17.2.2 Regulatory Market Splits and Structural Traffic Regulations -- 17.2.3 Reasonable Traffic Management and the Ban on Paid Prioritization -- 17.2.4 Minimum QoS Regulations and the Dirt Road Argument -- 17.3 Conclusions and Policy Implications -- 18 Summary -- References | |
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contents | Cover -- Acknowledgements -- Papers -- List of Abbreviations -- 1 Introduction -- Part I The Internet Ecosystem: Evolution, Innovation, and Heterogeneity -- 2 The Internet from a Disaggregated Network Economic Perspective -- 2.1 The Economic Side of Layering: Disaggregating the Value Chain -- 2.2 The Technical Side of Layering: Modularity and the OSI and TCP/IP Reference Models -- 2.3 Reconciling the Economic and the Technical Sides of Layering: Towards a Layer Scheme for All-IP Networks -- 3 Internet Evolution: Towards Heterogeneity -- 3.1 From ARPANET to the Internet: A Historical Perspective -- 3.2 From Narrowband Access to the Broadband Internet -- 3.3 Broadband Evolution and the "Fiberization" of Access Networks -- 3.3.1 Broadband Network Evolution: A Dual Lineage -- 3.3.2 Upgrading the PSTN: From First-Generation xDSL to "Future-Proof" FTTH -- 3.3.3 Upgrading CATV Networks: From First-Generation Broadband to RFoG -- 3.3.4 Wireless Broadband Access: Towards 5G -- 3.3.4.1 (Cellular) Mobile Broadband: Fiberization and the Road Towards 5G -- 3.3.4.2 (Fixed) Wireless Broadband Access: WLAN, WiMAX, and Satellite Access -- 3.4 Evolution in the Broadband Access Ecosystem: A Brief Summary -- 4 Network Performance and Quality of Service -- 4.1 Quality of Service and Quality of Experience -- 4.2 Network Performance and Quality of Service -- 4.2.1 Why Location Matters: End-to-End Network Performance and the Role of the Geographical and Virtual Location -- 4.2.2 Delay -- 4.2.3 Jitter -- 4.2.4 Packet Loss Rate -- 4.2.5 Throughput, Bandwidth, and Data Rates -- 4.3 Heterogeneous QoS Requirements and the Evolution of Application Services -- 5 TCP/IP and the Best Effort Service Model -- 5.1 The End-to-End Arguments and the Best Effort Service Model -- 5.2 The Internet Protocol (IP) -- 5.2.1 The IP Packet Header: Beyond Addressing 5.2.2 IP Packet Forwarding and Routing -- 5.3 Some Fundamentals on Intra-Domain Routing -- 5.4 Some Fundamentals on Inter-Domain Routing: The Border Gateway Protocol (BGP) -- 5.5 An Introduction to the Transmission Control Protocol (TCP) -- 5.5.1 Flow Control -- 5.5.2 Congestion Control -- 5.5.3 TCP and Network Performance -- 5.6 An Alternative to TCP: The User Datagram Protocol (UDP) -- 5.7 Transport Layer Protocols: A Brief Summary -- 5.8 The Interconnection Ecosystem -- 5.8.1 Peering, Transit, and the Hierarchical Structure of the Traditional Interconnection Ecosystem -- 5.8.2 Innovations in Interconnection Agreements -- 6 Enhancing Performance in a Best Effort Internet -- 6.1 Over-Provisioning Strategies -- 6.2 Usage Constraints: Ad Hoc Quantity Rationing -- 6.3 Data Compression and Endpoint-Based Upper Layer Mechanisms -- 6.4 Overlay Networks and Location-Based Traffic Management -- 6.4.1 Overlay Networks and Content Delivery Networks -- 6.4.2 Edge Computing and Distributed Cloud Infrastructures -- 6.4.3 Internet Exchange Points, Remote Peering, and Growing Interconnection Diversity -- 6.5 The Limits of Enhancing Performance in a Best Effort Internet -- 7 Active Traffic Management and Enhanced Services on the Internet -- 7.1 Guaranteed Services and Flow-Based QoS: The Integrated Services Architecture and the Resource Reservation Protocol -- 7.2 Predictive Services and Class-Based QoS: The Differentiated Services Architecture -- 7.2.1 Per-Hop Behaviors (PHBs) -- 7.2.2 QoS Differentiations and the DiffServ Architecture: A Closer Look -- 7.3 Multiprotocol Label Switching, MPLS-TE and DS-TE -- 7.3.1 Some MPLS Basics -- 7.3.2 MPLS TE -- 7.3.3 DS-TE -- 7.4 The Generalized DiffServ Architecture -- Part II Congestion, Capacity Allocation, and Pricing in All-IP Networks The evolving demand for heterogeneous QoS levels is the key driver for the introduction of QoS differentiations. As described in Sections 6 and 7, a wide variety of technologically complementary traffic management mechanisms is available to facilitate the implementation of required service differentiations for the Internet. On the one hand, there are some mechanisms located at upper layers of the Internet protocol stack that can provide (scalable) QoS differentiations without requiring modificat -- 8 Scarcity, Network Externalities, and Two-Sided Markets -- 8.1 An Introduction to Scarcity and Economic Efficiency on the Internet -- 8.2 Network Externalities -- 8.2.1 Rivalry, Congestion, and Negative Externalities -- 8.2.2 Direct (Positive) Network Effects -- 8.2.3 Indirect Network Effects and Two-Sided Markets -- 9 Congestion and Pricing in the Internet -- 9.1 A Closer Look at Scarcity and Congestion on the Internet -- 9.1.1 Internet Congestion from an Economic Perspective -- 9.1.2 Algorithm-Based Capacity Rationing by the TCP -- 9.1.3 M/M/1 Queueing Models -- 9.1.4 Bandwidth Partitioning Approaches -- 9.1.5 Preliminary Conclusions on Congestion Modeling in Two-Sided Market Models -- 9.2 Internet Pricing and the Economics of Internet Congestion -- 9.2.1 A Primer on Usage-Independent versus Usage-Dependent Pricing -- 9.2.2 A Brief Survey of Traditional Internet Pricing Models -- 10 Economically Efficient Single-Channel Congestion Pricing -- 10.1 Some Basics on Optimal Congestion Pricing and Capacity Expansions -- 10.2 A Simple Model of Congestion Pricing for a Single-Class Internet -- 11 Towards Optimal Capacity Allocation in all-IP Networks -- 11.1 Paris Metro Pricing and its Implications for Multi-Channel Congestion Pricing -- 11.2 Pure Prioritization and Interclass Externality Pricing 11.2.1 Incentive Compatible Pricing and Optimal Investment: Social Welfare Maximization -- 11.2.2 Incentive Compatible Pricing and Optimal Investment: Profit Maximization -- 11.2.3 Interclass Externality Pricing -- 11.2.4 A Brief Assessment -- 12 Optimal Capacity Allocations in All-IP Networks -- 12.1 The Basic Idea -- 12.2 Capacity Reservation versus Packet Prioritization: On the Provision of Deterministic and Stochastic QoS Guarantees -- 12.3 Interclass Externalities and the Opportunity Costs of Different Types of Network Usage -- 12.4 Opportunity Costs and Interclass Externality Pricing for All-IP Networks -- 12.5 Optimal Capacity Allocations in All-IP Networks: Incentive Compatible Price and QoS Differentiations and Optimal Network Investment -- 12.6 A Brief Summary -- 12.7 An Example of a Price and QoS Differentiation Based on the Introduction of a Deterministic Traffic Class -- 12.8 Model Implications and Limitations: Extensions and Future Research -- 13 Implications for QoS-Based Interconnections and the Interconnection Ecosystem -- 13.1 Legacy Interconnections for an All-IP Ecosystem: A Growing Mismatch? -- 13.2 Challenges and Evolution in the Interconnection Ecosystem -- 13.3 A Summary and (Forward-Looking) Discussion -- Part III Ecosystem Evolution, Optimal Capacity Allocations and Network Neutrality Regulations -- 14 A Primer on Competition and Regulation of the Internet -- 14.1 The Many Facets of Competition in Network Industries -- 14.2 Remedying Market Power Problems: Regulatory Policy versus Active Competition Policy -- 15 A Sector-Specific Regulatory Framework for the Internet -- 15.1 Disaggregated Market Power Regulation for the Internet -- 15.2 Technical Regulations and Consumer Protection Measures -- 15.3 Universal Service Regulations -- 16 Network Neutrality Regulations and Optimal Capacity Allocations for the Internet 16.1 Network Neutrality: Normative Proposition and Regulatory Paradigm -- 16.2 On the Need for a Market-Driven Network Neutrality Concept -- 16.3 Network Neutrality Regulations in the U.S. and the EU -- 16.3.1 Network Neutrality Regulation in the U.S. -- 16.3.2 Network Neutrality Regulation in the EU -- 16.3.3 A Brief Summary of the Regulations in the U.S. and the EU -- 17 A Network Economic Analysis of Network Neutrality Regulations -- 17.1 Brief Overview of the Two-Sided Market Literature on Network Neutrality -- 17.2 A Critical Appraisal of Network Neutrality Regulations from A Network Economic Perspective -- 17.2.1 The Many Facets of Network Neutrality Regulations and Their Impact on Optimal Capacity Allocations and Innovation -- 17.2.2 Regulatory Market Splits and Structural Traffic Regulations -- 17.2.3 Reasonable Traffic Management and the Ban on Paid Prioritization -- 17.2.4 Minimum QoS Regulations and the Dirt Road Argument -- 17.3 Conclusions and Policy Implications -- 18 Summary -- References |
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edition | 1st ed |
format | Electronic eBook |
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"><subfield code="a">Cover -- Acknowledgements -- Papers -- List of Abbreviations -- 1 Introduction -- Part I The Internet Ecosystem: Evolution, Innovation, and Heterogeneity -- 2 The Internet from a Disaggregated Network Economic Perspective -- 2.1 The Economic Side of Layering: Disaggregating the Value Chain -- 2.2 The Technical Side of Layering: Modularity and the OSI and TCP/IP Reference Models -- 2.3 Reconciling the Economic and the Technical Sides of Layering: Towards a Layer Scheme for All-IP Networks -- 3 Internet Evolution: Towards Heterogeneity -- 3.1 From ARPANET to the Internet: A Historical Perspective -- 3.2 From Narrowband Access to the Broadband Internet -- 3.3 Broadband Evolution and the "Fiberization" of Access Networks -- 3.3.1 Broadband Network Evolution: A Dual Lineage -- 3.3.2 Upgrading the PSTN: From First-Generation xDSL to "Future-Proof" FTTH -- 3.3.3 Upgrading CATV Networks: From First-Generation Broadband to RFoG -- 3.3.4 Wireless Broadband Access: Towards 5G -- 3.3.4.1 (Cellular) Mobile Broadband: Fiberization and the Road Towards 5G -- 3.3.4.2 (Fixed) Wireless Broadband Access: WLAN, WiMAX, and Satellite Access -- 3.4 Evolution in the Broadband Access Ecosystem: A Brief Summary -- 4 Network Performance and Quality of Service -- 4.1 Quality of Service and Quality of Experience -- 4.2 Network Performance and Quality of Service -- 4.2.1 Why Location Matters: End-to-End Network Performance and the Role of the Geographical and Virtual Location -- 4.2.2 Delay -- 4.2.3 Jitter -- 4.2.4 Packet Loss Rate -- 4.2.5 Throughput, Bandwidth, and Data Rates -- 4.3 Heterogeneous QoS Requirements and the Evolution of Application Services -- 5 TCP/IP and the Best Effort Service Model -- 5.1 The End-to-End Arguments and the Best Effort Service Model -- 5.2 The Internet Protocol (IP) -- 5.2.1 The IP Packet Header: Beyond Addressing</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">5.2.2 IP Packet Forwarding and Routing -- 5.3 Some 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Remote Peering, and Growing Interconnection Diversity -- 6.5 The Limits of Enhancing Performance in a Best Effort Internet -- 7 Active Traffic Management and Enhanced Services on the Internet -- 7.1 Guaranteed Services and Flow-Based QoS: The Integrated Services Architecture and the Resource Reservation Protocol -- 7.2 Predictive Services and Class-Based QoS: The Differentiated Services Architecture -- 7.2.1 Per-Hop Behaviors (PHBs) -- 7.2.2 QoS Differentiations and the DiffServ Architecture: A Closer Look -- 7.3 Multiprotocol Label Switching, MPLS-TE and DS-TE -- 7.3.1 Some MPLS Basics -- 7.3.2 MPLS TE -- 7.3.3 DS-TE -- 7.4 The Generalized DiffServ Architecture -- Part II Congestion, Capacity Allocation, and Pricing in All-IP Networks</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">The evolving demand for heterogeneous QoS levels is the key driver for the introduction of QoS differentiations. As described in Sections 6 and 7, a wide variety of technologically complementary traffic management mechanisms is available to facilitate the implementation of required service differentiations for the Internet. On the one hand, there are some mechanisms located at upper layers of the Internet protocol stack that can provide (scalable) QoS differentiations without requiring modificat -- 8 Scarcity, Network Externalities, and Two-Sided Markets -- 8.1 An Introduction to Scarcity and Economic Efficiency on the Internet -- 8.2 Network Externalities -- 8.2.1 Rivalry, Congestion, and Negative Externalities -- 8.2.2 Direct (Positive) Network Effects -- 8.2.3 Indirect Network Effects and Two-Sided Markets -- 9 Congestion and Pricing in the Internet -- 9.1 A Closer Look at Scarcity and Congestion on the Internet -- 9.1.1 Internet Congestion from an Economic Perspective -- 9.1.2 Algorithm-Based Capacity Rationing by the TCP -- 9.1.3 M/M/1 Queueing Models -- 9.1.4 Bandwidth Partitioning Approaches -- 9.1.5 Preliminary Conclusions on Congestion Modeling in Two-Sided Market Models -- 9.2 Internet Pricing and the Economics of Internet Congestion -- 9.2.1 A Primer on Usage-Independent versus Usage-Dependent Pricing -- 9.2.2 A Brief Survey of Traditional Internet Pricing Models -- 10 Economically Efficient Single-Channel Congestion Pricing -- 10.1 Some Basics on Optimal Congestion Pricing and Capacity Expansions -- 10.2 A Simple Model of Congestion Pricing for a Single-Class Internet -- 11 Towards Optimal Capacity Allocation in all-IP Networks -- 11.1 Paris Metro Pricing and its Implications for Multi-Channel Congestion Pricing -- 11.2 Pure Prioritization and Interclass Externality Pricing</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">11.2.1 Incentive Compatible Pricing and Optimal Investment: Social Welfare Maximization -- 11.2.2 Incentive Compatible Pricing and Optimal Investment: Profit Maximization -- 11.2.3 Interclass Externality Pricing -- 11.2.4 A Brief Assessment -- 12 Optimal Capacity Allocations in All-IP Networks -- 12.1 The Basic Idea -- 12.2 Capacity Reservation versus Packet Prioritization: On the Provision of Deterministic and Stochastic QoS Guarantees -- 12.3 Interclass Externalities and the Opportunity Costs of Different Types of Network Usage -- 12.4 Opportunity Costs and Interclass Externality Pricing for All-IP Networks -- 12.5 Optimal Capacity Allocations in All-IP Networks: Incentive Compatible Price and QoS Differentiations and Optimal Network Investment -- 12.6 A Brief Summary -- 12.7 An Example of a Price and QoS Differentiation Based on the Introduction of a Deterministic Traffic Class -- 12.8 Model Implications and Limitations: Extensions and Future Research -- 13 Implications for QoS-Based Interconnections and the Interconnection Ecosystem -- 13.1 Legacy Interconnections for an All-IP Ecosystem: A Growing Mismatch? -- 13.2 Challenges and Evolution in the Interconnection Ecosystem -- 13.3 A Summary and (Forward-Looking) Discussion -- Part III Ecosystem Evolution, Optimal Capacity Allocations and Network Neutrality Regulations -- 14 A Primer on Competition and Regulation of the Internet -- 14.1 The Many Facets of Competition in Network Industries -- 14.2 Remedying Market Power Problems: Regulatory Policy versus Active Competition Policy -- 15 A Sector-Specific Regulatory Framework for the Internet -- 15.1 Disaggregated Market Power Regulation for the Internet -- 15.2 Technical Regulations and Consumer Protection Measures -- 15.3 Universal Service Regulations -- 16 Network Neutrality Regulations and Optimal Capacity Allocations for the Internet</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">16.1 Network Neutrality: Normative Proposition and Regulatory Paradigm -- 16.2 On the Need for a Market-Driven Network Neutrality Concept -- 16.3 Network Neutrality Regulations in the U.S. and the EU -- 16.3.1 Network Neutrality Regulation in the U.S. -- 16.3.2 Network Neutrality Regulation in the EU -- 16.3.3 A Brief Summary of the Regulations in the U.S. and the EU -- 17 A Network Economic Analysis of Network Neutrality Regulations -- 17.1 Brief Overview of the Two-Sided Market Literature on Network Neutrality -- 17.2 A Critical Appraisal of Network Neutrality Regulations from A Network Economic Perspective -- 17.2.1 The Many Facets of Network Neutrality Regulations and Their Impact on Optimal Capacity Allocations and Innovation -- 17.2.2 Regulatory Market Splits and Structural Traffic Regulations -- 17.2.3 Reasonable Traffic Management and the Ban on Paid Prioritization -- 17.2.4 Minimum QoS Regulations and the Dirt Road Argument -- 17.3 Conclusions and Policy Implications -- 18 Summary -- References</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Erscheint auch als</subfield><subfield code="n">Druck-Ausgabe</subfield><subfield code="a">Stocker, Volker</subfield><subfield code="t">Innovative Capacity Allocations for All-IP Networks : A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem</subfield><subfield code="d">Baden-Baden : Nomos Verlagsgesellschaft,c2020</subfield><subfield code="z">9783848761371</subfield></datafield><datafield tag="912" ind1=" " ind2=" "><subfield code="a">ZDB-30-PQE</subfield></datafield><datafield tag="999" ind1=" " ind2=" "><subfield code="a">oai:aleph.bib-bvb.de:BVB01-033601120</subfield></datafield><datafield tag="966" ind1="e" ind2=" "><subfield code="u">https://ebookcentral.proquest.com/lib/hwr/detail.action?docID=6405191</subfield><subfield code="l">HWR01</subfield><subfield code="p">ZDB-30-PQE</subfield><subfield code="q">HWR_PDA_PQE</subfield><subfield code="x">Aggregator</subfield><subfield code="3">Volltext</subfield></datafield></record></collection> |
id | DE-604.BV048220374 |
illustrated | Not Illustrated |
index_date | 2024-07-03T19:50:30Z |
indexdate | 2024-07-10T09:32:23Z |
institution | BVB |
isbn | 9783748902607 |
language | English |
oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-033601120 |
oclc_num | 1319622563 |
open_access_boolean | |
owner | DE-2070s |
owner_facet | DE-2070s |
physical | 1 Online-Ressource (450 Seiten) |
psigel | ZDB-30-PQE ZDB-30-PQE HWR_PDA_PQE |
publishDate | 2020 |
publishDateSearch | 2020 |
publishDateSort | 2020 |
publisher | Nomos Verlagsgesellschaft |
record_format | marc |
series2 | Freiburger Studien zur Netzökonomie |
spelling | Stocker, Volker Verfasser aut Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem 1st ed Baden-Baden Nomos Verlagsgesellschaft 2020 ©2020 1 Online-Ressource (450 Seiten) txt rdacontent c rdamedia cr rdacarrier Freiburger Studien zur Netzökonomie v.22 Description based on publisher supplied metadata and other sources Cover -- Acknowledgements -- Papers -- List of Abbreviations -- 1 Introduction -- Part I The Internet Ecosystem: Evolution, Innovation, and Heterogeneity -- 2 The Internet from a Disaggregated Network Economic Perspective -- 2.1 The Economic Side of Layering: Disaggregating the Value Chain -- 2.2 The Technical Side of Layering: Modularity and the OSI and TCP/IP Reference Models -- 2.3 Reconciling the Economic and the Technical Sides of Layering: Towards a Layer Scheme for All-IP Networks -- 3 Internet Evolution: Towards Heterogeneity -- 3.1 From ARPANET to the Internet: A Historical Perspective -- 3.2 From Narrowband Access to the Broadband Internet -- 3.3 Broadband Evolution and the "Fiberization" of Access Networks -- 3.3.1 Broadband Network Evolution: A Dual Lineage -- 3.3.2 Upgrading the PSTN: From First-Generation xDSL to "Future-Proof" FTTH -- 3.3.3 Upgrading CATV Networks: From First-Generation Broadband to RFoG -- 3.3.4 Wireless Broadband Access: Towards 5G -- 3.3.4.1 (Cellular) Mobile Broadband: Fiberization and the Road Towards 5G -- 3.3.4.2 (Fixed) Wireless Broadband Access: WLAN, WiMAX, and Satellite Access -- 3.4 Evolution in the Broadband Access Ecosystem: A Brief Summary -- 4 Network Performance and Quality of Service -- 4.1 Quality of Service and Quality of Experience -- 4.2 Network Performance and Quality of Service -- 4.2.1 Why Location Matters: End-to-End Network Performance and the Role of the Geographical and Virtual Location -- 4.2.2 Delay -- 4.2.3 Jitter -- 4.2.4 Packet Loss Rate -- 4.2.5 Throughput, Bandwidth, and Data Rates -- 4.3 Heterogeneous QoS Requirements and the Evolution of Application Services -- 5 TCP/IP and the Best Effort Service Model -- 5.1 The End-to-End Arguments and the Best Effort Service Model -- 5.2 The Internet Protocol (IP) -- 5.2.1 The IP Packet Header: Beyond Addressing 5.2.2 IP Packet Forwarding and Routing -- 5.3 Some Fundamentals on Intra-Domain Routing -- 5.4 Some Fundamentals on Inter-Domain Routing: The Border Gateway Protocol (BGP) -- 5.5 An Introduction to the Transmission Control Protocol (TCP) -- 5.5.1 Flow Control -- 5.5.2 Congestion Control -- 5.5.3 TCP and Network Performance -- 5.6 An Alternative to TCP: The User Datagram Protocol (UDP) -- 5.7 Transport Layer Protocols: A Brief Summary -- 5.8 The Interconnection Ecosystem -- 5.8.1 Peering, Transit, and the Hierarchical Structure of the Traditional Interconnection Ecosystem -- 5.8.2 Innovations in Interconnection Agreements -- 6 Enhancing Performance in a Best Effort Internet -- 6.1 Over-Provisioning Strategies -- 6.2 Usage Constraints: Ad Hoc Quantity Rationing -- 6.3 Data Compression and Endpoint-Based Upper Layer Mechanisms -- 6.4 Overlay Networks and Location-Based Traffic Management -- 6.4.1 Overlay Networks and Content Delivery Networks -- 6.4.2 Edge Computing and Distributed Cloud Infrastructures -- 6.4.3 Internet Exchange Points, Remote Peering, and Growing Interconnection Diversity -- 6.5 The Limits of Enhancing Performance in a Best Effort Internet -- 7 Active Traffic Management and Enhanced Services on the Internet -- 7.1 Guaranteed Services and Flow-Based QoS: The Integrated Services Architecture and the Resource Reservation Protocol -- 7.2 Predictive Services and Class-Based QoS: The Differentiated Services Architecture -- 7.2.1 Per-Hop Behaviors (PHBs) -- 7.2.2 QoS Differentiations and the DiffServ Architecture: A Closer Look -- 7.3 Multiprotocol Label Switching, MPLS-TE and DS-TE -- 7.3.1 Some MPLS Basics -- 7.3.2 MPLS TE -- 7.3.3 DS-TE -- 7.4 The Generalized DiffServ Architecture -- Part II Congestion, Capacity Allocation, and Pricing in All-IP Networks The evolving demand for heterogeneous QoS levels is the key driver for the introduction of QoS differentiations. As described in Sections 6 and 7, a wide variety of technologically complementary traffic management mechanisms is available to facilitate the implementation of required service differentiations for the Internet. On the one hand, there are some mechanisms located at upper layers of the Internet protocol stack that can provide (scalable) QoS differentiations without requiring modificat -- 8 Scarcity, Network Externalities, and Two-Sided Markets -- 8.1 An Introduction to Scarcity and Economic Efficiency on the Internet -- 8.2 Network Externalities -- 8.2.1 Rivalry, Congestion, and Negative Externalities -- 8.2.2 Direct (Positive) Network Effects -- 8.2.3 Indirect Network Effects and Two-Sided Markets -- 9 Congestion and Pricing in the Internet -- 9.1 A Closer Look at Scarcity and Congestion on the Internet -- 9.1.1 Internet Congestion from an Economic Perspective -- 9.1.2 Algorithm-Based Capacity Rationing by the TCP -- 9.1.3 M/M/1 Queueing Models -- 9.1.4 Bandwidth Partitioning Approaches -- 9.1.5 Preliminary Conclusions on Congestion Modeling in Two-Sided Market Models -- 9.2 Internet Pricing and the Economics of Internet Congestion -- 9.2.1 A Primer on Usage-Independent versus Usage-Dependent Pricing -- 9.2.2 A Brief Survey of Traditional Internet Pricing Models -- 10 Economically Efficient Single-Channel Congestion Pricing -- 10.1 Some Basics on Optimal Congestion Pricing and Capacity Expansions -- 10.2 A Simple Model of Congestion Pricing for a Single-Class Internet -- 11 Towards Optimal Capacity Allocation in all-IP Networks -- 11.1 Paris Metro Pricing and its Implications for Multi-Channel Congestion Pricing -- 11.2 Pure Prioritization and Interclass Externality Pricing 11.2.1 Incentive Compatible Pricing and Optimal Investment: Social Welfare Maximization -- 11.2.2 Incentive Compatible Pricing and Optimal Investment: Profit Maximization -- 11.2.3 Interclass Externality Pricing -- 11.2.4 A Brief Assessment -- 12 Optimal Capacity Allocations in All-IP Networks -- 12.1 The Basic Idea -- 12.2 Capacity Reservation versus Packet Prioritization: On the Provision of Deterministic and Stochastic QoS Guarantees -- 12.3 Interclass Externalities and the Opportunity Costs of Different Types of Network Usage -- 12.4 Opportunity Costs and Interclass Externality Pricing for All-IP Networks -- 12.5 Optimal Capacity Allocations in All-IP Networks: Incentive Compatible Price and QoS Differentiations and Optimal Network Investment -- 12.6 A Brief Summary -- 12.7 An Example of a Price and QoS Differentiation Based on the Introduction of a Deterministic Traffic Class -- 12.8 Model Implications and Limitations: Extensions and Future Research -- 13 Implications for QoS-Based Interconnections and the Interconnection Ecosystem -- 13.1 Legacy Interconnections for an All-IP Ecosystem: A Growing Mismatch? -- 13.2 Challenges and Evolution in the Interconnection Ecosystem -- 13.3 A Summary and (Forward-Looking) Discussion -- Part III Ecosystem Evolution, Optimal Capacity Allocations and Network Neutrality Regulations -- 14 A Primer on Competition and Regulation of the Internet -- 14.1 The Many Facets of Competition in Network Industries -- 14.2 Remedying Market Power Problems: Regulatory Policy versus Active Competition Policy -- 15 A Sector-Specific Regulatory Framework for the Internet -- 15.1 Disaggregated Market Power Regulation for the Internet -- 15.2 Technical Regulations and Consumer Protection Measures -- 15.3 Universal Service Regulations -- 16 Network Neutrality Regulations and Optimal Capacity Allocations for the Internet 16.1 Network Neutrality: Normative Proposition and Regulatory Paradigm -- 16.2 On the Need for a Market-Driven Network Neutrality Concept -- 16.3 Network Neutrality Regulations in the U.S. and the EU -- 16.3.1 Network Neutrality Regulation in the U.S. -- 16.3.2 Network Neutrality Regulation in the EU -- 16.3.3 A Brief Summary of the Regulations in the U.S. and the EU -- 17 A Network Economic Analysis of Network Neutrality Regulations -- 17.1 Brief Overview of the Two-Sided Market Literature on Network Neutrality -- 17.2 A Critical Appraisal of Network Neutrality Regulations from A Network Economic Perspective -- 17.2.1 The Many Facets of Network Neutrality Regulations and Their Impact on Optimal Capacity Allocations and Innovation -- 17.2.2 Regulatory Market Splits and Structural Traffic Regulations -- 17.2.3 Reasonable Traffic Management and the Ban on Paid Prioritization -- 17.2.4 Minimum QoS Regulations and the Dirt Road Argument -- 17.3 Conclusions and Policy Implications -- 18 Summary -- References Erscheint auch als Druck-Ausgabe Stocker, Volker Innovative Capacity Allocations for All-IP Networks : A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem Baden-Baden : Nomos Verlagsgesellschaft,c2020 9783848761371 |
spellingShingle | Stocker, Volker Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem Cover -- Acknowledgements -- Papers -- List of Abbreviations -- 1 Introduction -- Part I The Internet Ecosystem: Evolution, Innovation, and Heterogeneity -- 2 The Internet from a Disaggregated Network Economic Perspective -- 2.1 The Economic Side of Layering: Disaggregating the Value Chain -- 2.2 The Technical Side of Layering: Modularity and the OSI and TCP/IP Reference Models -- 2.3 Reconciling the Economic and the Technical Sides of Layering: Towards a Layer Scheme for All-IP Networks -- 3 Internet Evolution: Towards Heterogeneity -- 3.1 From ARPANET to the Internet: A Historical Perspective -- 3.2 From Narrowband Access to the Broadband Internet -- 3.3 Broadband Evolution and the "Fiberization" of Access Networks -- 3.3.1 Broadband Network Evolution: A Dual Lineage -- 3.3.2 Upgrading the PSTN: From First-Generation xDSL to "Future-Proof" FTTH -- 3.3.3 Upgrading CATV Networks: From First-Generation Broadband to RFoG -- 3.3.4 Wireless Broadband Access: Towards 5G -- 3.3.4.1 (Cellular) Mobile Broadband: Fiberization and the Road Towards 5G -- 3.3.4.2 (Fixed) Wireless Broadband Access: WLAN, WiMAX, and Satellite Access -- 3.4 Evolution in the Broadband Access Ecosystem: A Brief Summary -- 4 Network Performance and Quality of Service -- 4.1 Quality of Service and Quality of Experience -- 4.2 Network Performance and Quality of Service -- 4.2.1 Why Location Matters: End-to-End Network Performance and the Role of the Geographical and Virtual Location -- 4.2.2 Delay -- 4.2.3 Jitter -- 4.2.4 Packet Loss Rate -- 4.2.5 Throughput, Bandwidth, and Data Rates -- 4.3 Heterogeneous QoS Requirements and the Evolution of Application Services -- 5 TCP/IP and the Best Effort Service Model -- 5.1 The End-to-End Arguments and the Best Effort Service Model -- 5.2 The Internet Protocol (IP) -- 5.2.1 The IP Packet Header: Beyond Addressing 5.2.2 IP Packet Forwarding and Routing -- 5.3 Some Fundamentals on Intra-Domain Routing -- 5.4 Some Fundamentals on Inter-Domain Routing: The Border Gateway Protocol (BGP) -- 5.5 An Introduction to the Transmission Control Protocol (TCP) -- 5.5.1 Flow Control -- 5.5.2 Congestion Control -- 5.5.3 TCP and Network Performance -- 5.6 An Alternative to TCP: The User Datagram Protocol (UDP) -- 5.7 Transport Layer Protocols: A Brief Summary -- 5.8 The Interconnection Ecosystem -- 5.8.1 Peering, Transit, and the Hierarchical Structure of the Traditional Interconnection Ecosystem -- 5.8.2 Innovations in Interconnection Agreements -- 6 Enhancing Performance in a Best Effort Internet -- 6.1 Over-Provisioning Strategies -- 6.2 Usage Constraints: Ad Hoc Quantity Rationing -- 6.3 Data Compression and Endpoint-Based Upper Layer Mechanisms -- 6.4 Overlay Networks and Location-Based Traffic Management -- 6.4.1 Overlay Networks and Content Delivery Networks -- 6.4.2 Edge Computing and Distributed Cloud Infrastructures -- 6.4.3 Internet Exchange Points, Remote Peering, and Growing Interconnection Diversity -- 6.5 The Limits of Enhancing Performance in a Best Effort Internet -- 7 Active Traffic Management and Enhanced Services on the Internet -- 7.1 Guaranteed Services and Flow-Based QoS: The Integrated Services Architecture and the Resource Reservation Protocol -- 7.2 Predictive Services and Class-Based QoS: The Differentiated Services Architecture -- 7.2.1 Per-Hop Behaviors (PHBs) -- 7.2.2 QoS Differentiations and the DiffServ Architecture: A Closer Look -- 7.3 Multiprotocol Label Switching, MPLS-TE and DS-TE -- 7.3.1 Some MPLS Basics -- 7.3.2 MPLS TE -- 7.3.3 DS-TE -- 7.4 The Generalized DiffServ Architecture -- Part II Congestion, Capacity Allocation, and Pricing in All-IP Networks The evolving demand for heterogeneous QoS levels is the key driver for the introduction of QoS differentiations. As described in Sections 6 and 7, a wide variety of technologically complementary traffic management mechanisms is available to facilitate the implementation of required service differentiations for the Internet. On the one hand, there are some mechanisms located at upper layers of the Internet protocol stack that can provide (scalable) QoS differentiations without requiring modificat -- 8 Scarcity, Network Externalities, and Two-Sided Markets -- 8.1 An Introduction to Scarcity and Economic Efficiency on the Internet -- 8.2 Network Externalities -- 8.2.1 Rivalry, Congestion, and Negative Externalities -- 8.2.2 Direct (Positive) Network Effects -- 8.2.3 Indirect Network Effects and Two-Sided Markets -- 9 Congestion and Pricing in the Internet -- 9.1 A Closer Look at Scarcity and Congestion on the Internet -- 9.1.1 Internet Congestion from an Economic Perspective -- 9.1.2 Algorithm-Based Capacity Rationing by the TCP -- 9.1.3 M/M/1 Queueing Models -- 9.1.4 Bandwidth Partitioning Approaches -- 9.1.5 Preliminary Conclusions on Congestion Modeling in Two-Sided Market Models -- 9.2 Internet Pricing and the Economics of Internet Congestion -- 9.2.1 A Primer on Usage-Independent versus Usage-Dependent Pricing -- 9.2.2 A Brief Survey of Traditional Internet Pricing Models -- 10 Economically Efficient Single-Channel Congestion Pricing -- 10.1 Some Basics on Optimal Congestion Pricing and Capacity Expansions -- 10.2 A Simple Model of Congestion Pricing for a Single-Class Internet -- 11 Towards Optimal Capacity Allocation in all-IP Networks -- 11.1 Paris Metro Pricing and its Implications for Multi-Channel Congestion Pricing -- 11.2 Pure Prioritization and Interclass Externality Pricing 11.2.1 Incentive Compatible Pricing and Optimal Investment: Social Welfare Maximization -- 11.2.2 Incentive Compatible Pricing and Optimal Investment: Profit Maximization -- 11.2.3 Interclass Externality Pricing -- 11.2.4 A Brief Assessment -- 12 Optimal Capacity Allocations in All-IP Networks -- 12.1 The Basic Idea -- 12.2 Capacity Reservation versus Packet Prioritization: On the Provision of Deterministic and Stochastic QoS Guarantees -- 12.3 Interclass Externalities and the Opportunity Costs of Different Types of Network Usage -- 12.4 Opportunity Costs and Interclass Externality Pricing for All-IP Networks -- 12.5 Optimal Capacity Allocations in All-IP Networks: Incentive Compatible Price and QoS Differentiations and Optimal Network Investment -- 12.6 A Brief Summary -- 12.7 An Example of a Price and QoS Differentiation Based on the Introduction of a Deterministic Traffic Class -- 12.8 Model Implications and Limitations: Extensions and Future Research -- 13 Implications for QoS-Based Interconnections and the Interconnection Ecosystem -- 13.1 Legacy Interconnections for an All-IP Ecosystem: A Growing Mismatch? -- 13.2 Challenges and Evolution in the Interconnection Ecosystem -- 13.3 A Summary and (Forward-Looking) Discussion -- Part III Ecosystem Evolution, Optimal Capacity Allocations and Network Neutrality Regulations -- 14 A Primer on Competition and Regulation of the Internet -- 14.1 The Many Facets of Competition in Network Industries -- 14.2 Remedying Market Power Problems: Regulatory Policy versus Active Competition Policy -- 15 A Sector-Specific Regulatory Framework for the Internet -- 15.1 Disaggregated Market Power Regulation for the Internet -- 15.2 Technical Regulations and Consumer Protection Measures -- 15.3 Universal Service Regulations -- 16 Network Neutrality Regulations and Optimal Capacity Allocations for the Internet 16.1 Network Neutrality: Normative Proposition and Regulatory Paradigm -- 16.2 On the Need for a Market-Driven Network Neutrality Concept -- 16.3 Network Neutrality Regulations in the U.S. and the EU -- 16.3.1 Network Neutrality Regulation in the U.S. -- 16.3.2 Network Neutrality Regulation in the EU -- 16.3.3 A Brief Summary of the Regulations in the U.S. and the EU -- 17 A Network Economic Analysis of Network Neutrality Regulations -- 17.1 Brief Overview of the Two-Sided Market Literature on Network Neutrality -- 17.2 A Critical Appraisal of Network Neutrality Regulations from A Network Economic Perspective -- 17.2.1 The Many Facets of Network Neutrality Regulations and Their Impact on Optimal Capacity Allocations and Innovation -- 17.2.2 Regulatory Market Splits and Structural Traffic Regulations -- 17.2.3 Reasonable Traffic Management and the Ban on Paid Prioritization -- 17.2.4 Minimum QoS Regulations and the Dirt Road Argument -- 17.3 Conclusions and Policy Implications -- 18 Summary -- References |
title | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_auth | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_exact_search | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_exact_search_txtP | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_full | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_fullStr | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_full_unstemmed | Innovative Capacity Allocations for All-IP Networks A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
title_short | Innovative Capacity Allocations for All-IP Networks |
title_sort | innovative capacity allocations for all ip networks a network economic analysis of evolution and competition in the internet ecosystem |
title_sub | A Network Economic Analysis of Evolution and Competition in the Internet Ecosystem |
work_keys_str_mv | AT stockervolker innovativecapacityallocationsforallipnetworksanetworkeconomicanalysisofevolutionandcompetitionintheinternetecosystem |