π Wavelength Services - Optical Transport Networks
Ultra-high capacity optical networking for demanding enterprise applications
π Overview
Wavelength services provide dedicated optical capacity over fiber optic networks using Dense Wavelength Division Multiplexing (DWDM) technology. Each wavelength represents a dedicated "light path" with massive bandwidth capacity, ultra-low latency, and complete protocol transparency. Ideal for data center interconnection, high-frequency trading, cloud connectivity, and bandwidth-intensive applications requiring maximum performance.
π Key Benefits
β‘ Ultra-High Capacity
- 10 Gbps to 400 Gbps: Massive bandwidth options
- Protocol Agnostic: Ethernet, Fibre Channel, SONET/SDH support
- Scalable Channels: Multiple wavelengths per fiber
- Future-Proof: Technology roadmap to 800 Gbps and beyond
π― Deterministic Performance
- Sub-Millisecond Latency: Physics-based speed of light performance
- Zero Jitter: Optical transmission eliminates packet variation
- No Packet Loss: Circuit-switched reliability
- Consistent Performance: Dedicated optical capacity
π Maximum Security
- Physical Layer Security: Optical isolation from other traffic
- Tamper Detection: Fiber monitoring for security breaches
- No Shared Infrastructure: Dedicated wavelength assignment
- Encryption Ready: Customer-controlled encryption options
π Geographic Reach
- Metro Connections: City-wide optical networks
- Regional Networks: State and multi-state coverage
- Long-Haul Networks: Cross-country connectivity
- Submarine Cables: International wavelength services
π Wavelength Service Types & Pricing
π Dark Wavelengths
Unlit optical spectrum with customer-provided equipment for maximum control.
| Wavelength | Capacity | Reach | Monthly Cost | Use Case |
|---|---|---|---|---|
| 1310nm | 10-100 Gbps | Metro (0-40km) | $2,000-8,000 | Metro DCI |
| 1550nm | 10-400 Gbps | Regional (40-600km) | $5,000-25,000 | Regional networks |
| CWDM | 8 channels x 10G | Metro multiplexed | $8,000-20,000 | Campus networks |
| DWDM | 40-96 channels | Long-haul optimized | $15,000-100,000 | Carrier networks |
π‘ Lit Wavelength Services
Provider-managed optical services with network equipment included.
| Service Level | Speed Options | Management | Monthly Cost | SLA |
|---|---|---|---|---|
| Basic Lit | 1-10 Gbps | Basic monitoring | $3,000-12,000 | 99.9% |
| Managed Lit | 10-100 Gbps | Full management | $8,000-40,000 | 99.95% |
| Premium Lit | 100-400 Gbps | White-glove service | $20,000-150,000 | 99.99% |
| Ultra Premium | 400+ Gbps | Dedicated team | $50,000-300,000 | 99.999% |
π Wave on Demand
Flexible, software-defined wavelength provisioning with elastic bandwidth.
| Service Type | Bandwidth Range | Provisioning | Cost Model |
|---|---|---|---|
| Elastic Wave | 1 Gbps - 100 Gbps | Software-defined | Usage-based |
| Burst Wave | Baseline + burst | On-demand scaling | Tiered pricing |
| Scheduled Wave | Time-based allocation | Calendar-driven | Time-based |
| Emergency Wave | Instant activation | 24/7 availability | Premium rates |
π οΈ Technical Specifications
π DWDM Technology
- ITU Grid Standards: 50 GHz and 100 GHz channel spacing
- C-Band Spectrum: 1530-1565 nm wavelength range
- L-Band Spectrum: 1565-1625 nm extended range
- Channel Capacity: 40, 80, 96, 120+ channels per fiber
- Amplification: EDFA and Raman amplification
- FEC Coding: Forward Error Correction for reliability
π‘ Interface Options
- 10GBASE-LR: 10 Gbps Ethernet over single-mode fiber
- 10GBASE-ER: 10 Gbps extended reach (40km+)
- 100GBASE-LR4: 100 Gbps Ethernet long reach
- OTU2/OTU4: Optical Transport Unit standards
- STM-64/OC-192: 10 Gbps SONET/SDH
- 8/16 Gbps FC: Fibre Channel protocols
- Custom Rates: Non-standard bandwidth options
π§ Performance Metrics
- Latency: 5 microseconds per kilometer (physics limit)
- Bit Error Rate: <10^-12 (effectively error-free)
- Availability: 99.99%+ with proper redundancy
- Optical Power: Optimized for maximum reach
- Dispersion Management: Chromatic and polarization compensation
π‘οΈ Protection Schemes
- 1+1 Protection: Dedicated backup path
- 1:1 Protection: Shared backup resources
- Ring Protection: Bi-directional ring architectures
- Mesh Restoration: Dynamic rerouting capability
- Diverse Routing: Physically separate fiber paths
ποΈ Network Applications
π’ Data Center Interconnection (DCI)
Connect enterprise data centers with ultra-high bandwidth optical links.
Use Cases:
- Disaster Recovery: Real-time data replication
- Load Balancing: Traffic distribution across sites
- Storage Networking: SAN extension over distance
- Cloud Bursting: Seamless capacity expansion
- Database Clustering: Distributed database architectures
Performance Requirements:
- Ultra-Low Latency: <1ms for metro connections
- High Bandwidth: 10-400 Gbps capacity
- Protocol Transparency: Support for all protocols
- 99.99% Availability: Mission-critical uptime
π° Financial Services & Trading
Ultra-low latency connections for high-frequency trading and financial applications.
Applications:
- Algorithmic Trading: Microsecond-sensitive transactions
- Market Data Distribution: Real-time financial feeds
- Arbitrage Networks: Cross-market trading
- Risk Management: Real-time portfolio monitoring
- Regulatory Reporting: Compliance data transmission
Critical Requirements:
- Deterministic Latency: Predictable transmission times
- Jitter-Free: Consistent packet arrival times
- Tamper Detection: Security monitoring
- Audit Trails: Complete transmission logging
π¬ Media & Entertainment
High-bandwidth connections for content creation, distribution, and broadcast.
Applications:
- Live Broadcasting: Uncompressed video transmission
- Content Distribution: Movie and TV show delivery
- Post-Production: Collaborative video editing
- Sports Broadcasting: Multi-camera live events
- Streaming Services: Content delivery networks
Technical Needs:
- Massive Bandwidth: Uncompressed 4K/8K video
- Zero Packet Loss: Broadcast-quality reliability
- Protocol Support: SDI, SMPTE 2110, IP video
- Real-Time: Live production requirements
π¬ Research & Education
Support for scientific computing, research networks, and academic collaboration.
Applications:
- High-Performance Computing: Supercomputer interconnection
- Research Collaboration: Global scientific partnerships
- Big Data Transfer: Large dataset sharing
- Telescope Networks: Astronomical data collection
- Academic Networks: Multi-campus connectivity
Requirements:
- Burst Capacity: Temporary high-bandwidth needs
- International Reach: Global research partnerships
- Cost Efficiency: Educational pricing models
- Flexibility: Varying bandwidth requirements
π Deployment Models
ποΈ Metro Wavelengths
Short-distance optical connections within metropolitan areas.
Characteristics:
- Distance: 0-40 kilometers
- Latency: <200 microseconds
- Cost: Lower due to shorter distance
- Applications: Local data centers, campus networks
π Regional Wavelengths
Medium-distance connections between cities and regions.
Characteristics:
- Distance: 40-600 kilometers
- Latency: 200 microseconds to 3 milliseconds
- Cost: Moderate distance-based pricing
- Applications: Regional data centers, state networks
π Long-Haul Wavelengths
Cross-country and international optical connections.
Characteristics:
- Distance: 600+ kilometers
- Latency: 3+ milliseconds
- Cost: Higher due to infrastructure requirements
- Applications: National networks, international links
π Submarine Wavelengths
Undersea optical cables for international connectivity.
Characteristics:
- Distance: Thousands of kilometers
- Latency: Geography-dependent
- Cost: Premium international pricing
- Applications: Global enterprise networks, content delivery
π° Cost Factors & Optimization
π Pricing Variables
- Distance: Primary cost factor for wavelength services
- Capacity: Higher speeds command premium pricing
- Term Commitment: Longer terms reduce monthly costs
- Route Diversity: Redundant paths increase costs
- Equipment Options: Lit vs. dark wavelength pricing
π‘ Cost Optimization Strategies
- Right-Size Capacity: Avoid over-provisioning bandwidth
- Term Negotiations: Multi-year contracts for discounts
- Shared Wavelengths: Multiple services on single wavelength
- Hub Architecture: Reduce total wavelength count
- Timing Flexibility: Off-peak installation scheduling
π ROI Considerations
- Application Performance: Improved user experience
- Operational Efficiency: Reduced latency and improved reliability
- Future-Proofing: Wavelength capacity growth potential
- Risk Mitigation: Reduced downtime and data loss
- Competitive Advantage: Performance differentiation
π§ Implementation Process
1. Network Assessment
- Bandwidth Analysis: Current and projected capacity needs
- Latency Requirements: Application performance requirements
- Route Analysis: Optimal path determination
- Redundancy Planning: Protection and diversity needs
2. Wavelength Design
- Capacity Planning: Right-sizing wavelength capacity
- Route Engineering: Path optimization and protection
- Equipment Selection: Customer vs. provider equipment
- Interface Specifications: Protocol and connector types
3. Installation & Testing
- Fiber Construction: If new fiber routes required
- Equipment Installation: Optical networking equipment
- Circuit Testing: End-to-end performance verification
- Acceptance Testing: Customer validation procedures
4. Service Delivery
- Service Turn-Up: Activation and initial configuration
- Performance Validation: SLA compliance verification
- Documentation: Network diagrams and procedures
- Training: Customer technical team education
π Wavelength Service Consultation
π§ Expert Consultation
- Toll-Free: (888) 765-8301
- Email: wavelength@solveforce.com
- Assessment: Free network assessment
- Quote Portal: Request Wavelength Quote
π Information Needed for Assessment
- Locations: Source and destination sites
- Bandwidth Requirements: Current and projected needs
- Application Types: Critical performance applications
- Latency Requirements: Maximum acceptable latency
- Redundancy Needs: Protection and diversity requirements
- Timeline: Desired service delivery date
β±οΈ Typical Implementation Timeline
- Assessment: 1-2 weeks
- Design & Engineering: 2-4 weeks
- Fiber Construction: 8-20 weeks (if new fiber needed)
- Equipment Installation: 2-4 weeks
- Testing & Turn-Up: 1-2 weeks
- Total: 14-32 weeks depending on complexity
π Why Choose SolveForce for Wavelength Services?
β
Carrier Neutral: Access to all major optical providers
β
Technical Expertise: Certified optical networking engineers
β
Global Reach: Worldwide wavelength connectivity options
β
Cost Optimization: Competitive pricing negotiation
β
Project Management: End-to-end implementation support
β
Future Planning: Scalable optical infrastructure design
Need ultra-high performance optical connectivity? Contact SolveForce at (888) 765-8301 for expert wavelength consultation and competitive pricing.
Wavelength Excellence at Light Speed β SolveForce Illuminates Performance.