S.
No. Generic Requirements
1 General requirements
1.1 Chassis based & modular architecture with multicore processor for scalability and should be a single box configuration for ease of management.
1.2 Should support complete Firewall, IPS features
1.3 Should have integrated USB port/flash to provide console and storage for configuration/image
2. Hardware and interface requirements
2.2 Routers should have at least 2 open slots for LAN/ WAN modules
2.3 Routers should support large selective of modular LAN and WAN connectivity options including Gigabit Ethernet and Fast Ethernet, T1/E1, V.35/G.703 Serial, 3G Wireless(Both HSPA and CDMA) interface modules.
2.4 Should have extensive debugging capabilities to assist in hardware for problem resolution.
• Support for monitoring of Traffic flows for Network planning and Security purposes
• Display of input and output error stats on all interfaces
• Display of Dynamic ARP table
• Display of physical layer line status signals like DCD, DSR, DTR, RTS, CTS on all serial interfaces
• Trace-route, Ping and extended Ping
2.5 Should have hardware assisted VPN acceleration.
2.6 Router should have minimum 2 nos. of V.35 serial ports from day 1 2.7 Router should have minimum 4 nos. of 10/100 Ethernet ports from day 1
2.8 The Router should have support for WAN optimization in software level. If this feature can’t be provided within router software level, external hardware must be proposed to cater the requirement
2.9 The Router should support Voice DSP's 2.10
3 Performance Requirements
3.1 The router should have a minimum performance of 280 Kpps
3.2 The router should have a minimum forwarding performance of 15 Mbps with IPSec, Firewall, Content Filtering, IPS functionality, Routing & Multicast enabled
3.3 Should support other IP Services like GRE tunnelling, ACLs, IPSEC VPNs, Firewalling, NAT services
4 Quality of Service (QoS) requirements
4.1 Routers should support Class-based queuing
4.2 Routers should support marking, policing and shaping
4.3 Routers should support Voice traffic optimization with features like WRED, H-QoS, & RSVP
5 Routingprotocol support
5.1 Routers should support:
5.2 IPv4, Ipv6, VRRP, Static Routes, RIPv1, RIPv2, OSPFv2, OSPFv3, IS-SI, BGP4, MBGP, BFD, Policy based routing, Ipv4 and Ipv6 tunneling
6. Ipv4 Multicast features
6.1 IGMP v1/v2/v3, PIM-DM, PIM-SM, Source Specific Multicast (SSM)
7. System Management and Administration
7.1 Routers should support Configuration rollback
7.2 Support for accounting of traffic flows for Network planning and Security purposes 7.3 Should support extensive support for SLA monitoring for metrics like delay,
latency, jitter, packet loss, RTP-Based VoIP traffic, CRTP
7.4 Routers should support Software upgrades
7.5 Routers should support SNMPv2 and SNMPv3
8 Security features
8.1 Routers should support AAA using RADIUS or TACACS
8.2 Routers should support Packet Filters like: Standard ACL, Extended ACL, ACL that can match arbitrary bits of packet bits of a packet at an arbitrary depth in the packet header and payload
“Certified that all the above features are complied”
Table 15: Specification for Equipment Rack 42 u Racks 600mm * 1000mm
42 u Racks 600mm * 1000mm Racks Size: 42u
Width * Depth: 600mm * 1000mm
Powder quoted steel Body with front door of glass. Completely covered & have security locks
All covers can be removed & operatable from all sides Uninhibited access to all mounting points inside the racks Proper ventilated with four fans
Power cable management
Two Power strips having 10 5A/15A sockets each
Adjustable shelf & accessories to accommodate equipment’s Fitted with Copper strip for earthing the equipments. One IP Power strip with min 5 sockets
The products offered must be of high quality and manufactured by nationally/internationally reputed manufacturer and ISO 9001 (Services and Manufacturing) and preferably ISO 14001
Table 16 Specification for Base Station:
The system should support OFDM (Orthogonal Frequency Division Multiplexing) for Near-Line of Sight (NLOS) application.
Base station should have minimum throughput of 10 mbps at 10 KM distance with 90 degree sector antenna and clear LOS.
8.6 Routers should support DES, 3DES, AES encryption
8.7 Routers should support MD5 authentication
8.8 Routers should support generation of SNMP traps and syslog 8.9 Routers should support Network address translation (NAT) 8.10 Router should be minimum common criteria EAL4+ certified
9 Built-in trouble shooting
9.1 Extensive debugs on all protocols
9.2 Shall support Secure Shell for secure connectivity
9.3 Should have to support Out of band management through Console and an external
modem for remote management 9.4 Pre-planned scheduled Reboot Facility
Transmit Power (Tx) of base station should be min. 23 dBm.
Range of minimum 25 km radius in point to multipoint mode at minimum 2 Mbps bandwidth at any point.
Should support following services: Videoconferencing Voice over IP Internet Browsing VPN Web Casting Messaging Video Streaming
Should support the following protocols:
Static Routes, RIPv2, IPV4, STP, UDP, ICMP, Telnet, HTTP, FTP, SNMP Security features support:
Data Encryption, WEP (64/128 bit) WPA/WPA-2, AES, IPSEC, MAC Based Authentication RF frequency should be in unlicensed band however their may be requirement of licensed band equipment at five to ten locations.
Data interface should be Ethernet. Should support routing and bridging.
NMS of wireless equipment should also have monitoring in terms of MRTG like tools for traffic utilization and general RF link parameters such as RSSI, SNR etc.
Wireless equipment should have QOS features with MIR and CIR inbuilt. The system should support WiMAX (802.16)-like QoS data classification.
Wireless equipment should be IPv6 compliant by year 2008. Channel bandwidth should be adjustable to 5, 10, and 20 MHz. Equipment should be SNMP enabled.
Desirable features are support for Dynamic Adaptive Modulation, Variable channel bandwidth, GUI based configuration and NMS features.
NMS of wireless equipment should be ‘one point of management’. The NMS should also provide remote maintenance (SW upgrades, etc) of the radio units.
Equipment should be SNMP enabled.
The system should support fully automatic configuration of the CPEs, including the QoS, once they acquire an RF link to the Base station.
The system should have self-interference prevention (preferably GPS synchronization), between different Base Stations and between co-locating sectors within a base station.
Antenna for Base Station
Gain 17.0 dBi
VSWR ≤ 1.5 : 1
Front to back ratio ≥ 22 dB
Impedance 50 Ω
H-plane half power beam width 900
E-plane half power beam width 70
Connector N-Female
Half power beam width ≤ 8º
Ground Direct Ground
Power handling capacity Minimum 5 Watts
Antenna should be suitable for outdoor applications with protection against surge, wind etc and should be supplied with all accessories
The base station should be outdoor type along with surge protection and gas discharge devices with cables and all accessories.
The design of a typical 3 meter Antenna section and installation guideline drawings are given below:
Table 16 Specification forWireless Access Point/CPE (Customer Premises Equipment) Receive sensitivity of the equipment should be min. -85 dBm at a throughput of 10 Mbps.
Should support following services: Videoconferencing Voice over IP Internet Browsing VPN Web Casting Messaging Video Streaming
Should support the following protocols:
Static Routes, RIPv2, IPV4, STP, UDP, ICMP, Telnet, HTTP, FTP, SNMP Security features required:
Data Encryption, WEP (64/128 bit) WPA/WPA-2, AES, IPSEC, MAC Based Authentication The CPE required are to support Point to Point, Point to Multi Point network.
Integrated antenna in CPE with option for connecting external antenna.
The CPE of the equipment should preferably provide two data Ethernet interfaces and an option for repeating the signal to second hop (CPE acting as a repeater).
The CPE will be outdoor type unit withsurge protection and gas discharge devices with cables, all accessories.
Table 17: Outdoor Antenna 24dBi
Gain Minimum 24.0 dBi
VSWR ≤1.5 : 1
3 dB Beam width Max 10° x 14°
Front to back ratio > 24 dB
Polarization Vertical or Horizontal
Power Handling capacity Minimum 5 Watts
Impedance 50 Ω
Ground Direct Ground
Connector N-Female
Table 18: Specification for MCU (also refer to video conferencing in scope of work)
Feature Specifications Complied Yes/No
Make : Model:
Capacity
Should have the ability to connect at least 10 video sites and 10 audio sites from day one in a
single MCU without cascading.
Video quality performance
All video ports must support 30 fps of 720p resolution from day one. The same MCU should be upgradable to support minimum 80 NHD ports
without Cascading
Should support H.264 even in Continuous
presence
Bandwidth per
port 4Mbps
Video
Standards Should support H.263, H.264 video algorithms
Video Resolution
Should support video resolution from QCIF to
1080p without losing ports
Audio Standards
Along with the Support for basic algorithms like G.711 and G.722.1 the MCU should also support wideband Audio protocols like MPEG 4 AAC - LC
and/or MPEG 4 AAC – LD
IP protocols
The MCU should support H.323 and SIP protocols Must have support for IPV6.
Transcoding &
Rate Matching
The MCU should support transcoding of different
Audio/video Protocols.
MCU should be able to combine HD and SD in the
same conference
The MCU should have an video encode resource
per participant
Dual Video
The MCU should support H.239 for sending and receiving dual video streams (Presenter +
Presentation) Conference Features
The MCU should have built-in provision for
conference scheduling and reservation
The MCU should allow active speaker selection
using an endpoint's remote control
The MCU should allow Far End Camera Control Tunnelling using Endpoint remote control or from
the Web.
The layout from MCU must utilize the screen space efficiently and every video pane in a
multiparty layout should have thin borders.
Network Resilience
Should support intelligent down speeding, packet
pacing and packet loss concealment
Should support H.323 Alternate Gatekeeper
Financial BID
1. Annual MPLS Costing : for connecting vertical Pops i.e SHQ, DHQ and BHQ (approx. 360 nos.):
Sl.
No. Speed for 1:1
Approx. Quantity Amount per Annum (In Rs.) Tax (In Rs.) Total Amount (In Rs.) 1 2 Mbps 130 2 4 Mbps 130 3 8 Mbps 50 4 16 Mbps 50 Gross 1 - Please not that above costing includes local lead cost, hardware rent(such as modem, transmission equipment), OFC laying cost, wireless equipment, its maintenance and management etc. - The total cost for part 1 will be calculated by multiplying the above quantity with the price and finding the gross amount. - In casein future if bandwidth require is in between the above bandwidth then the price will be derived in following way: example price of 6 Mbps = price of 4 Mbps +( (price of 8Mbps-price of 4Mbps)X (6-4)/(8-4) - However service provider can quote their price for bandwidth not figuring in above list 2. Point to point leased line for horizontal circuit (mostly in the SHQ, DHQ or BHQ ) (either on Copper ) Sl. No. Speed Distance Qty percentage below TRAI tariff Tax in % Total 1 2 Mbps 0-20 Km 2000 2 2 Mbps >20 Km 500 Gross 2 - Cost includes all local leads and main circuit, modems, transmission equipment etc required to terminate the link on the router as well as its maintenance and management - Cost of 4 Mbps, 8 Mbps, 12 Mbps and 16 Mbps, 34 Mbps will be calculated by multiplying to 2 Mbps cost by coefficient 1.8, 3.5, 3.9, 4.6 and 6.5. - For calculating the cost, 2000 links ranging from 0 to 20 Km, 500 links > 20 Km will be considered. The tariff for 20 Km will be considered for serial 1 and 150 Km for serial 2. - In actual scenario for calculating the cost of bandwidth, first on the basis of distance the bracket will be identified and then the %quoted for that bracket will be applicable on TRAI tariff for the actual distance. - The distance between two locations will be calculated on the basis of x, y coordinate of the two locations. - MPSEDC will do rate contract for this item allowing with multiple operator to provide horizontal connect. - Please enclose current TRAI Rate list
3. Alternate solution (like 3G, Wimax, BB VPN, VSAT KU Band, EVDO router) Sl No Item description One time cost
Tax Total Annual
recurring Tax Total 1 3G 2 BB VPN 3 EVDO 4 wimax 5 VSAT Ku Band
Separate sheet may be given for different speed
A. Selection of bidder for Vertical connectivity:
H1 = 70% of technical marks(T1) + 30% of financial (F1) Where F1 = (100- G1/1,00,00,000) Where G1= Gross1+Gross 4 B. Selection of Bidder for Horizontal Connectivity:
H2 = 70% of technical marks(T1) + 30% of financial (F2) Where F2 = (100- G2/1,00,00,000) Where G2= Gross2+Gross 5
Other bidders can be selected if they agree to work on rate of H2 bidders rate
C. Rate contract for item in serial 3 above will be done
Note:
MPSEDC reserve the right to award contract for part quantity.
The Network Monitoring Centre at Bhopal is currently located at 214, Zone - I, M P Nagar Bhopal. This location is likely to be shifted to 47 A, Arera Hills Bhopal. In case the NMC is shifted before commissioning of the Circuits, the successful bidder will have to provide connectivity accordingly.
In case NMC is shifted after commissioning at present location, the successful bidder will have to shift the connectivity without causing any significant downtime. The successful bidder may also be required to shift any of the other locations of connectivity in future. For this purpose rates have been asked for in the financial bid, for which the bidder is required to quote separately.
Signature of the Bidder