2. The Vision
Next Generation of Connectivity: “Internet of Things”
Personal Data Cloud on Private Network: “Smart Cloud”
Internet Protocol TV: “IPTV”
Mobile VoIPv6
Forget 4G, this is 10G
This is the Future
3. The Market Potential
Internet Service Personal Cloud
Mobile VoIP IPTV
Providers Network
AT&T: 71.3 million 7.3 million US
~150 million people use
subscribers with a $18 Billion Market subscribers & 45
the cloud in the US
valuation of $240 billion million worldwide
Verizon Wireless: 67.2
Mobile VoIP Market to
million subscribers with Global cloud market in Forecasted to grow 31%
Grow 57% Annually
a valuation of $150 2011 was $40 billion annually through 2014
Through 2014
billion
Sprint: 51.9 million
IPv6 will dramatically Estimated to be $241
subscribers with a Verizon: FiOS TV
improve mobile VoIP billion by 2020
valuation of $22 billion
Comcast: 44.3 million
Tremendous value for
subscribers with a Future of mobile calls SureWest
users
valuation of $112 billion
4. The Technology
IPv4
IPv6
VoIP
Ka-Band Frequency
Communication Satellites
High Altitude
Communication Platforms
5. Internet Protocol
IPv4 IPv6
68.63.222.133 2001:0db8:85a3:0000:0000:8a2e:0370:7334
6. IPv6
Improved performance over the wireless networks
Increased address space
Optimized for high-speed data transfers
Enhanced wireless security features
Optimized for always-on real-time networks
Mandatory IPSec
Enhanced VoIP Qos
8. The Future Internet
• Each person will have their own unique IPv6 address
• New email address: Brennen@Hodge
• No more .com: whatever.whatever
• Everything is connected in the cloud: “Smart Cloud”
• Strattus
9. VoIP
Voice over Internet Protocol
Network Address Translation
(NAT)
Latency
Qos
IPSec
10. Ka-Band Transmission
• C & Ku bands used for
digital TV transmission
• 100 times the capacity of
Ku-band
• In-orbit costs per Gbyte
only a fraction of even the
newest satellites in orbit
• Increased bandwidth
• Spot beam isolation
11. Communication Satellites
One GEO 3 year
LEO, MEO, & ~$400 million for
satellite can development
GEO build & launch
cover the US time
13. The Costs
The total cost to have a communication satellite custom built
and launched is estimated to be $400 million to $450 million,
which includes:
-Construction: $250 million
-Launch: $80 million
-Insurance: More than $40 million
-Ground network and other equipment
14. High Altitude Platforms
Situated in the 300,000 square Cheaper and quicker 1000x the
Stratosphere miles of coverage than satellite bandwidth density
(~20km) (~Texas) development of GEO
15. The Costs
The total cost to have a High Altitude Communication Platform
custom built is estimated to be $500,000 to $10 million.
-Construction: $500,000 to $10 million
-Launch: $10,000-$20,000
16. The Competition
Internet Service Personal Cloud
Mobile VoIP IPTV
Providers Network
AT&T: 71.3 million Mobile VoIP Market to 7.3 million US
~150 million people use
subscribers with a Grow 57% Annually subscribers & 45
the cloud in the US
valuation of $240 billion Through 2014 million worldwide
Verizon Wireless: 67.2
million subscribers with Global cloud market in
Rebel AT&T: U-Verse
a valuation of $150 2011 was $40 billion
billion
Sprint: 51.9 million
Estimated to be $241
subscribers with a Vopium Verizon: FiOS TV
billion by 2020
valuation of $22 billion
Comcast: 44.3 million
This is a brand new
subscribers with a Skype SureWest
market
valuation of $112 billion
17. Plans
Hire key individuals
Establish
Purchase an with knowledge in
relationships with
extremely large block the fields of Develop the next Grow Strattus into
Register Strattus as satellite
of IPv6 address from telecommunications, generation of the largest ISP and
an ISP (Internet manufacturers
ARIN (American satellite technology, communication Mobile provider in
Service Provider) (Space
Registry of Internet IPv6 architecture, platforms the United States
Systems/Loral,
Numbers) VoIP architecture,
Boeing)
and mobile networks
IPv6 implements QoS with the help classification and marking (of IP packets) to ensure a reliable VOIP infrastructure. With the help of classification and marking technique, the network can identify packets or traffic flows and then can assign certain parameters within the packet headers in order to group them. In order to implement QOS marking, IPv6 provides a traffic-class field (8 bits) in the IPv6 header. It also has a 20-bit flow label.