GUTP and IEEE1888 for Smart Facility Systems using - Test-beds

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Transcript GUTP and IEEE1888 for Smart Facility Systems using - Test-beds

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GUTP and IEEE1888 for Smart Facility Systems
using Internet Architecture Framework
Hiroshi Esaki, Ph.D.
Professor, The University of Tokyo
Director, Green University of Tokyo Project (GUTP)
Director, Japan Data Center Consortium
Chair, IPv6 Ready Logo Program, IPv6 Forum
Executive Director, IPv6 Promotion Council of Japan
Chair, Task Force on IPv4 Address Exhaustion
Director, WIDE Project
Conclusion; “6” lessons and strategy
1. Things are ready to be connected (via IEEE1888)
– Not only network, but also database /applications
2. Improvement of RoI by “wireless” technology
3. Strategic invitation of ”stakeholders”, to share the
power of open system
4. Autonomous delivery of new/innovative
applications by “transparent” open platform
5. You DO care IP version, but most people does NOT.
6. Controlling things by computer networks, for
improvement of efficiency, rather than saving
energy
What we will achieve, as a result
• Maintain (and improve) the performance of
social and industrial activities, with less energy
consumption.
1. The first step is maintain the same social and
industrial activities with the 15% (electrical)
energy saving.
2. The long-run result after 5 years is to build the
most high quality and high performance society
and industry with lower power consumption.
What is meant, comparing with
driving a car at highway ?
1. Legacy offices and campuses
 Do not have speed meter, while asking 15% reduce
2. Offices introduced the first step measure
 Providing the dash-board displaying the speed meter
to the driver
3. Advanced Offices introduced the second measure
 Providing other information, e.g., fuel efficiency or
accessories status, to the driver with multiple screens.
 will lead to faster driving with the same (or
less) energy consumption
Design of “Smart” City
人(Human-being)
都市(City)
Cloud Computing
脳+頭骸骨(Brain)
Data Center
頭骸骨(Skull),
血管(Blood vessels)
Servers, switches
神経(Brain nerves)
Internet
神経(Nerves)
各器官(Organs)
骨等(Bone)
センシング器官(Sensor)
筋肉(Muscle)
Facilities (i.e., Things)
Building(構造体)
Sensor
Actuator
“100 meter sprint”
Usain Bolt,
Jamaica
Small
difference on
Born inassets/components,
1986.
Height = 196cm
But large difference on
Weight = 95kg
“efficiency”
9.58 seconds
△ 14.3%
+ 10%
△ ∞ (500%?)
Hiroshi Esaki, Japan
Born in 1963.
Height = 168cm
Weight = 105kg
∞ seconds (50 sec?)
Questions and Challenges
1.
You may stop to your challenge by the pictures
2.
What if Esaki’s leg will be replaced by machine?

3.

Introduction of Innovative or revolutional technology

Can you provide appropriate interface ?

Can you change the rules/regulations ?
When technology and/or rule change(s),
Mr.Usain Bolt will be of “Galapagos”
Shaping up your body will lead to open up new world
and new activities
4.
History of GUTP
(Green University of Tokyo)
&
IEEE1888 deployment
Building Automation WG
in 2003 at
in 2005
Collaboration
with Tokyo Gov.
since 2004
Established FNIC in2006
(Facility Network Interop)
Since 2005
(7th at Kyoto)
In 2008
DUMBO2006
with AIT
KU+KUS with MIC+JGN2
IIT Hyderabad
With IMD
FIAP in 2009
(Live E! architecture)
IEEE 1888
in 2010
Beijing Olympic
In 2008
China-Japan Green IT
Project funded by MIC
in 2009
with NIST@USA
B2G in SmartGrid
• 2003
Activates since 2003
– Building Automation WG at IPv6 Promotion Council
– Talk with ASHREA BACnet regarding IPv6 introduction
• 2004
– Talked with Tokyo Metropolitan Office
• 2006
– Security framework focusing on facility networks (RFC4430)
– Established FNIC (Facility Network Interoperability Consortium)
• 2008
–
–
–
–
Beijing Olympic Game Lights Control
Green University of Tokyo Project
SBC (Smart Building Consortium) for Japanese standard
Start to talk with NIST and BACnet regarding B2G (Building-to-Grid)
• 2010 : Kicked off P-IEEE1888 (UGCCnet)
• 2011 : Approved as IEEE1888, Campus-wide & Multi-campus deployment
• 2003
Activates since 2003
– Building Automation WG at IPv6 Promotion Council
– Talk with ASHREA BACnet regarding IPv6 introduction
• 2004
– Talked with Tokyo Metropolitan Office
• 2006
– Security framework focusing on facility networks (RFC4430)
– Established FNIC (Facility Network Interoperability Consortium)
• 2008
–
–
–
–
Beijing Olympic Game Lights Control
Established Green University of Tokyo Project
SBC (Smart Building Consortium) for Japanese standard
Started to talk with NIST and BACnet regarding B2G (Building-to-Grid)
• 2010 : Kicked off P-IEEE1888 (UGCCnet)
• 2011 : Approved as IEEE1888, Campus-wide & Multi-campus deployment
Facility management
IPv6 based P2P control of facilities
- Status of elevators, AC or ventilators, movement of guests in the museum, temperature of rooms, surveillance
camera images may be monitored in a facility management center.
- Shared use of networks among IP phone, Internet access and facility management.
- Cost reduction
- Where experts’ analysis of data on the number of guests in respective rooms and temperatures are available,
it is possible to minimize energy consumption.
Toward
the Green (or Eco) City
(1) Tokyo Metropolitan HQ Buildings
Analysis of data by experts
Meteorological data
Secure
Surveillance
Has decides
to Introduce
camera
access
Energy consumption
control
Obtain
Based “OPEN” Facility Controlling
analysis
TV phone
Entry sensor IPv6
facility
vendor A
System in 2006.
data
Thermometers
Vendor B
C
(2) Replacing ControlIPv6
System inVendor
Old
Facilities,
Internet
Centralized control/
Museum
Facility management center
Which
Use Inefficient “Engine”
Remote maintenance (i.e., poor
Minimize energy usage
fuel efficiency) Consuming
a Lot of
theater
based on analysis of
Theater
museum
facility data Unnecessary Energy.
Total energy
600M USD per year for Tokyo
!!!
fluctuations
Building facility
management
system
Status of
elevators
Rationalizing day-to-day
management of facilities using
remote maintenance
m2m-x
access control server
Weather data
Number of
guests
Centralized facility
management system14
• 2003
Activates since 2003
– Building Automation WG at IPv6 Promotion Council
– Talk with ASHREA BACnet regarding IPv6 introduction
• 2004
– Talked with Tokyo Metropolitan Office
• 2006
– Security framework focusing on facility networks (RFC4430)
– Established FNIC (Facility Network Interoperability Consortium)
• 2008
–
–
–
–
Beijing Olympic Game Lights Control
Established Green University of Tokyo Project
SBC (Smart Building Consortium) for Japanese standard
Started to talk with NIST and BACnet regarding B2G (Building-to-Grid)
• 2010 : Kicked off P-IEEE1888 (UGCCnet)
• 2011 : Approved as IEEE1888, Campus-wide & Multi-campus deployment
Beijing Olympic 2008 Main Stadium District
Lighting System Control by IPv6 Facility Manage & Control
Operated by Panasonic Electric Works
Proved;
IP works for mission critical
environment
Lightening Management & Control
- Using IPv6 based Facility
Networking
- Area Management System, i.e.,
not single facility but multiple
facilities
- 1.4kmx2.4km with 18,000 lights
- 340 IPv6-based control nodes
- 10% Energy saving
• 2003
Activates since 2003
– Building Automation WG at IPv6 Promotion Council
– Talk with ASHREA BACnet regarding IPv6 introduction
• 2004
– Talk with Tokyo Metropolitan Office
• 2006
– Security framework focusing on facility networks (RFC4430)
– Established FNIC (Facility Network Interoperability Consortium)
• 2008
–
–
–
–
Beijing Olympic Game Lights Control
Green University of Tokyo Project
SBC (Smart Building Consortium) for Japanese standard
Started to talk with NIST and BACnet regarding B2G (Building-to-Grid)
• 2010 : Kicked off P-IEEE1888 (UGCCnet)
• 2011 : Approved as IEEE1888, Campus-wide & Multi-campus deployment
SGIP Organization leaded by NIST
SGIP Officers
Governing Board
NIST
SGIP Administrator
Test & Certification
Committee (SGTCC)
Architecture
Committee
(SGAC)
Cyber Security
Working Group
(CSWG)
B2G;
Building 2 Grid,
PAP 4
PAP 5
PAP …
i.e., smart
Priority Action Plan Teams building
PAP 1
PAP 2
PAP 3
Standing Committees &
Working Groups
Program Management
Office
(PMO)
Coordination Functions
H2G
TnD
B2G
I2G
PEV2G
BnP
Domain Expert Working Groups
SGIP Membership
• 2003
Activates since 2003
– Building Automation WG at IPv6 Promotion Council
– Talk with ASHREA BACnet regarding IPv6 introduction
• 2004
– Talk with Tokyo Metropolitan Office
• 2006
– Security framework focusing on facility networks (RFC4430)
– Established FNIC (Facility Network Interoperability Consortium)
• 2008
–
–
–
–
Beijing Olympic Game Lights Control
Established Green University of Tokyo Project (aka GUTP)
SBC (Smart Building Consortium) for Japanese standard
Start to talk with NIST and BACnet regarding B2G (Building-to-Grid)
• 2010 : Kicked off P-IEEE1888 (UGCCnet)
• 2011 : Approved as IEEE1888, Campus-wide & Multi-campus deployment
Green Univ. of Tokyo Project
• Building No.2, Hongo Campus
– Established in June 2008.
– Forming R&D consortium (independent from Gov.)
– Targeted reduction;
• 15%=$4M USD (in 2012), 50%=$30M USD (in 2030)
– 12 floor high, R&D and R&E activities
– Established October 2005
– More than saving energy
– Global standard
• IEEE1888
•
【Companies】
•
Asahi Kasei Microdevices Corporation
•
Cimx Corporation.
•
Cisco Systems, Inc.
•
Citrix Systems Japan K.K.
•
Daikin Industries, Ltd.
•
DSI, Inc.
•
Fuji Xerox Co., Ltd.
•
Fujitsu Limited
•
Hitachi Co.Ltd.
•
IBM Japan Ltd.,
•
ITOCHU Corporation
•
Johnson Controls Inc.
•
KAJIMA CORPORATION
•
Kantokowa Co., Ltd.
•
KOKUYO Co.,Ltd.
•
Microsoft Japan Corporation
•
Mitsubishi Corportion
•
Mitsubishi Heavy Industries Ltd.
•
Mitsubishi Research Institute Inc.
•
Mitsui Fudosan Co.,Ltd
•
Mitsui Knowledge Industry Co.Ltd.
•
NEC Corporation
•
Nippon Steel Engineering Co.Ltd.
•
NTT Corporation
•
NTT Facilities Inc.
•
OPTiM Corporation
•
ORIX Corporation
•
OTSUKA Corporation
•
Panasonic Corporation
•
•
•
•
•
•
•
•
•
•
•
•
•
Panasonic Electric Works Co., Ltd.
Q&A Corporation
Richo Co., Ltd.
Sanki Engineering Co., Ltd.
Schneider Electric Japan Group
SHINRYO Corporation
Sohgo Security Services Co.Ltd.,
Takenaka Corporation
Toshiba Corporation
Toyo Denki Seizo K.K.
Ubiteq Inc.
VeriSign Japan K.K.
Yamatake Corporation
【Organizations/Universities】
•
Green IT Promotion Council.
•
IPv6 Promotion Council.
•
The Institute of Electrical Engineers of Japan
•
The Institute of Electrical Installation
Engineers of Japan
•
LONMARK JAPAN
•
OKAYAMA IPv6 CONSORTIUM.
•
WIDE Project.
•
Tokyo Metropolitan Research Institute for
Environmental Protection
•
Keio University.
•
Nagoya University
•
Ritsumeikan University
•
Shizuoka University.
•
The University of Tokyo
【Companies】
•
Asahi Kasei Microdevices Corporation
•
Cimx Corporation.
•
Cisco Systems, Inc.
•
Citrix Systems Japan K.K.
•
Daikin Industries, Ltd.
•
DSI, Inc.
•
Fuji Xerox Co., Ltd.
•
Fujitsu Limited
•
Hitachi Co.Ltd.
•
IBM Japan Ltd.,
•
ITOCHU Corporation
•
Johnson Controls Inc.
•
KAJIMA CORPORATION
•
Kantokowa Co., Ltd.
•
KOKUYO Co.,Ltd.
•
Microsoft Japan Corporation
•
Mitsubishi Corportion
•
Mitsubishi Heavy Industries Ltd.
•
Mitsubishi Research Institute Inc.
•
Mitsui Fudosan Co.,Ltd
•
Mitsui Knowledge Industry Co.Ltd.
•
NEC Corporation
•
Nippon Steel Engineering Co.Ltd.
•
NTT Corporation
•
NTT Facilities Inc.
•
OPTiM Corporation
•
ORIX Corporation
•
OTSUKA Corporation
•
Panasonic Corporation
•
•
•
•
•
•
•
•
•
•
•
•
•
Panasonic Electric Works Co., Ltd.
Q&A Corporation
Richo Co., Ltd.
Sanki Engineering Co., Ltd.
Schneider Electric Japan Group
SHINRYO Corporation
Sohgo Security Services Co.Ltd.,
Takenaka Corporation
Toshiba Corporation
Toyo Denki Seizo K.K.
Ubiteq Inc.
VeriSign Japan K.K.
Yamatake Corporation
57 Members
42 Companies 15 NPOs
Stakeholders on Facility Business;
- Developer, e.g., landlord
【Organizations/Universities】
- General Contractor/Con”s”tractor
•
Green IT Promotion Council.
Promotion Council.
- System Integrator •• IPv6
The Institute of Electrical Engineers of Japan
Institute of Electrical Installation
- System Designer • The
Engineers of Japan
•
LONMARK JAPAN
- ICT Vendor
•
OKAYAMA IPv6 CONSORTIUM.
WIDEsensor
Project.
- Component vendor,•• e.g.,
Tokyo Metropolitan Research Institute for
Environmental Protection
- Standardization Body
•
Keio University.
Nagoya
University
- R&D organization, ••e.g.,
University
Ritsumeikan University
•
Shizuoka
University.
- Local government, e.g.,
Tokyo
•
The University of Tokyo
System overview
Data Integration among legacy sub-systems
Schedule
Server
Student
Router
TE
LON-IP
G/W
BACnet/
WS
Yamatake
Visualization of data
Web I/F
CiMX Server
LMJ
LON-ADP
Professor
TE
Common DB
(Live E!)
Management
TE
G/W
BACnet/
BXWS
Office
Ubiteq
Toshiba
/Cisco/
Panasonic
BACnet
CSV
Savic
Yamatake
EHP
Mitsubishi
GHP
Mitsubishi
N-MAST
Panasonic
Action and Control
Electricity Data Analysis
(CiMX) (Yokogawa)
oBIX
G/W
Schedule
controller
LMJ
EHP
mngmnt and
control
GHP
Lightening
mngmnt and control
control
Legacy system + common I/F gateway
Digital
LMJ
LONーIP
G/W
HDPLC LONーIP
G/W
DU
CiMX
HDPLC
PLC
Wireless
temperature
Wireless
sensor
temperature
sensor
Toshiba
HDPLC
100V
outlets
Electricity Electricity
(100V・200V) (100V)
Breaker
PC
Server
LMJ
LON-IP
G/W
Panasonic
DU
Metering
Aichi
Electricity
and water
metering
Ubiteq/Cisco
データ
収集PC
DU
200V Power
monitoring,
Digital
signage
LMJ
Wireless
temperature
sensor
NEC
Electricity
Sensor
Watanabe
Wireless
temperature
sensor
Yamatake
Data
spots
Additional system
System overview
Data Integration among legacy sub-systems
Visualization
of data
1. Sub-systems have
never
cooperated to
Action and Control
each other.…..
2. Enough stupid to deny the cooperation
and coordination…..
3. Isolated and proprietary sub-systems…..
Web I/F
CiMX Server
Schedule
Server
Student
Router
TE
Yamatake
TE
LON-IP
G/W
BACnet/
WS
Professor
LMJ
LON-ADP
Common DB
(Live E!)
Management
TE
G/W
BACnet/
BXWS
Office
Ubiteq
Toshiba
/Cisco/
Panasonic
BACnet
CSV
Savic
Yamatake
200V Power
monitoring,
Electricity Data Analysis
(CiMX) (Yokogawa)
oBIX
G/W
Schedule
controller
LMJ
Digital
signage
Ubiteq/Cisco
Digital
データ
収集PC
LMJ
LONーIP
G/W
HDPLC LONーIP
G/W
DU
CiMX
PC
Server
Panasonic
Wireless
temperature
Wireless
sensor
temperature
sensor
 Expensive and Stupid System
EHP
Mitsubishi
EHP
mngmnt and
control
GHP
Mitsubishi
N-MAST
Panasonic
i.e., 烏合衆
GHP
Lightening
mngmnt and control
control
DU
Metering
Aichi
Electricity
and water
metering
Legacy system + common I/F gateway
HDPLC
PLC
DU
Toshiba
HDPLC
100V
outlets
Electricity Electricity
(100V・200V) (100V)
Breaker
LMJ
LON-IP
G/W
LMJ
Wireless
temperature
sensor
NEC
Electricity
Sensor
Watanabe
Wireless
temperature
sensor
Yamatake
Data
spots
Additional system
The Important Lessons
1. Digital equipments are enough “cheap”
2. Very large “installation” cost, by human-being
work force
3. No security consideration, i.e., closed system is
implicit assumption
① Wireless technologies (1,2)
② Open system security (3)
Smart Meter
Smart Lights
With iPad/iPhone
Smart HVAC
Smart Kiosk
Migrating; from “single screen” to “multiple screens”
from “Pull” to “Push”
iPhone
Android
iPad
Mobile Cloud Solution
Currently 60 {small} companies
could run demand control
Smart Meters connected with
Internet and managed by iPad
with a mobile cloud platform
Strategic Use of;
Internet Data Center (iDC) and
Cloud Computing
We are discussing
Eco-ICT life with iPad
1. You do not need desktop nor note PC,
you can live only with iPad and i-Phone
(*) good for security management
2.Think Client charges up at home, no
power consumption at the office
3.Serves go to Data Center
Contribution by hosting service
• Many offices install old and in-efficient HVAC systems. When
we move the servers in these offices to iDC, we will be able to
improve the HVAC bill. Current HVAC systems improves 3040% energy efficiency, compared with existing systems.
15%
reduction
NTTビズリンクHP
http://www.nttbiz.com/eco_act/housing.html
Contribution of Virtualization,
i.e., Cloud Computing
• Servers in the offices with old hardware platform can be
accommodated in iDC with virtualization, i.e., cloud computing.
• Large energy saving by sharing the computing resources and
HVAC resources.
CO2 Emission = 100
(1) Move servers to iDC
CO2 Emission = 60
(2) Sharing resources by virtulization
Server A
Power Consumption
40kVA
40%
reduction
電力
40%削減
24kVA
Server B
Virtualization
Server A
Server B
Server C
Server C
Before
After
Source : NTT
We are discussing
Eco-ICT life with iPad
Now, we are doing;
1. You do not need desktop nor note PC,
(1)Energy saving of Esaki-Lab with
you can live only with iPad and i-Phone
VM integration
(*) good for security management
2.Think Client charges up at home, no
power consumption at the office
3.Serves go to Data Center
東京大学 大学院 情報理工学研究科 江崎研究室
本郷キャンパス 工学部2号館内
System configuration “before” virtualization
33.97kWh/24h
15.53kWh/24h
今回は対象外
Total: 49.50kWh/24h
35
東京大学 大学院 情報理工学研究科 江崎研究室
本郷キャンパス 工学部2号館内
System configuration “after” virtualization
Total: 49.50kWh/24h
→ 20.93kWh/24h
Reduced 57.7%!!
1.78kWh/24h
2.34kWh/24h
2.38kWh/24h
1.87kWh/24h
12.56kWh/24h
36
9 Serves into 5 Servers,
leading to 57.7% Saving
• 9 servers; 49.5 kWh
• 5 servers; 20.9 kWh
(*) Additional migrations
will be accommodated
We are discussing
Now, we are doing;
Eco-ICT life with iPad
(1)Energy saving of Esaki-Lab
1. You do
not
need
desktop
nor
note
PC,
with VM integration
you can live only with iPad and i-Phone
(2)Disaster protection, including
(*) good for security management
live VM migration, of WIDE
2.ThinkInternet
Client charges
up at home,
with Cloud
over 6no
(six)
power consumption at the office
university sites in Japan
3.Serves
go Leading
to Data Center
to better BCP
Then, Beyond the Energy Saving……
by UBITEQ, Panasonic EW, Cisco Systems, Daikin
Energy saving is of result, but the primary objective is efficient
and comfortable working environment.
Integration of
• Lights
• HVAC
• Sensors
In operation
since Nov.15,2008
Two steps; before and after the Earthquake
at Venture Company in Tokyo
kwh
1000.00
900.00
950.10
46%
21%
STEP1
800.00
752.89
700.00
STEP2
31%
600.00
516.20
500.00
400.00
Step 1
Step 2
300.00
200.00
100.00
0.00
2010/03
2011/03/07
2011/03/14
STEP1:
for non computer system
STEP2:
for computer system
Footprint: 1173.67 m2
www.ubiteq.co.jp
5F:415.27㎡、 6F: 758.4 m2
Number of employees: 82
After STEP1
②
①
Daily Report (2011.03.07)
1.
2.
More than 55% of Power consumption (384 kWh) was by “Servers” and
HVAC of “Server Room”.
Power consumption by “Lighting System” was larger than sum of other
equipments, i.e., PC, printer, copier or ordinary HVAC.
STEP2
March 07, 2011
622.89kwh / Day
236.69kwh
Reduction
March 14, 2011
386.20kwh / Day
38% Reduction
1.
2.
Introduction of Virtualization of servers, i.e., cloud computing
Further fine control of lighting system Power
Strategic collaboration with
China Team
Testbed and Standardization
Data from Beijing, China, with IEEE1888(=FIAP)
中日緑色IT合同 清華大学FIT ゲームニクス画面
中日緑色IT合同
清華大学 設置風景
清華大学 FITロビー 歓迎垂れ幕
寺崎審議官 視察風景
Same consortium has been established
by Tsinghua (清華大学)University in
Beijing (China)
大型ディスプレイ東芝REGZA 52‘
大型ディスプレイとタッチパネル
Green Society by IT
Smartway
Smart
Building
Smart
Remote
Agriculture
Healthcare
Smart
Home
Smart
factory
46
China-Japan Joint Green IT Project
清華大学FIT
Green Campus/Building)
(グリーンキャンパス)
中関村ソフトパーク
Green Industrial Park
(イノベーションハイテクパーク)
実施場所:
湖南省長沙市百果園農業ハウス
実施場所:
会議室、共用エリア、廊下、配電室
実施場所:
IDCマシンルーム、共用エリア、廊下
、駐車場
•センサー(温度、湿度、日照、CO2、
土壌の監視測定)
•農作物成長リアルタイムビデオ監視
制御システム
•灌漑自動化制御システム
•天窓、遮光ネット、ファン……自動制
御システム
•農業知能制御プラットフォーム
•灯光照明、LED照明制御システム
•共用エリアビデオ監視制御システム
•センサー(人感、温度湿度、照度)
•空調改造
•配電室改造
•可視化集中制御監視測定(遠隔)
•灯光照明、LED照明制御システム
•共用エリアビデオ監視制御システム
•センサー(人感、温度湿度、防犯照明)
•IDCマシンルーム空調改造
•電力システム改造(スマートメーター)
•可視化集中制御監視測定
•駐車場管理
湖南精密農業
Agriculture
(「両型社会」建設)
47
Toward Global Standardization;
FIAP to
IEEE1888 and ASHREA BACnet
http://standards.ieee.org/findstds/standard/1888-2011.html
Referenced System Architecture, 3 layers,
for standardization
Application
Data-Base
(Repository)
Field-bus
FIAP : Facility Information Access Protocol
4 Methods
data, query
registration, lookup
Gateway
LonWorks
oBIX
Gateway
ZigBee
Proprietary
Systems
Gateway
Registry
Data Storage Data Storage
APP.
Diagnosis of
operational condition
APP.
Energy analysis
APP.
Report making
4 Components
Gateway
Gateway
Gateway
Field Bus
FETCH, WRITE, TRAP
REGISTRATION, LOOKUP
Registry
BACnet
BACnet/WS
Modbus
5 Protocols
APP.
Etc.
Application Unit
FIAP Architecture for multi-frameworks
Activities toward global standard
1. Not domestic, but global
2. Practical;
(i) Open source for implementation
(ii) Testing spec/software for
interoperability and conformance
(iii) Logo program for deployment
①China-Japan Green IT
②NIST B2G
③IEEE 1888
④IETF/W3C
⑤ASHRAE BACnet (ISO/IEC)
⑥IPSO (with 6LowPAN)
⑦IPv6 Forum
⑧The Green Grid (for iDC)
⑨ETSI INT, IoT, 3GPP2/IMS
⑩SBC(Smart Building Consortium)
for Japan
Invitation of stakeholders
(new faces for us)
Testbed operation
Interoperability of IoT/SO
Identified Extending Functions
for IEEE1888
1. Security, i.e., authentication & authorization
2. Place-and-Play
a. CCDM (Central Controller-Based Device
Management) framework
b. Runtime objects generation and management
3. Component-Flow Framework
4. Transaction trace-ablity
5. DTN, Delay Tolerant Network
Further consideration
on Mobile Cloud
We need DTN.
• Ad hoc routing, e.g., MANET,
never work in the “real” field…..
•Do not trust simulations with “ns”
Conclusion; “6” lessons and strategy
1. Things are ready to be connected (via IEEE1888)
– Not only network, but also database /applications
2. Improvement of RoI by “wireless” technology
3. Strategic invitation of ”stakeholders”, to share the
power of open system
4. Autonomous delivery of new/innovative
applications by “transparent” open platform
5. You DO care IP version, but most people does NOT.
6. Controlling things by computer networks, for
improvement of efficiency, rather than saving
energy
Green University of Tokyo Project:
http://www.gutp.jp/
E-mail: [email protected]
www.wide.ad.jp
Thank you
Hiroshi ESAKI, Ph.D,
Graduate School of Information Science and Technology,
The University of Tokyo, Japan
Email [email protected]
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