Performance Analysis between H.323 and SIP over VoIPijtsrd
There are a number of protocols that may be employed in order to provide the Voice over IP VoIP communication services. In VoIP system, H.323 and Session Initiation Protocol SIP are the two major standards. Both of these signaling protocols provide mechanisms for multimedia teleconferencing services. Although the two protocols architecture is quite similar, they have many differences. This system presents Voice Video over IP communication and summarizes the differences and performance of two major VoIP protocols, H.323 and SIP according to the packet delay variation, jitter, packet loss, and Packet end to end delay. It is found that both of them are non interoperable, approaching each other, their focus and applicability is still different. In this paper, the system is designed and configured by Graphical Network Simulator GNS3 and analyzed performance by Opnet Modeler Simulation. Thet Zaw Aye "Performance Analysis between H.323 and SIP over VoIP" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-5 , August 2019, URL: https://www.ijtsrd.com/papers/ijtsrd26647.pdfPaper URL: https://www.ijtsrd.com/engineering/computer-engineering/26647/performance-analysis-between-h323-and-sip-over-voip/thet-zaw-aye
Performance Analysis between H.323 and SIP over VoIPijtsrd
There are a number of protocols that may be employed in order to provide the Voice over IP VoIP communication services. In VoIP system, H.323 and Session Initiation Protocol SIP are the two major standards. Both of these signaling protocols provide mechanisms for multimedia teleconferencing services. Although the two protocols architecture is quite similar, they have many differences. This system presents Voice Video over IP communication and summarizes the differences and performance of two major VoIP protocols, H.323 and SIP according to the packet delay variation, jitter, packet loss, and Packet end to end delay. It is found that both of them are non interoperable, approaching each other, their focus and applicability is still different. In this paper, the system is designed and configured by Graphical Network Simulator GNS3 and analyzed performance by Opnet Modeler Simulation. Thet Zaw Aye "Performance Analysis between H.323 and SIP over VoIP" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-5 , August 2019, URL: https://www.ijtsrd.com/papers/ijtsrd26647.pdfPaper URL: https://www.ijtsrd.com/engineering/computer-engineering/26647/performance-analysis-between-h323-and-sip-over-voip/thet-zaw-aye
A NEW SYSTEM ON CHIP RECONFIGURABLE GATEWAY ARCHITECTURE FOR VOICE OVER INTER...csandit
The aim of this paper is to present a new System on Chip (SoC) reconfigurable gateway
architecture for Voice over Internet Telephony (VOIP). Our motivation behind this work is
justified by the following arguments: most of VOIP solutions proposed in the market are based
on the use of a general purpose processor and a DSP circuit. In these solutions, the use of the
serial multiply accumulate circuit is very limiting for the signal processing. Also, in embedded
VOIP based DSP applications, the DSP works without MMU (memory management unit). This
is a serious limitation because VOIP solutions are multi-task based. In order to overcome these
problems, we propose a new VOIP gateway architecture built around the OpenRisc-1200-V3
processor. This last one integrates a DSP circuit as well as a MMU. The hardware architecture
is mapped into the VIRTEX-5 FPGA device. We propose a design methodology based on the
design for reuse and design with reuse concepts. We demonstrate that the proposed SoC
architecture is reconfigurable, scalable and the final RTL code can be reused for any FPGA or
ASIC technology. Performances measures, in the VIRTEX-5 FPGA device family, show that the
SOC-gateway architecture occupies 52% of the FPGA in term of slice LUT, 42% of IOBs, 60%
of bloc memory, 8% of integrated DSP, 16% of PLL and the total power is estimated at
4.3Watts.
Global System for Mobile Communication Based Smart Home Security SystemIJERA Editor
Home security system is needed for occupants' convenience and safety. In this paper, we present the design and implementation of an affordable, low power consumption, and GSM (Global System for Mobile Communication) based wireless home security system. In existing system, the home network is engaged with non-wireless technology, where the installation and maintenance is difficult. So the system cost is very high. In our proposed system, these difficulties are overcome by introducing a wireless home network which contains a GPRS Gateway and three kinds of security nodes namely door security node, anti intrusion node and SMS node to inform the user. The nodes are easy installing. All the three nodes are connected to the microcontroller.
A NEW SYSTEM ON CHIP RECONFIGURABLE GATEWAY ARCHITECTURE FOR VOICE OVER INTER...csandit
The aim of this paper is to present a new System on Chip (SoC) reconfigurable gateway
architecture for Voice over Internet Telephony (VOIP). Our motivation behind this work is
justified by the following arguments: most of VOIP solutions proposed in the market are based
on the use of a general purpose processor and a DSP circuit. In these solutions, the use of the
serial multiply accumulate circuit is very limiting for the signal processing. Also, in embedded
VOIP based DSP applications, the DSP works without MMU (memory management unit). This
is a serious limitation because VOIP solutions are multi-task based. In order to overcome these
problems, we propose a new VOIP gateway architecture built around the OpenRisc-1200-V3
processor. This last one integrates a DSP circuit as well as a MMU. The hardware architecture
is mapped into the VIRTEX-5 FPGA device. We propose a design methodology based on the
design for reuse and design with reuse concepts. We demonstrate that the proposed SoC
architecture is reconfigurable, scalable and the final RTL code can be reused for any FPGA or
ASIC technology. Performances measures, in the VIRTEX-5 FPGA device family, show that the
SOC-gateway architecture occupies 52% of the FPGA in term of slice LUT, 42% of IOBs, 60%
of bloc memory, 8% of integrated DSP, 16% of PLL and the total power is estimated at
4.3Watts.
Global System for Mobile Communication Based Smart Home Security SystemIJERA Editor
Home security system is needed for occupants' convenience and safety. In this paper, we present the design and implementation of an affordable, low power consumption, and GSM (Global System for Mobile Communication) based wireless home security system. In existing system, the home network is engaged with non-wireless technology, where the installation and maintenance is difficult. So the system cost is very high. In our proposed system, these difficulties are overcome by introducing a wireless home network which contains a GPRS Gateway and three kinds of security nodes namely door security node, anti intrusion node and SMS node to inform the user. The nodes are easy installing. All the three nodes are connected to the microcontroller.
The industrial internet of things (IIoT) sometimes called Industry 4.0 – is radically changing how businesses, especially industrial companies, operate.
Let’s begin with a short IIoT definition:
The Industrial Internet of Things (IIoT) refers to the vast number of machines and devices – or ‘things’ – a business uses that are now connected to the Internet. Protecting this critical operational data, secure IIoT forms a closed, private Internet network where the devices can communicate and share data with other people, systems, and things. This data can be used to improve existing work practices and business processes as well as creating entirely new ways of doing things.
The industrial internet of things (IIoT) sometimes called Industry 4.0 – is radically changing how businesses, especially industrial companies, operate.
Let’s begin with a short IIoT definition:
The Industrial Internet of Things (IIoT) refers to the vast number of machines and devices – or ‘things’ – a business uses that are now connected to the Internet. Protecting this critical operational data, secure IIoT forms a closed, private Internet network where the devices can communicate and share data with other people, systems, and things. This data can be used to improve existing work practices and business processes as well as creating entirely new ways of doing things.
A Comparison of Four Series of CISCO Network Processorsaciijournal
Network processors have created new opportunities by performing more complex calculations. Routers
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flexibility, providing integrated services, high security, supporting and updating with the lowest cost, and
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Similar to Video Teleconferencing (VTC) Technology at the National ... (20)
Video Teleconferencing (VTC) Technology at the National ...
1. Office of the Chief IT Architect (OCITA) M. Amodio/R. Sloan
NIHRFC0032 OCITA
Category: Informational June 2008
Video Teleconferencing (VTC) Technology
at the National Institutes of Health (NIH)
v1.0
Status of this Memo
This memo provides information for Video Teleconferencing (VTC) Technology at the National
Institutes of Health (NIH). Distribution of this memo is unlimited.
Table of Contents
1 Introduction............................................................................................................................. 2
2 Business Objectives for a Standardized VTC Technology Architecture................................ 2
3 Video Teleconferencing (VTC) Technology at the National Institutes of Health (NIH) ....... 2
3.1 Introduction..................................................................................................................... 2
3.2 Current VTC Practices within NIH................................................................................. 2
3.3 Compliant Specifications for NIH VTC Endpoints ........................................................ 4
4 References............................................................................................................................... 6
5 Contact .................................................................................................................................... 6
6 Security Considerations .......................................................................................................... 6
7 Changes................................................................................................................................... 6
8 Authors’ Addresses................................................................................................................. 7
Approved 6/17/2008
2. NIHRFC0032 VTC Technology at the NIH June 2008
v1.0
1 Introduction
The intent of this document is to provide information on the VTC practices at NIH, a background
on the International Telecommunication Union -Telecommunications Standardization Sector
(ITU-T) Recommendations and the business drivers for utilizing NIH’s VTC infrastructure.
Ultimately, it will be used as supplemental information for a separate VTC technology standard.
2 Business Objectives for a Standardized VTC Technology
Architecture
NIH has adopted specifications and standards for VTC endpoints that work most efficiently and
effectively with the VTC infrastructure.
Business objectives for adopting and implementing VTC technology standards include the
following:
• Enable successful passing through of the NIH border firewall
• Allow VTC administrators to remotely manage endpoints
• Provide a standard naming convention for all endpoints
• Supply dedicated telephony services
• Certify capability with endpoints to the NIH VTC infrastructure and the NIH network in
general
• Comply with International Telecommunication Union – Telecommunications
Standardization Sector (ITU-T) defined recommendations for VTC
3 Video Teleconferencing (VTC) Technology at the National
Institutes of Health (NIH)
3.1 Introduction
In order to ensure the successful integration of new VTC technology infrastructure, primarily
supported by the Center for Information Technology (CIT), organizations implementing VTC
technology should understand the established endpoint specifications in use within the VTC
infrastructure. An endpoint is a terminal, gateway or multipoint control unit (MCU).
Terminals are the conference rooms on the local area network (LAN) that provide real-time,
two-way video and audio communications. These specifications were determined through
market and independent research.
3.2 Current VTC Practices within NIH
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3. NIHRFC0032 VTC Technology at the NIH June 2008
v1.0
Currently, there are two services provided by CIT’s VTC infrastructure: Internet Protocol (IP)
Videoconference – ITU-T Recommendation H.323 – and Integrated Services Digital Network
(ISDN) – ITU-T Recommendation H.320. IP Videoconference is performed on more of an ad
hoc basis while ISDN primarily concerns scheduling VTC technology services.
ITU standards describe the protocols, services and equipment required for VTC communications
including video, audio, and all other data on networks that does not possess guaranteed Quality
of Service (QoS). CIT complies with this standard with its IP Videoconference services.
Both H.323 and H.320 are ITU-T Recommendations. Recommendations are standards that
define how telecommunication networks operate and interwork.
CIT has a heterogeneous, H.323 and H.320, multi-vendor enterprise video teleconferencing
infrastructure. A Gatekeeper is an optional component in the H.323 system which is used for
admission control and address resolution.
The H.323 Recommendation (IP Videoconference) is comprehensive, yet flexible, and can be
applied to voice-only handsets and full multimedia video-conferencing stations, among others.
H.323 applications are set to grow into the mainstream market for several reasons:
H.323 establishes multimedia standards for the existing infrastructure (i.e. IP-based
networks). Designed to compensate for the effect of highly variable LAN latency,
H.323 allows customers to use multimedia applications without changing their
network infrastructure.
IP LANs are becoming stronger. Ethernet bandwidth is migrating from 10 Mbps to
100 Mbps, and Gigabit Ethernet is making headway into the market.
By providing device-to-device, application-to-application and vendor-to-vendor
interoperability, H.323 allows customer products to interoperate with other H.323-
compliant products.
PCs are becoming stronger multimedia platforms due to faster processors, enhanced
instruction sets, and better multimedia accelerator chips.
H.323 provides standards for interoperability between LANs and other networks.
Network loading can be managed. With H.323, the network manager can restrict the
amount of network bandwidth available for conferencing. Multicast support also
reduces bandwidth requirements.
H.323 has the support of many computing and communications companies and
mainstream organizations. The efforts of these companies will generate a higher level
of awareness in the market.
H.323 is not tied to any hardware or operating system. H.323-compliant platforms will
be available in many sizes and shapes, including video-enabled personal computers,
dedicated platforms, IP-enabled telephone handsets, cable TV set-top boxes and
turnkey boxes.
Many users want to conference from a LAN to a remote site. For example, H.323
establishes a means of linking LAN-based desktop systems with ISDN-based group
systems. H.323 uses common codec technology from different videoconferencing
standards to minimize transcoding delays and to provide optimum performance.
Amodio/Sloan Page 3
4. NIHRFC0032 VTC Technology at the NIH June 2008
v1.0
H.320 Recommendation (ISDN) describes the protocols for establishing videoconferencing over
a digital telephone connection. Typically an ISDN videoconference unit is purchased from a
commercial vendor and is then connected using either ISDN2 lines or channels patched from an
ISDN30 bearer. High quality videoconferencing today can be achieved on as little as 256Kbps
(fair quality), 384kbps (which is industry default) or up to 1152kbps, which includes data sharing,
i.e. using a PowerPoint™ presentation.
This H.320 type of videoconferencing has historically been the most popular and flexible. The
standard governs communications over digital channels, similar to those a telephone uses deep
within the telecommunications network. Frequently, in order to ensure a high degree of picture
and sound quality, a technique called "inverse multiplexing" is used to aggregate channels for
higher bandwidth.
Other applicable ITU-T Recommendations include:
• H.460.18 – ITU Standard that governs the traversal of H.323 call setup messaging
through a firewall/NAT using standard H.323 signaling in a non-tunneled communication
protocol.
• H.460.19 – ITU Standard that governs the traversal of all media within an H.323 call
through a firewall/NAT. H.460.19 compliance requires compliance with H.460.18 as
well.
• H.460.19 Multiplexed Media – an optional portion of H.460.19 standard that reduces the
number of ports needed for media communications with a traversal server.
3.3 Compliant Specifications for NIH VTC Endpoints
To use the NIH VTC infrastructure, NIH organizations should adhere to the endpoint
specifications listed below. This section illustrates all the specifications required to ensure
seamless integration.
Amodio/Sloan Page 4
5. NIHRFC0032 VTC Technology at the NIH June 2008
v1.0
H.320 H.323
Approval Date 1990 1996
Network ISDN IP
Video H.261 H.261
H.263* H.263
H.264 H.264
Audio G.711 G.711
G.722 G.722
G.722.1 G.722.1
G.728* G.728*
AAC G.723*
AAC-LD G.729
AAC
AAC-LD
Multiplexing H.221 H.225.0
Control H.230 H.245
H.242
* Denotes Optional Standard
The Video Standards
H.261: Supports 352x288 (CIF or FCIF) and 176x144 (QCIF). DCT-based algorithm tuned for
2B to 6B ISDN communication. Required for H.320, H.323, and H.324.
H.263: Much-improved derivative of H.261, tuned for POTS data rates. Mostly aimed at
QCIF and Sub-QCIF (128x96 -- SQCIF), while providing better video than H.261 on QCIF and
CIF.
H.264: Joint collaboration between the ITU and ISO. Improved video over H.263 providing
similar quality at half the bandwidth.
The Audio Standards
G.711: 64 Kbps, 8K samples/sec, 8-bit companded PCM (A-law or µ-law), high quality, low
complexity.
G.722: ADPCM audio encode/decode (64 kbit/s, 7 kHz).
G.722.1: ADPCM audio encode/decode (24 or 32 kbit/s, 7 kHz)
G.723: Speech coder at 6.3 and 5.3 Kbps data rate. Medium complexity.
G.723.1: 3.4 kHz dual rate speech codec at 5.3 and 6.4 kbit/s
G.728: 16 Kbps, LD-CELP, high quality speech coder, very high complexity.
G.729: 8Kbps, LD-CELP, high quality speech coder, medium complexity. G.DSVD is an
interoperable subset.
AAC: Advanced Audio Coding, variations include AAC-LD (low delay) (TANDBERG
endpoints: 64 or 128 kbit/s, 20kHz).
The Communications Standards
H.221: Frame Structure 64-1920 Kbps.
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6. NIHRFC0032 VTC Technology at the NIH June 2008
v1.0
H.225: Media Stream Packetization and synchronization on non-guaranteed quality-of service
LANs.
H.230: Frame synchronous control and indication signals for audio visual systems.
H.242: System for establishing audio visual terminals using digital channels up to 2Mbps.
H.245: Control of communications between visual telephone systems and terminal equipment on
non-guaranteed bandwidth LANs.
By aligning to these VTC endpoint specifications, NIH stakeholders, including those within the
Institutes and Centers (IC), will be able to acquire hardware and software that will work with
CIT’s VTC service and prevent incompatibility with the NIH VTC infrastructure.
4 References
For additional information about the International Telecommunication Union -
Telecommunications Standardization Sector (ITU-T), please visit http://www.itu.int/ITU-
T/index.html.
For a list of all the applicable ITU-T Recommendations, please visit
http://www.packetizer.com/ipmc/h323/standards.html.
5 Contact
To contact the NIHRFC Editor, send an email message to EnterpriseArchitecture@mail.nih.gov.
Please contact the CIT VTC group at NIHVTCadmin@mail.nih.gov to obtain VTC information
and registration/installation forms at NIH.
6 Security Considerations
Although this Informational NIHRFC details changes to security architecture procedures for
video teleconferencing, the information contained in this document does not compromise
security considerations at NIH.
7 Changes
Version Date Change Authority Author of
Change
0.1 4/14/2008 Original Document N/A Matthew Amodio,
NIH OCITA
0.2 5/28/2008 Added Rubin Sloan NIHRFC0001 Matthew Amodio,
as the Technical NIH OCITA
Author
0.3 5/29/2008 Removed language NIHRFC0001 Steve Thornton,
Amodio/Sloan Page 6
7. NIHRFC0032 VTC Technology at the NIH June 2008
v1.0
that suggested this NIHRFC Editor
document as a
standard.
1.0 06/17/2008 Document approved. NIHRFC0001 Steve Thornton,
NIHRFC Editor
8 Authors’ Addresses
Matthew Amodio
National Institutes of Health
10401 Fernwood Road
MSC 4806
Bethesda, Maryland 20817
Phone: 301-402-1088
Email: amodiomr@mail.nih.gov
Rubin Sloan
National Institutes of Health
10401 Fernwood Road
MSC4806
Bethesda, Maryland 20817
Phone: 301-451-9960
Email: sloanr@mail.nih.gov
Amodio/Sloan Page 7