Friday, May 26, 2017

Media Converter best for Surveillance Network

Media Converter best for Surveillance Network

Over the years, there has been a growing popularity of Video based Ethernet networks, resulting in the increasing use of Ethernet switches in the video network infrastructure.
Many types of video security and surveillance networks that are designed for applications in different environments. Analog video network and IP video network are the two most commonly used types for security and surveillance video transmission.

While IP video is more advance and can provide better image quality and network performance in large scale. The biggest character of IP video surveillance network is that every camera has its own IP address to tell itself from the others in the whole video network. Currently, with the demand for higher transmission speed, image quality and longer transmission distances, fiber optic cables are widely used in the video network. Thus, in both of the two surveillance networks, media conversion are necessary, like conversions between fiber and copper or video to fiber. The following will offer the cabling solutions that using media converters.

Video Media converter is a simple networking device that enables you to interconnect networks or network devices with different speeds, operation types, modes and media types. And the most common type usually works as a transceiver, converting the electrical signals in copper unshielded twisted pair (UTP) network cabling to light waves used for fiber optic cabling. It is essential to have the fiber optic connectivity if the distance between two network devices is greater than the copper cabling's transmission distance. Since media converters are IEEE compliant devices, they implement IEEE data encoding rules.
What is the

SFP module?
The small form-factor pluggable (SFP) is a compact, hot-pluggable transceiver used for both telecommunication and data communications applications. The form factor and electrical interface are specified by a multi-source agreement (MSA).

Media converter?
A fiber media converter is a simple networking device that make it possible to connect two dissimilar media types such as twisted pair with fiber optic cabling. Twisted pair cable, coaxial cable and other copper cabling can only support limited length before signal becomes too weak. Main application area is in security surveillance.

Why Best:

Ease of Use and High Availability
The SFP ports are widely used in the Gigabit Ethernet and the Fiber channel to provide a flexible and cost-saving solution for the enterprise networks and data centers. SFP port available in Enterprise Gigabit Ethernet Switcher. During the troubleshooting entire network will be down for time being.

Configuring and installing redundant solution of media converter is much easier to handle and to manage than higher-layer devices. And it will makes the troubleshooting easier if you add management functions to the media converter.
Proprietary
SFP modules are vendor dependent and switch is not available or that part number switch manufacture is stopped. In that case whole network switches needs to be stopped.

Media Converter is available, it can change any time. Its biggest advantage of this product.

EMI Emissions
The heat and EMI emissions are one of the biggest problems related to SFP devices.
No Such pain with media Converter.

Flexibility and Simplification
Wonderfull performance with LAN without protocol transparency with 850 nm and 1300 nm multimode fiber and 1310 nm and 1550 nm single-mode fiber.
It is of much flexibility for media converter to combine copper with 850 nm and 1300 nm multimode fiber and 1310 nm and 1550 nm single-mode fiber. With protocol transparency, it can be applied in anywhere in the local network or remote network whether it's a LAN, WAN or the MAN environment.

Handling Warning
Copper SFP are static sensitive. To prevent damage from electrostatic discharge (ESD), it is recommended to attach an ESD preventative wrist strap to your wrist and to a bare metal surface whenever you install or remove a Copper SFP module.
No such warning with media converter.

Safety Warning
Only trained and qualified personnel should be permitted to install or replace.
No such personnel required.

Spaceing
SFP Module takes up less space at Network Switch port.
Media converter  takes Little more space.

Powering
SFP Module Take power from Enterprise Ethernet Switch.
Media converter derives power from the switch it's plugged into. (Media converter requires a separate AC power outlet.)

Cost Reduction
Compared with the hybrid media switches, the cost of media converters with cost-effective Ethernet switches is much lower. This type of media converter solution can cost significantly less than that relies on higher-layer devices such as routers or switches.

Biggest advantage in this type of topology is where network consist of more than hundred nodes network. Fault point is reducing to switch only.

Analog Video Network Cabling Infrastructure
In a typical analog video network (shown in the above picture), analog CCTV cameras are connected to a central management room or devices (VCR—video cassette recorder or DVR—digital video recorder) via coaxial cables. If the camera has PTZ (Pan-Tilt-Zoom) function, an additional controller is added.

As mentioned, the performance and the transmission distance are limited by using copper cables. To connector more fixed analog cameras and PTZ analog cameras, fiber optic cable should be introduced to this typical network. Then fiber media converters are the best solutions. The following picture shows the basic structure or an upgraded version of a typical analog video structure which using fiber optic cable in this network.
To connect the fixed analog cameras to the server room, a pair of fiber media converters should be added between the server room and cameras. Video signals will be transmitted into fiber optic signals. For analog PTZ cameras, there are two types of signals should be converted into fiber optic signals, one for video and one for data. Thus, two different media converters or a fiber media converter that covers the two functions should be installed.
It is known that fiber media converters should be used in pairs. As one of the media converters is in deploy on the fiber end that near the camera, the other one should be deploy on the other fiber ends that near the server room. For better management, all the fiber media converters at the fiber end near the server room could be installed in a managed fiber media converter rack chassis.
IP Video Network Cabling Infrastructure
In a typical IP video surveillance network (shown in the above picture), IP cameras are connected directly to the local area network and transport video across the IP network via UTP cabling and switches. PoE IP cameras are also time-save and cost-effect solutions. Video can be recorded to any PC or server on the network. To introduce fiber optic cabling in to this typical IP video network, the method is similar to introducing fiber optic into an analog video network as described in the above paragraph.

In the following case (shown in the following picture), PoE IP cameras are used. A pair of PoE media converters should be installed on both ends of a length of fiber optic cable to achieve the conversion between video and fiber. At the computer side where the videos are recorded, a pair of Ethernet media converters should be installed. All of the media converters near the network switches can be set at a managed media converter chassis before the connected to the switches.
Biography:
Arindam Bhadra is an eSecurity professional 11yr + in this industry. He is a good freelance blogger. His blog is now No 1. Blog in India. 2.8L page viewer globally. Mr. Bhadra is an Electronics & telecommunication Engineer from IETE, New Delhi. He is a member of FSAI from 2011 & Go Beyond security from 2008. His blog arindamcctvaccesscontrol.blogspot.com focuses on security & Safety bloggers. Apart from his job, he loved to spend all his time with eSecurity & Safety technology and loves to help people. He is a Tech enthusiast and has written articles over the period on this blog. You can follow him on Facebook, Twitter, LinkedIn & Google+ etc.

This artical publish on May 2017 issue Safe Secure Magazine

Sunday, May 14, 2017

Difference between Dynamic and Static IP

Difference between Dynamic and Static IP
The major difference between dynamic and static IP is that dynamic IPs change every time one connects to the internet, while static IPs remain the same.
Internet Protocols, also known as IP addresses is a 32-bit number that is usually assigned to a computer when it connected to a network, such as the Internet. The IP address works similar to an actual address and lets computers know where to send data packets. The network devices use these address in order to communicate with each other.
The IP address are made up of 4 parts of numbers that are divided by dots (.) So, a typical IP address will looking something like – 72.169.189.01.
Although, the IP Based product / computers communicate with each other using IP addresses, to make it easier to remember the internet uses DNS or Domain Name System. This DNS is sort of an address book that pairs names to IP addresses. For example, if one wanted to visit the Google website, they would type in www.google.com in the address bar. The DNS will look up the IP address (74.125.239.35) paired with this name and will ping that address. Their system will respond back and the webpage will load on your computer.
There are two types of IPs – dynamic and static IP addresses. The major difference between dynamic and static IP is that dynamic IPs change every time one connects to the internet, while static IPs remain the same.
There are limited amount of IP addresses that are available and for this reason, many companies assign dynamic IPs, unless a static IP is asked for. So, every time a device is connected to the Internet, the IP address can change. This also allows the limited number of IPs to become reused, making it more convenient.
Broadband connections today lease IP addresses and use the DCHP dynamic IP address system. This system is also often considered safer, since the IP is always changing it makes it more difficult to hack the computer. Static IPs are commonly used by companies or people who require a similar IP address. The can apply for a static IP by paying a fee.
Comparison between Dynamic and Static IP:

Dynamic IP
Static IP
Full form
Dynamic Internet Protocol
Static Internet Protocol
Definition
The internet protocol will constantly change
The internet protocol will remain the same
Cost Effective
More cost effective
Less cost effective
Security Risk
Lower
Higher
Upload/Download Speed
Slower
Faster
Good for
Good for residential user and small business owners
Web servers, email servers and other Internet servers. Also, for VOIP, VPN, playing online games or game hosting




Saturday, May 6, 2017

SD-WAN can provide Quality of Service over the Internet

SD-WAN can provide Quality of Service (QoS) over the Internet
Organizations have tried to make voice services work over Internet Protocol (IP) network pipes (aka Voice over IP or VoIP), there have been very basic requirements in order to make it operate effectively. The first item needed for IP based voice was a dedicated, business class network line to carry this sensitive traffic. A business class circuit was paramount to reliability and uptime required for a crucial service like voice. This type of network access has low latency characteristics which keeps the amount of time it takes to forward the voice traffic low so that conversations are not made off kilter by long delays. Also absolutely critical to voice over network pipes is an additional layer over these high quality dedicated connections, something called quality of service or QoS. QoS is a suite of bandwidth prioritization and reservation techniques that give select services fast lane access to bypass lesser classifications of traffic and also reserves bandwidth preventing exhaustion of available throughput. Most commonly, QoS is used in tandem with carrier services like an IP VPN or Multi-Protocol Label Switching (MPLS) and have been assumed by many to be the only way to reliably deliver voice services for an organization. I can affirm as a network engineer for the past few decades, this has been the case for most of my career. In order for voice to perform adequately, specific care was required to spec out dedicated pipes with prioritization and if you didn't, you were typically asking for trouble in the way of poor quality, disconnections and general voice issues. That is until a thing called Software Defined Wide Area Networks or SD-WAN came along. This nascent technology space is drastically changing the way we do a lot of things on the wide area network, including managing sensitive real-time protocols that require QoS.

Video quality can suffer if the network can’t meet its high bandwidth needs. Video conferencing can take on many forms and protocols. For enterprises that have experienced problems, such as delay and jitter on voice over IP platforms, you know some platforms are better than others. The big variance in supporting video conferencing requirements is the integrity of traffic over wide-area connections.

Let's take a look at some of the things that make SD-WAN different versus how we've implemented voice over traditional networks up until now. These are items that are truly differentiators from means we used in the past to run network traffic over both tried and true dedicated lines not to mention over the commodity broadband or specifically configured Dedicated Internet pipes.

1.   Multi-Path Steering - SD-WAN can actively forward over multiple lines and is constantly measuring the characteristics and properties of each path available. Because it can very rapidly identify issues like high latency, packet loss and jitter, there are software mechanisms to quickly bypass these issues by utilizing an alternate path on the fly.
2.   Forward Error Correction and/or Packet Duplication - When issues like data loss from dropped packets arise, if there is only one path available or all paths are experiencing loss, that can be a serious issue with traditional networks with little means to remediate. SD-WAN employs features such as Forward Error Correction (FEC) or Packet Duplication which once packet loss is identified on a path, will send duplicates of the same packet to have greater assurance that critical data like voice or video will make it to their destination. At the other side of the SD-WAN connection for that voice or video stream, the first packet received will be sent along and the duplicates will be dropped.
3.   Jitter Buffering - Voice and video quality can suffer from a network condition called "jitter" which is when the information sent over the network is spaced inconsistently leading to a variable tempo for the stream. The result is audio or video that can have gaps, speed up then slow down and generally become impaired. SD-WAN measures the gaps between the packets and can evenly space these packets on the other side providing what is called a "jitter buffer" to realign the timing of these packets to keep the video or audio stream cadence intact.
4.   Prioritization and Queuing over Multiple Paths - Because SD-WAN performs it's queuing and packet forwarding over something called an "overlay", the forwarding decisions for information that has the highest priority and reservation of bandwidth for applications is performed at a layer above the traditional IP interface. With this, a priority "fast pass" can be given to crucial data like voice, video or other business essential apps bi-directionally and this can be done over all paths available.
So as you can see, there are many pieces that come together to make IP based voice over broadband and Dedicated Internet Access (DIA) is now possible. WAN Dynamics has designed many SD-WAN based solutions for customers and has seen it perform in the "real world" so can attest that IT WORKS! 

The following are some of the more prominent examples of reasons for SD-WAN we've been able to assist with to date:
1.   Voice Services Over the Internet - A lot of small to medium sized businesses have started utilizing voice services over commodity broadband connections with no Quality of Service (QoS) in place. Though most of the time this works adequately, there will be many instances of degradation in quality or dropped calls that can be frustrating. This has just been the reality of utilizing the public Internet for voice services... up until now. With SD-WAN, we're able to prioritize voice traffic both inbound and outbound while leveraging multi-path technologies to "route around" carrier backbone problems. We're able to do this with single, stand alone sites in addition to multiple locations.
2.   WAN Visibility and Management - Setting aside the benefits of multi-path link steering, bandwidth aggregation and QoS for a bit, many organizations have no usage breakdowns or application performance visibility in their network today. As a byproduct of the application steering and prioritization baked into most SD-WAN solutions, there is a great deal of reporting functionality available. So now when stakeholders of IT want to know what is happening at their remote locations, they have a graphical interface to see exactly what is happening.
3.   Configuration Uniformity and Standardization - Large organizations which have many sites or will soon have many sites at the hands of rapid growth can have a lot of hands in the IT group working on things. With this, lack of standardization becomes an issue as sites are configured and turned up if there is not a uniform configuration policy. With SD-WAN, attaining a high level of uniformity is simple using features like Zero Touch provisioning and Configuration Profiles to make sure that all sites are configured identically. This also helps greatly for change management if you want to make a configuration update to all of your locations. With this approach, you can update a configuration in one place and push it to all sites, instantaneously. This frees up engineers to solve larger problems facing the business rather than making a minor configuration change on dozens or hundreds of sites.
4.   Remote Diagnostics Capabilities - When there are issues at a remote location, it can often times be difficult to walk users through providing troubleshooting assistance or getting the right software and hardware onsite. With the built in tools into many SD-WAN solutions, the ability to perform packet captures, see network state and what the users see on the network, so that the time vetting issues on the network can be greatly reduced.
5.   MPLS / IP VPN Replacement - MPLS and other dedicated private network infrastructures have begun to outlive their usefulness with many organizations as critical workloads are moved to the cloud. Further, there is growing demand by companies to reduce cost of their expensive WANs that typically have no redundancy or application smarts built in. SD-WAN can easily leverage existing dedicated internet access (DIA) links and even inexpensive broadband connections to build an application aware, private network overlay that provides more applications control, redundancy and critical business application prioritization than traditional network designs.
These are just five examples of things we have been able to help with. We're happily conducting Proof of Concept deployments for businesses to show the value of SD-WAN and finding new use cases all the time.

"By the end of 2019, 30% of enterprises will have deployed SD-WAN technology in their branches, up from less than 1% today."

Wednesday, April 26, 2017

CCTV installation challenges

CCTV installation challenges

We describe some of the challenges you can encounter during installation, and how to deal with them. We’ll guide you through areas such as cabling, network setup, environmental considerations, and camera selection and placement.
Considerations when cabling
Use the correct wiring standards
There are two wiring standards for network cabling: T568a and T568b. DO NOT COMBINE T568a and T568b on the same cable.

Use high-quality CAT 5e or CAT 6 cabling
Cables are categorized according to the data rates that they can transmit effectively. The specifications also describe the material, the connectors and the number of times each pair is twisted per meter. The most widely-installed category is CAT 5e. Ensure that the cabling in your installation fulfills the required Category (Cat).

Cat 3 (no longer used) with 16 MHz bandwidth
Cat 5e with 100 MHz bandwidth
Cat 6 up to 250 MHz
Cat 6A up to 500 MHz
Cat 7 up to 600 MHZ
Cat 7A with a frequency range through 1000 MHz

Video files are generally very large data files, and need to be moved around the network as quickly as possible. In general, it is possible to use good-quality Cat 5 cabling for gigabit networks; it is recommended to utilize Cat 5e or Cat 6 cabling for gigabit connectivity, even if your existing network switches and routers support only 100 Mbps. This will ensure that the cabling infrastructure is in place when the gigabit upgrade occurs. The rest of the points apply equally to 1 Gbps and 100 Mbps connections – each can be affected by poor cabling and incorrect connections.


Have good cable runs
Ensure that your cabling meets the requirements of your equipment. The distance between a transmitter and a receiver cannot be greater than 100 m (325 ft) in total. If installing sockets, remember to take into account the distance between the socket and the computer. A good rule of thumb is 90 meters for horizontal runs, and ten meters for the patch cabling. It is also important to be aware that the whole length of cable and connectors is of the same type, such as STP.
Do NOT run cabling next to electrical mains cabling (because of the potential for interference), or suspend network cabling from ceiling tiles (this may violate building codes and fire regulations).

Axis network products are intended to be used with Shielded Twisted Pair (STP) cables in Europe due to CE-marking requirements and are EMC approved with STP cables. This requirement is also valid for several other countries such as Australia/New Zealand, Canada, Korea and Japan. The use of STP cables is especially important to maintain a high degree of immunity to RF (Radio Frequency), electrical and magnetic disturbances as well as provide the lowest possible degree of radiated and conducted Radio Frequency emission.
It is also mandatory to use an STP cable where the camera is used outdoors, or where the network cable is routed outdoors. STP cables also lower the effects of close situated power relays, motor inverters and electrical cables that are run in parallel close to network cables. Shielded Twisted Pair (STP) cabling needs to be grounded. This is normally accomplished since the switch or POE adapter is connected to an earthed mains socket. For more information about STP versus UTP, go to Shielded or unshielded network cables.
The electrical environment shall be considered when deciding which type of Twisted Pair cable is to be used.
Since network cabling typically uses solid wire, cabling should not be twisted or bent into a tight radius (not less than 4 times the diameter of the cable). Do not use metal staples to secure cable runs, nor tightly adjusted cable wraps. Avoid a daisy chain network topology.
Use the correct connectors
Network connections use RJ45 connectors designed for either stranded or solid cable, but usually not both. Ensure that you use the correct crimping tool for the specific type of connector.

The customer can use the connector being shipped, or decide to order an optional premounted cable with the connector already attached, called the RJ-45 IP66-rated Cable with premounted connector (CAT6) 5 m. This connector maintains the the IP66 rating of the camera and prevents dust and moisture from entering into the dome assembly.
Ethernet cables can be run outdoors, but their thin plastic casing will deteriorate quickly when exposed to the elements. For best results, outdoor Ethernet cables should be placed in a conduit and buried a fair distance away from power lines or other sources of electrical interference. Remember to use an STP cable if the camera is used outdoors or if the network cable is routed outdoors.
PVC or other plastic pipe, installed with waterproofing, can work as a conduit. Special exterior or direct burial CATEGORY cables could be used for outdoor runs. Direct burial CAT5 cable costs more, but it is designed specifically for outdoor use. Both ordinary and direct burial CAT5 cables attract lighting strikes to some degree. Simply burying a cable underground does not lessen its affinity for lightning. Accordingly, CAT5 surge protectors should be installed as part of outdoor Ethernet networks to guard against lightning strikes.

Keep the pairs together and wire correctly
A network cable consists of four pairs of twisted wires, and these are color coded (orange, green, blue and brown). The cable specification has been designed for high-speed data transfer and very little cross-talk. It is very important that no more than about 6 mm of the cable is untwisted at either end; otherwise, problems such as ‘near end cross-talk’ can arise, which will have a detrimental impact on your network. It is essential that you wire the plug correctly and not just from pins 1 through 8 at both ends.
Environmental conditions
Environmental considerations, for example whether the camera will be installed indoors or outdoors, determine the cabling and connectors to use.
Depending on the environment, the camera should be installed with the adequate housing to provide the correct level of protection. If the camera is exposed to acids, severe weather conditions, or extreme heat or cold, the camera needs a housing that withstands this kind of environment. For more information on Environmental issues, see Challenge 5, Environmental Considerations.
Certify the installation
In twisted-pair copper wire networks, copper cable certification is achieved through a thorough series of tests in accordance with standards set by the Telecommunications Industry Association (TIA) or the International Organization for Standardization (ISO). These tests are done using a certification testing tool, which provide "Pass" or "Fail" information.

Voltage transients
The most recognized cause of transient voltage is lightning; however, the most frequent source is the local power grid.
Network camera for outdoor installation are protected by design against power surges and transients. Part of this design involves using a shielded network cable STP between the PSE (Power Sourcing Equipment - The term PSE defines any device connected at the camera end of the cable, such as a midspan, endspan, network switch, network hub or power injector.) and the camera to ensure a path for the power surge to reach ground.
The installation of cameras using a shielded cable STP and a properly grounded PSE has been tested to comply with industry immunity standards levels, for example for surge protection. Any other installation method will void the warranty and leave the unit at risk.
Always use a shielded network cable STP between the camera and the PSE, and ensure that the PSE is properly grounded.
Calculating the total power needed
Power over Ethernet (PoE) is a mechanism for supplying power to network devices over the same cabling used to carry network traffic.

There are currently two standards for PoE: 802.3af allows for a maximum of 15.4 W per channel, whereas PoE 802.3at doubles the available power to 25 W.
The total power consumption requirement of all equipment that will be connected to a specific switch on a network needs to be calculated to ensure sufficient power is available per switch. This total wattage requirement must be less than a switch’s PoE power budget – total PoE power per switch and per port.
The following chart shows the power consumption at both the PSE and the PD.
Class
Usage
Power Level Output at the Power Sourcing Equipment (PSE)
Maximum Power Levels at the Powered Device (PD)
0
Default
15.4 W
0.44 - 12.95 W
1
Optional
4.0 W
0.44 - 3.84 W
2
Optional
7.0 W
3.84 - 6.49 W
3
Optional
15.4 W
6.49 - 12.95 W
4
Valid for 802.3at High PoE
30 W
12.95 - 25.5 W
 Example of power requirements in a PoE system


As illustrated in above Figure, six cameras, all PoE Class 2, are connected to one switch. Since a Class 2 device draws 7 W maximum from the switch, we can calculate the power requirements for a total of 6 cameras X 7 W = 42 W.

This will be the PoE power budget. Therefore, we need a switch with at least 42 W available for PoE.

Examples of  xPoE and powering calculation with Axis cameras

The examples present the concept behind the PoE and powering calculation for an Axis camera. The exact figures and products used in the examples may change over time.


High PoE with AXIS Q6032-E

The AXIS Q6032-E power input is specified in the datasheet as max. 60 W and in the Installation Guide (IG) it is specified as 50 W (max.). However, the midspan AXIS T8124 input is specified as max. 74 W.
Why is the input 50 W/60 W for the camera, but 74 W for the midspan?
The background for this is that the midspan itself consumes power and there is loss of power in the RJ45 cable from the midspan to the camera. Therefore, to ensure proper power to the camera, the midspan needs input and output power that is higher than the camera needs.
To conclude: input to the midspan is 74 W, and output from the midspan is 60 W, while input to the camera is 50 W.

PoE with P13xx-E

Some cameras are specified with two different classes of PoE. This is because products can require different wattages, depending on whether they are used with or without extra equipment, such as heating or cooling. The first PoE number specifies the wattage for the product itself, whereas the second number specifies the wattage needed for the product, including extra equipment. The AXIS P13xx-E is an enclosed product, and is specified as "PoE IEEE 802.3af max. 12.95 W or High PoE max 25.5 W".

Using Direct Current (DC) Midspan

DC may be used for certain applications, such as solar panels, and AXIS has the T81B22 30W DC midspan for just this purpose. T81B22 is specified as “51 V DC at: 12 DC IN (max. 30 W) or 24 V DC IN (max. 15 W)”.


PoE switch with P3384-VE

AXIS P3384-VE is specified as "Power over Ethernet IEEE 802.3af Class 3; max 12.1 W".

How can you find out what switch to use?
Usually the provider of the PoE switch describes three parameters that should be taken into account when deciding upon what switch to use. For example, the three parameters could be as follows:
·        Supplies power to PD: up to 15,4 W
This value is the maximum PoE power the switch can deliver per port, and is not related to total PoE budget. It is important to remember that it says "up to".
·        Total PoE budget:
The total PoE budget is what the switch can deliver in total PoE power on all ports. High value and few ports means a higher value of W per port. Low value and many ports mean a lower value of W per port.
·        Average PoE W / port: 13
Example: 50 W is the total PoE and the switch has 4 ports => 52 W / 4 = 13 W
This value is basically what the switch per port can handle if all PoE ports are being used. It is important to have a margin here to be on the safe side to know my device.
Basically, in this example, an 802.3af PoE switch would be suitable for the camera, and can be used to connect four AXIS P3384-VE’s.

Ensure the right PoE for environmental conditions

The PoE powering of a device becomes more critical depending on temperature. Many devices can function at different low temperature levels based on the amount of power available. It is imperative to verify the correct midspan is used for exterior cameras. AXIS P1344-E can operate down to -40°C when using high PoE.

Environmental
Surveillance cameras are often placed in environments that are very demanding. Failure to adequately protect an installed device from environmental factors can cause premature failure or void the product warranty.

Select the correct housing based on conditions

Camera housings come in various sizes and qualities, and various features. Housings are made of either metal or plastic and can be classified into two general types: fixed camera housings and dome camera housings.
When selecting an enclosure, several things need to be considered, including:
·        Side or slide opening (for fixed camera housings)
·        Mounting accessories
·        Clear or smoked dome (for dome camera housings)
·        Cable management
·        Temperature and other ratings (consider the need for a heater, sunshield, fan and wipers)
·        Power supply (12 V, 24 V, 110 V, etc.)
·        Level of vandal resistance

Ingress Protection Rating (IP Rating)

The IP Code classifies and rates the degrees of protection provided against the intrusion of solid objects (including body parts like hands and fingers), dust, accidental contact, and water in mechanical casings.

Solid particle protection

The first digit indicates the level of protection that the enclosure provides against access to hazardous parts (for example, electrical conductors, moving parts) and the ingress of solid foreign objects.
Level
Object size protected against
Effective against
0
-
No protection against contact and ingress of objects
1
>50 mm
Any large surface of the body, such as the back of a hand, but no protection against deliberate contact with a body part
2
>12.5 mm
Fingers or similar objects
3
>2.5 mm
Tools, thick wires, etc.
4
>1 mm
Most wires, screws, etc.
5
Dust protected
Ingress of dust is not entirely prevented, but it must not enter in sufficient quantity to interfere with the satisfactory operation of the equipment; complete protection against contact
6
Dust tight
No ingress of dust; complete protection against contact



Liquid ingress protection

Level
Protected against
Testing for
Details
0
Not protected
-
-
1
Dripping water
Dripping water (vertically falling drops) shall have no harmful effect.
Test duration: 10 minutes
Water equivalent to 1mm rainfall per minute
2
Dripping water when tilted up to 15°
Vertically dripping water shall have no harmful effect when the enclosure is tilted at an angle up to 15° from its normal position.
Test duration: 10 minutes
Water equivalent to 3mm rainfall per minute
3
Spraying water
Water falling as a spray at any angle up to 60° from the vertical shall have no harmful effect.
Test duration: 5 minutes
Water volume: 0.7 liters per minute
Pressure: 80–100 kPa
4
Splashing water
Water splashing against the enclosure from any direction shall have no harmful effect.
Test duration: 5 minutes
Water volume: 10 liters per minute
Pressure: 80–100 kPa
5
Water jets
Water projected by a nozzle (6.3mm) against enclosure from any direction shall have no harmful effects.
Test duration: at least 3 minutes
Water volume: 12.5 liters per minute
Pressure: 30 kPa at distance of 3m
6
Powerful water jets
Water projected in powerful jets (12.5mm nozzle) against the enclosure from any direction shall have no harmful effects.
Test duration: at least 3 minutes
Water volume: 100 liters per minute
Pressure: 100 kPa at distance of 3m
7
Immersion up to 1m
Ingress of water in harmful quantity shall not be possible when the enclosure is immersed in water under defined conditions of pressure and time (up to 1 m of submersion).
Test duration: 30 minutes
Immersion at depth of 1m
8
Immersion beyond 1 m
The equipment is suitable for continuous immersion in water under conditions which shall be specified by the manufacturer. Normally, this will mean that the equipment is hermetically sealed. However, with certain types of equipment, it can mean that water can enter but only in such a manner that it produces no harmful effects.
Test duration: continuous immersion in water
Depth specified by manufacturer

Determining the coverage area
When selecting cameras, the field of view required should be defined. The field of view is determined by the focal length of the lens and the size of the image sensor; both are specified in a network camera’s datasheet.
A lens’ focal length is defined as the distance between the entrance lens (or a specific point in a complicated lens assembly) and the point where all the light rays converge to a point (normally the camera’s image sensor). The longer the focal length of the lens, the narrower the field of view (FoV) will be.
The FoV can be classified into three types:
·        Normal view: offering the same field of view as the human eye.
·        Telephoto: a narrower field of view, providing, in general, finer details than a human eye can deliver. A telephoto lens is used when the surveillance object is either small or located far away from the camera. A telephoto lens generally has less light gathering capability than a normal lens.
·        Wide angle: a larger field of view with less detail than in normal view. A wide-angle lens generally provides good depth of field and fair, low-light performance. Wide-angle lenses sometimes produce geometrical distortions such as the "fish-eye" effect.
It is always advisable to take a snapshot from the camera to verify the coverage is correct and the depth of field is sufficient to capture the requirements. As depth of field changes with the available lighting, make certain to verify this multiple times per day.

Camera placement
When determining camera placement during installation, many factors must be taken into account. As mentioned in Camera Selection, the surveillance objectives decide what type of camera should be used, as well as how the camera should be placed.
Acquiring a useful image involves much more than simply pointing the camera at an object. Lighting, angle, reflections, dead zones, and the zoom factor for PTZ cameras are things to consider. Avoiding backlight and minimizing reflections are other factors that should be addressed. In some environments, in order to solve challenging scene problems, it’s easier to change the environment itself.
Camera placement is also an important factor in deterring vandalism. By placing a camera out of reach on high walls or in the ceiling, many spur-of-the-moment attacks can be prevented. The downside may be the angle of view, which can be compensated for to some extent by selecting a different lens.
The purpose of each camera should be clearly specified. If the aim is to get an overview of an area to be able to track the movement of people or objects, make sure that a camera suitable for the task is placed in a position that achieves the objective.
If the intention is to be able to identify a person or object, the camera must be positioned or focused in a way that will capture the level of detail needed for identification purposes. Local police authorities may also be able to provide guidelines on how best to position a camera.

Light considerations
For successful camera placement, light considerations are crucial. It is normally easy and cost-effective to add bright lamps in both indoor and outdoor situations to provide the necessary light conditions for capturing good images.
When mounting cameras outdoors, it is important to consider how the sunlight will change during the day. It is also important to avoid direct sunlight, as it will “blind” the camera and can reduce the performance of the image sensor. If possible, position the camera with the sun shining from behind the camera.
Camera angles

Detection zones and dead zones

The different ranges/zones of a camera are depicted in Figure XX. The line closest to the camera is where the maximum height is detectable. The yellow line illustrates the minimum required detectable height. The detection zone is in between these lines. These factors need to be addressed at the time of installation to ensure proper camera coverage.

Considerations during installation
For a successful installation, ensure the following:
·        The installer must ensure that he/she reads the included installation documentation.
·        The proper screwdriver, Allen wrench, etc. should be used, so as not to damage the mounting hardware.
·        The correct security tool should be used for vandal-resistant dome assemblies.
·        Ensure that all transport and packaging materials are removed from the dome assembly. This is very important especially for PTZ cameras, which is often packaged with a foam insert to protect the camera during transport.
Documentation
When performing a camera installation, make sure to document the installation properly.
This is not done for its own sake; there are many reasons for it. First of all, it is crucial for the user when it comes to future installations. Furthermore, it is a matter of security for the user to know vital safety and planning information, such as how the cables are wired. Proper documentation can also help to reduce customer calls.
All aspects of the physical installation should be documented during the actual installation process. This documentation should include, but not be limited, to the following:
·        Physical network layout showing all cable locations and the cable and port numbering scheme
·        Camera and server IP addresses
·        As-built floor plan showing camera locations
·        Camera parameter setup list
The documentation required by the end user can then be handed over at the proper time, allowing for the end user to verify the information and also make better use of the training provided prior to system startup.

End user training
End user training is one of the most important final tasks for the completion of an installation.
This step is required, not only to introduce users to new equipment but also to consolidate new processes and procedures which may have been introduced by the installation.
Training not only benefits the user, it benefits the integrator by reducing post-installation questions. It also allows end users to make much better decisions and use of the installed system.

The end user training will require documentation from the equipment manufacturer as well as integration technicians. All aspects of the system will need to be taught to the users. Various user groups might also require different training levels, from simple PTZ camera control and configuration to VMS recording and playback.

This Artical publish in safe secure magazine April 2017.