Sunday, August 16, 2015

iPhone and iPad Security Camera Apps

iPhone and iPad Security Camera Apps
As a well-known eSecurity Professional in India I got many appreciation call/mail for my Blog writing. Thanks to all of you for read and understand my wrong English writing on my blog. Recently I visit Bhubaneswar (Located in India, Capital of Orissa) and face some question, customer ask you people highlight our NVR/ DVR is support Remote viewing on iPhone & iPad, but we are not enjoy the benefits of mobile security camera monitoring. Our System Integrator / Installer technical person come and say something that we are not understands. So you’ve come to the right place. Many IP camera and NVR manufacturers have unveiled top-of-the-line mobile monitoring apps compatible with the iPhone and iPad. A list of manufacturer iPhone security camera apps and iPad security camera apps is provided below, each with a detailed description of noteworthy features.

Optica
iPhone & IPad Security Camera App Name: OpticaMobile & OpticaMobile HD
Optica, a leading manufacturer of high-definition IP cameras, offers OpticaMobile and OpticaMobile HD mobile apps designed for iPhone, iPad, and Android devices. OpticaMobile delivers a wide spectrum of features to improve the viewing experience for all Optica IP cameras, including quad-view mode, live video streams, bookmarking, audio, snapshots, dual stream support, and PTZ control of Optica’s P218Z speed dome. It’s an easy and convenient way to tap into your Optica IP camera system while on the go. OpticaMobile HD is built for use on the iPad, while OpticaMobile is compatible with iPhone and Android devices.

Milestone
iPhone & IPad Security Camera App Name: XProtect Mobile
Milestone is one of the leading providers of video management software. Always on the forefront of IP video technology, Milestone offers an iPhone security camera app designed for use with the iPhone 3GS, iPhone 4, iPhone 4S, iPhone 5, iPhone 6, and iPad. To use the iPhone and iPad app, you must first have Milestone’s free XProtect Mobile Server installed and configured, which you can download from the Milestone website. Once installed on your iPhone, you can view live video from several cameras simultaneously; play back recorded images; control PTZ cameras; connect to cameras from more than one site; and send images to others via MMS and email. It’s by far one of the best mobile monitoring apps out there.

Smartvue
iPhone & IPad Security Camera App Name: Smartvue 9
An all-star player in the NVR market, Smartvue offers a complimentary iPhone and iPad monitoring app compatible with a wide range of IP camera brands and styles such as Axis, Sony, Optica, Vivotek, and Panasonic. This innovative app allows you to view numerous cameras at once, slide through live images, connect to different cameras, change display options, see off-site camera monitors, view recorded video, and search archived footage. It’s easy to use, has an intuitive design, and operates through simple touch screen functions such as scrolling and pinch-to-zoom.

Vivotek
iPhone & IPad Security Camera App Name: Vivotek iViewer
The iViewer iPhone security camera app created by Vivotek is compatible with the iPhone 3GS, iPhone 4, iPhone 5, iPhone 6 and iPad devices. With the iViewer app installed on your iPhone or iPad, you can view your live camera feed anytime, anywhere. You’re not limited to just one camera either; the iViewer supports hundreds of live camera feeds from innumerable server connections. The app gives you complete control of your live video, including PTZ camera control, a snapshot command to capture specific video frames, real-time switching of cameras to change displays as needed, and saving your display settings. The app also features remote playback so you can browse through recorded images for peace of mind. Additionally, you can search recorded video via a date and time, and playback recorded video in time intervals of 1, 2, 5, and 10 minutes.

QNAP
iPhone & IPad Security Camera App Name: VMobile
NVR manufacturer QNAP offers a free mobile monitoring app called VMobile that works with most versions of the iPhone as well as the iPad. Using the VMobile app, you can view your IP cameras and playback recorded video from the VioStor NVR series. Unique to the VMobile app is its ability to connect with hundreds of network cameras of varied brands. You’ll have access to breakthrough mobile monitoring features like PTZ control, notification of events and snapshots, adjustable viewing modes, and recorded video playback.

Everfocus
iPhone & IPad Security Camera App Name: MobileFocus
Everfocus is one of the world’s most trusted manufacturers of CCTV camera systems and DVRs. The MobileFocus app supports multi-touch control for zooming in on images, quick access to preset positions, sequence mode, image snapshots of real-time video, PTZ control, full screen displays, live audio, and device management, among many other convenient features. The app currently works with all Paragon Series DVRs and HD Series DVRs.

Backup and Archiving

Backup and Archiving

Backup and archiving are always mentioned together, as both of these technologies support primary data storage. However, the commonalities end over here and cannot be carried forward. But in enterprise IT world it is often observed that archive is analogous to backup.
Simply put, backup and archive are not the same and here’s why explained in simple terms-

Data Backup

Data backup is intended to recover individual lost or corrupt files, or individually corrupt operating system instances. The backed up data has both active and inactive information which encompasses all of your production data. This backup set is useful for purposes of recovery in case of the original copy of data is lost or becomes inaccessible due to reasons. It is always critical that a backup is a copy of production data and the actual data still resides on the production storage systems.
Backups are historically being optimized for large scale recoveries. They are written in large blocks to dedicated hardware like tape libraries or deduplicated disk backup appliances.
On a typical note, these backups are scheduled, often every 24 hours, sometimes more frequently, even hourly with some continuous data protection solutions. The data driven by a backup is stored on a tape or a disk solution or off site like a cloud platform. Restoration from backup can be a complex and lengthy process depending on the volume of data to be restored.

Data archiving

Data archiving on the other hand, is data meant for long term retention, typically for compliance purposes in regulated industries such as finance and legal sectors. These are actually designed with very different access profiles. These systems typically store individual data objects such as files, databases or email messages and usually also capture metadata associated with each item.  The result is that an archive can provide immediate granular access to stored information and so accessing an individual file or email is typically very easy in an archive system.
Generally, archiving solutions which retain and index all copies and versions of a document, file, or email, making them easily are expected to be rapidly retrievable by end users rather than IT admins.

So, please do not treat your backups as archives or vice versa as same, as they serve for different purposes.

Friday, August 14, 2015

Installation of Camera In Harsh Environment

In this article, our aim to provide you some basic information about same standard which determine the outdoor working reliability. Outdoor Security cameras must be able to continue working properly. To achieve this, the security cameras must can effectively withstand in harsh conditions - such as rain, dust, wind, sand, salt, extreme hot and cold temperature etc. Many factors determine the camera whether they are suitable for specific outdoor critical environments.

1.       WEATHERPROOF STANDARD - INGRESS PROTECTION (IP)
To let user know whether certain products are suitable for certain conditions, some international organizations set standards that can indicate how effectively product can work in environment prone to water, dust, explosion and impact. Ingress protection is the most widely used one standard.


IP stands for ingress protection which is a standard (IEC-529) that specify how caable equipment can withstand the ingress, or entry, of dust or water. An IP is usually consisted of two numerals, the first digital indicates the level of protection that the enclosure provides against access to hazardous parts (e.g. electrical conductors, moving parts) and the ingress of solid foreign objects, the second digital indicates the protection of the equipment inside the enclosure against harmful ingress of water. For harsh environment, the security camera should be rated IP66 to IP68 as opposed to IP32 to IP54 for indoor environment.

2.       IMPACT PROTECTION - IK RATING
IK or impact protection, is the standard that specify degrees of protection provided by enclosures for electrical equipment against external mechanical impacts in accordance with IEC 62262:2002 and IEC 60068-2-75:1997. IK rating system ranges from IK00, or no protection, to IK10, or protection against 20 joules impact, equivalent to impact of 5kg mass dropped from 400 mm above impacted surface. Typically, vandal-proof security cameras utilizes high impact polycarbonate plastic dome. Tamper-resistant screws make the unit resistant to vandalism.

3.       SURGE PROTECTION
The majority of all surge-induced damage is caused by surges and spikes travelling along unprotected video, data, and power lines. These surges originally come from a wide variety of sources, including lightning strikes and static charge buildup. Surge protection can provide protection for both IP video surveillance and analog video surveillance systems which include front-end cameras, data lines, power lines, back-end storage DVR, NVR, as well as PoE switches. When security cameras are installed outdoor, extra surge protection is essential, surge protection is a smart investment in preventing not only equipment loss, but the potential loss of critical information.

4.       EXTREME LOW/HIGH TEMPERATURE
Users also need to consider the temperature factor if the camera is installed in extreme hot or low temperature degrees environment, the security cameras should be able to withstand these conditions. While typical security camera ought to have a working temperature range from -10 to 60 degrees Celsius, critical environment products should be able to work in a range between -40 and 70 degrees Celsius. Some IP cameras has built-in heater and fan to maintain the camera's inner temperature therefore allows camera to work in an extreme high/low environments.

5.       OTHER CUTTING-EDGE TECHNOLOGIES
Many other new technologies which has been implemented into security camera to enable them work in places that subject to danger or extreme weather conditions. Pelco by Scheider Electric released a series of products that have capability to withstand water and dust ingress, fog, high and low temperatures, winds of up to 57 meters per second, explosions, and corrosion by salt and different types of chemicals.

Many different technologies have been utilized to make those features possible. For example, some products feature the pressurized integrated optics cartridge (IOC) technology, which is able to protect the equipment from moisture and airborne contaminants and packages an auto-focus camera, lens, heater, and sensors in a small, self-contained, and sealed unit. Another cutting-edge technology is Dry nitrogen pressurized to 10 pounds per square inch gauge (PSIG), which protects the environment inside the cartridge, whereby sensors strategically placed in the cartridge send an alert message if changes in pressure, humidity, or temperature are beyond factory-set threshold points.

Some security cameras also feature heater, window defroster, sun shroud, and thermal insulation blanket to enable operation in temperature conditions ranging from as low as -46 degrees Celsius to over 49. In case the power failure during an ice store, the entire camera can deice itself and become operational in just two hours after power restore at a temperature as as -25 degrees Celsius.

Monday, July 20, 2015

Design of CCTV System

CCTV system design
Designing a CCTV system is a complex task, requiring at least basic knowledge of all the stages in a system, as well as its components. But more importantly, prior to designing the system, we need to know what the customer expects from it.

Understanding the customer’s requirements
The first and most important preparation before commencing the design is to know and understand the customer’s requirements. Customers can be technically oriented people, and many understand CCTV as well as you do, but most often they are not aware of the latest technical developments and capabilities of each component.
The most important thing to understand is the general concept of the surveillance the customer wants, Constant monitoring of cameras and activities undertaken by 24-hour security personnel, or perhaps just an unattended operation (usually with constant recording), or maybe a mixture of the two. Once you understand their general requirements, it might be a good idea to explain to them what is achievable with the equipment you would be suggesting. This is reasonably easy to accomplish with smaller and simpler systems, but once they grow to a size of more than 10 cameras some of which could be PTZs, a few monitors, more than one control point, a number of alarms, VCRs, and the like, things will get tougher.

Many unknown variables need to be considered: What happens if a number of alarms go off simultaneously? Which monitor should display the alarms? Will the alarms be recorded if the DVR/VCR(s) is/are playing back? What is the level of priority for each operator? And so on.

Those are the variables that define the system complexity and as in mathematics, in order to solve a system with more variables, one needs to know more parameters. They can be specified by the customer, but only after the customer has understood the technical capabilities of the equipment.

Understandably, it is imperative for you, as a CCTV expert, to know the components, hardware, and software you would be offering and to achieve what is required in the best possible way. You can create a favorable impression in the customer’s mind if at the end you give him or her as much as, or even more than, what you have promised. You will prove unsatisfactory if you do not. Remember that if the customer is fully satisfied the first time, chances are he or she will come back to do business with you again. To put it simply: Do not claim the system will do this and that if you are not certain; make sure your system delivers what you say it will.

So, to design a good, functional system, one has to know the components used, their benefits and limitations, how they interconnect, and how the customer wants them to be used. The first few parts are assumed to be fulfilled, since you would not be doing that job unless you knew a few things about CCTV. The last one – what the customer wants – can be determined during the first phone call or meeting.

Usually, the next step is to conduct a site inspection. Here is a short list of questions you should ask your customer prior to designing the system and before or during the site inspection:

• What is the main purpose of the CCTV system?
If it is a deterrent, you need to plan for cameras and monitors that will be displayed to the public.
If it is a concealed surveillance, you will need to pay special attention to the camera type and size, its protection, concealed cabling, and the like, as well as when it is supposed to be installed (after hours perhaps).

• Who will be the operator(s) ?
If a dedicated 24 hour guard is going to use the system, the alarm response needs to be different from that expected when unattended, or a partially attended, system operation.

• Will it be a monochrome or color system ?
The answer to this question will dictate the price, as well as the minimum illumination response.
Consequently, the lighting in the area needs to be looked at. A color picture will give more details about the observed events, but if the intention is to see images in very low light levels, or with infrared lights, there is no other alternative but B/W cameras (unless the customer is prepared to pay for some of the new cameras available on the market that switch between color and monochrome operation).
The price of a color system is dictated not only by the cameras, but also by the monitors, multiplexers, and/or quads (if any). Needless to say, sequential or matrix switchers, as well as time-lapse VCRs, are the same for both B/W and color.

• How many cameras are to be used ?
A small system with up to half a dozen cameras can be easily handled by a switcher or multiplexer, but bigger systems usually need a matrix switcher or a larger number of switchers and multiplexers.

• How many of the cameras will be fixed focal length and how many PTZ ?
There is a big difference in price between the two because if a PTZ camera is used instead of a fixed one, the extra cost is in the zoom lens (as opposed to the fixed one), the pan and tilt head or dome, the site driver, and the control keyboard to control it. But the advantages your customer will get having a PTZ camera will be quadrupled. If on top of this, preset positioning PTZ cameras are used, the system flexibility and efficiency will be too great to be compared with the fixed camera system. A system with only one PTZ camera and half a dozen fixed ones is a choice that may require a matrix switcher for control and will increase the price dramatically (compared to a system with only fixed cameras). Alternatively, single PTZ camera control can be achieved via a special single-camera digital or hard-wired controller, but they would also increase the price considerably. So, if a PTZ camera is required, it would be more economical to have more than one PTZ camera.

• How many monitors and control keyboards are required?
If it is a small system, one monitor and keyboard is the logical proposal, but once you get more operators and/or channels to control and view simultaneously, it becomes harder to plan a practical and efficient system. Then, an inspection of the control room is necessary in order to plan the equipment layout and interconnection.

• Will the system be used for live monitoring (which will require an instant response to alarms), or perhaps recording of the signals for later review and verification ?
This question will define whether you need to use DVR/VCR(s) with multiplexer(s). If you have a matrix switcher, you will still need a multiplexer or two in addition. Have in mind that the time lapse mode you are going to use depends on how often the tapes can be changed, and this defines the update rate of each camera recorded. Choose, whenever possible, a pair of 9-way (or 8-way) multiplexers instead of one 16-way, if you want to minimize the time delay in the recording rate update.

• What transmission media can be used on the premises ?
Usually, a coaxial cable is taken as an unwritten rule and installation should be planned accordingly. Sometimes, however, there is no choice but to use a wireless microwave or even a fiber optics transmission, which will add considerably to the total price. If the premises are subject to regular
lightning activity, you had better propose fiber optics from the beginning and explain to the customer the savings in the long run. So, you have to find out more about the environment in which the system is going, what is physically possible and what is not, and then plan an adequate video and data transmission media.

• Lastly and probably the most important thing to find out, if possible, is what sort of budget is planned for such a CCTV system?
This question will define and clarify some of the previous queries and will force you to narrow down either the type of equipment, the number of cameras, or how the system is expected to work. Although this is one of the most important factors, it should not force you to downgrade the system to something that you know will not operate satisfactorily.
If the budget cannot allow for the desired system, it is still good to go back to the customer with a system proposal that you are convinced will work as per his or her requirements (even if it is over budget) and another one designed within the budget with as many features as the budget will allow for. This will usually force you to narrow down the number of cameras, or change some from PTZ to fixed. The strongest argument you should put forward when suggesting your design is that a CCTV system should be a secure one, which can only be the case if it is done properly. Thus, by having a well-designed system, bigger savings will be made in the long run.

By presenting a fair and detailed explanation of how you think the system should work, the customer will usually accept the proposal.

Site inspections
After the initial conversation with the customer and assuming you have a reasonably good idea of what is desired, you have to make a site inspection where you would usually collect the following information:
• Cameras: type (i.e., B/W or color, fixed or PTZ, Resolution, etc.).
• Lenses: angles of view, zoom magnification ratio for zoom lenses (12.5–75 mm, 8–80 mm, etc.).
• Camera protection: housing type (standard, weatherproof, dome, discrete, etc.) mounting.
• Light: levels, light sources in use (especially when color cameras are to be used), east/west viewing direction. Visualize the sun’s position during various days of the year, both summer and winter. This will be very important for overall picture quality.
• Video receiving equipment: location, control room area, physical space, and the console.
• Monitors: Resolution, size, position, mounting, and the like.
• Power supply: type, size (always consider more amperes than what are required). Is there a need for an uninterruptable power supply (UPS)? (VA rating in that case).
• If pan/tilt heads are to be used: type, size, load rating, control (two wire – digital or multi-core). Is there a need for preset positioning (highly recommended for bigger systems)? Where are they going to be mounted? What type of brackets ?
• Make a rough sketch of the area, with the approximate initial suggestions for the camera positions. Take into account, as much as possible, the installer’s point of view. A small change in the camera’s position, which will not affect the camera’s customer. An unwritten golden rule for a good picture is to try and keep the camera from directly facing light.
• Put down the reference names of areas where the customer wants (or where you have suggested) the cameras to be installed. Also write down the reference names of areas to be monitored because you will need them in your documentation as reference points. Be alert for obvious “no-nos” (in respect to installation), even if the customer wishes something to be done. Sometimes small changes may result in high installation costs or technical difficulties that would be impossible to solve. It is always easier to deter the customer from making changes by explaining why in the initial stage, rather than having to do so later in the course of installation, when additional costs will be unavoidable.
To know more just read Condensed Code BS EN 62676-4 and BS EN 50132-7, BS EN 62676-4 Clause 4.4 & BS EN 62676-4 Clause 4.5.

Designing and quoting a CCTV system
With all of the above information, as well as the product knowledge (which needs constant updating), you need to sit down and think.

Designing a system, like designing anything new, is a form of art. As is true of many artists, your work may not be rewarded immediately, or it may not be accepted for some reason. But think positively and concentrate as if that is to be the best system you can propose. With a little bit of luck you may make it the best, and tomorrow you can proudly show it to your colleagues and customers. Different people will use different methods when designing a system. There is, however, an easy and logical beginning.

Always start with a hand drawing of what you think the system should feature. Draw the monitors, cameras, housings, interconnecting cables, power supplies, and so on. While drawing you will see the physical interconnection and component requirements. Then you will not omit any of the little things
that can sometimes be forgotten, such as camera brackets, types of cable used, and cable length. Making even a rough hand sketch will bring you to some corrections, improvements, or perhaps further inquiries to the customer. You may, for example, have forgotten to check what the maximum distance for the PTZ control is, or how far the operators are to be from the central video processing equipment, power cable distances, voltage drops, and so on.

Once you have made the final hand drawing, you will know what equipment is required, and it is at this point that you can make a listing of the proposed equipment. Then, perhaps, you will come to
the stage of matching camera/lens combinations. Make sure that they will fit in the housings or domes you intend to use. This is another chance to glance through the supplier’s specifications booklet. Do not forget to take into account some trivial things that may make installation difficult, like the coaxial cable space behind the camera (remember, it is always good to have at least 50 mm for BNC terminations), the focusing movement of a zoom lens (as mentioned earlier in the chapter on zoom lenses, in a lot of zoom lenses focusing near makes the front optical element protrude for an additional couple of millimeters), and so on.


The next stage is pricing the equipment – costs, sales tax and duty, installation costs, profit margins and the most important of all (especially for the customer) the total price.

Do not forget to include commissioning costs in there, although a lot of people break that up and show the commissioning figure separately. This is more of a practical matter, since the commissioning cost may vary considerably and it could take longer or shorter than planned. General practical experience shows that it will always take at least three times longer than planned. Also, in the commissioning fees, time should be allocated for the CCTV operator’s training.

After this step has been completed, you need to make a final and more accurate drawing of the system you are proposing. This can be hand drawn, but most CCTV designers these days use computers and CAD programs. It is easier and quicker (once you get used to it), and it looks better.
Also, the hand-calculated price needs to be written in a quotation form, with a basic explanation of how the system will work and what it will achieve. It is important for this to be written in a concise and simple, yet precise form, because quotations and proposals (besides being read by security managers and technical people) are also read by nontechnical people such as purchasing officers and accountants.

Often, spreadsheet programs are used for the purpose of precise calculation, and this is another chance to double-check the equipment listing with your drawing and make sure nothing has been left out. As with any quotation, it is more professional to have a set of brochures enclosed for the components you are proposing.

In the quotation, you should not forget to include your company’s terms and conditions of sale which will protect your legal position.

If the quotation is a response to a tender invitation, you will most likely need to submit a statement of compliance.

This is where you confirm whether your equipment complies or does not comply with the tender requirements. This is where you also have to highlight eventual extra benefits and features your equipment offers. In the tender, you may also be asked to commit yourself to the progress of the work and supply work insurance cover, in which case you will need a little bit of help from your accountant and/or legal advisor.


Many specialized companies only design and supply CCTV equipment, in which case you will need to get a quote from a specialized installer, who, understandably, will need to inspect the site. It is a good practice, at the end, to have all the text, drawings, and brochures bound in a single document, in a few copies, so as to be practical and efficient for reviewing and discussions.

Installation considerations
If you are a CCTV system designer, you do not have to worry about how certain cables will be pulled through a ceiling, raisers, or camera pole mounting; that is the installer’s job. But it would be very helpful and will save a lot of money, if you have some knowledge in that area. If nothing else, it is a good practice, before you prepare the final quotation, to take your preferred installer on site, so that you can take into account his or her comments and suggestions of how the practical installation should be carried out.

First, the most important thing to consider is the type of cable to be used for video, power, and data transmission, their distances and protection from mechanical damage, electromagnetic radiation, ultraviolet protection, rain, salty air, and the like. For this purpose it is handy to know the surrounding area, especially if you have powerful electrical machinery next door, which consumes a lot of current and could possibly affect the video and control signals. Powerful electric motors that start and stop often may produce a very strong electromagnetic field and may even affect the phase stability of the mains. This in turn will affect the camera synchronization (if line-locked cameras are used) as well as the monitor’s picture display.

For example, there might be a radio antenna installed in the vicinity, whose radiation harmonics may influence the highfrequency signals your CCTV system uses.
Mounting considerations are also important at both the camera and monitor end. If poles are to be installed, not only the height, but also the elasticity of the poles is important. Steel poles, for example, are much more elastic than concrete poles. If a PTZ camera is installed, the zoom lens magnification factor will also magnify the pole’s movement which could result from wind, or vibrations from the pan/tilt head movement itself. This magnification factor is the same as the optical magnification (i.e., a zoom lens, when fully zoomed in, may magnify a 1mm movement of the camera due to wind to a 1 m variation at the object plane).
The shape of the pole is also very important
– hexagonal poles are less elastic than round ones of the same height and diameter.
The same logic applies to camera and pan/tilt head mounting brackets. A very cheap bracket of a bad design can cause an unstable and oscillating picture from even the best camera.
If the system needs to be installed in a prestigious hotel or shopping center, the aesthetics are an additional factor to determine the type of brackets and mounting. It is especially important then not to have any cables hanging.

The monitoring end demands attention to all aspects. It needs to be durable (people will be working with the equipment day and night), or aesthetical (it should look good) and practical (easy to see pictures, without getting tired of too much noise and flashing screens).
Since all of the cables used in a system wind up at the monitoring end and in most cases this is the same room where the equipment is located, special attention needs to be paid to cable arrangement and protection.

Often, cables lying around on the floor for a few days (during the installation) are subject to people walking on them, which is enough weight to damage the cable characteristics, especially the coaxial cable impedance. Remember, the impedance depends on the physical relation between the center core, the insulation, and the shield. If a bigger system is in question, it is always a better idea to propose a raised floor, where all the cables are installed freely below the raised floor.
Sometimes, if a raised floor is not possible, many cables can be run over a false ceiling. In such cases special care should be taken to secure the cables as they could become very heavy when bundled together.

Larger installations may want a patch panel for the video signals.
This is usually housed in a 19'' rack cabinet, and its purpose is to break the cables with special coax link connectors so as to be able to reroute them in case of a problem or testing.
Many installers fail to get into the habit of marking the cables properly. Most of them would know all of the cables at the time of installation, but two days later they can easily forget them. Cable marking is especially critical with larger and more complex systems. Insist on proper and permanent cable markings as per your drawings. There are plenty of special cable-marking systems on the market. In addition, listing of all the numbers used on the cables should be prepared and added to the system drawings.

Remember, good installers differ from bad ones in the way they terminate, run, arrange, and mark the cables, as well as how they document their work.

Drawings
There is no standard for drawing CCTV system block diagrams, as there is in electronics or architecture. Any clear drawing should be acceptable as long as you have clearly shown the equipment used (i.e., cameras, monitors, VCRs) and their interconnection.
Many people use technical drawing aids, such as CAD programs, or other PC or Mac-based drawing packages. Depending on the system size, it might be necessary to have two different types of drawings: one of a CCTV block diagram showing the CCTV components’ interconnection and cabling requirements, while the other could be a site layout with the camera positions and coverage area. In smaller installations, just a block diagram may be sufficient.
The CCTV block diagram needs to show the system in its completeness, how the components are interconnected, which part goes where, what type of cable is used, and where it is used.
If the site layout drawing is well prepared, it can later be used as a reference by the installer, as well as by your customer and yourself when reviewing camera locations, reference names, and discussing eventual changes.
When the CCTV system is installed and the job is finished, drawings may need small alterations, depending on the changes made during the installation. After the installation, the drawings are usually enclosed with the final documentation, which should also include manuals, brochures, and other relevant documentation.


Commissioning
Commissioning is the last and most important procedure in a CCTV system design before handing it over to the customer. It involves great knowledge and understanding of both the customer’s requirements and the system’s possibilities. Quite often, CCTV equipment programming and setup are also part of this. It includes video matrix switcher programming, time-lapse VCR programming, camera setup, and so on.
Commissioning is usually conducted in close cooperation with the customer’s system manager and/or operator(s), since a lot of settings and details are made to suit their work environment.
The following is a typical list of what is usually checked when commissioning:
All wiring is correctly terminated.
Supply voltage is correct to all appropriate parts of the system.
Camera type and lens fitted are correct for each position.
Operation of auto irises under various light levels is satisfactory.
If VCRs are fitted, they should be recording in the most efficient time-lapse mode (especially when multiplexed cameras are being recorded).
If DVRs are installed, the pictures per second performance and image quality (compression setting) should be checked .
All system controls are properly functioning (pan/tilt, zoom, focus, etc.)
The setting of all pan and tilt limits is correct.
Preset positioning, if such cameras are used, is correct.
The level of supplementary lighting is satisfactory.
The system must continue to work when the main supply is disconnected, and a check should be made as to how long it does (if UPS is used).
Commissioning larger systems may take a bit longer than the smaller ones. This is an evolution from the system on paper to the real thing, where a lot of small and unplanned things may come up because of new variations in the system concept. Customers, or users, can suggest the way they want things to be done, only when they see the initial system appearance. Commissioning in such cases may therefore take up to a few days.
Commissioning under  BS EN 62676-4 Clause 4.6 & BS EN 62676-4 Clause 13.

Training and manuals
After the initial setup, programming, and commissioning are finished, the operators, or system users, will need some form of training.
For smaller systems this is fairly straightforward and simple. Just a verbal explanation may be sufficient, although every customer deserves a written user’s manual. This can be as simple as a laminated sheet of paper with clearly written instructions.

Every piece of equipment should come with its own User’s Manual, be it a time lapse VCR, a camera, or a switcher, but they have to be put together in a system with all their interconnections and this is what has to be shown to the customer. Every detail should be covered, especially alarm response and the system’s handling in such cases. This is perhaps the most important piece of information to the operators.

For larger systems, it is a good idea to bind all the component manuals, together with the system drawings, wiring details, and operator’s instructions, in a separate folder or a binder. Naturally, for systems of a larger size, training can be a more complex task. It may even require some special presentation with slides and drawings so as to cover all the major aspects.

Good systems are recognized not only by their functionality but also by their documentation.

Handing over
When all is finished and the customer is comfortable with what he or she is getting, it is time to hand over the system. This is an official acceptance of the system as demonstrated and is usually backed by the signing of appropriate documents.
It is at this point in time that the job can be considered finished and the warranty begins to be effective.
From now on, the customer takes over responsibility for the system’s integrity and operation.
If customers are happy with the job, they usually write an official note of thanks. This may be used later, together with your other similar letters, as a reference for future customers.
Documentation consider BS EN 62676-4 Clause 4.8, BS EN 62676-4 Clause 15.3 & BS EN 62676-4 Clause 16.

Preventative maintenance
Effective and regular maintenance of a CCTV surveillance system is essential to ensure that the system remains reliable at all times. It is advisable that maintenance of the CCTV system should be carried out by the company which installed the system. However, the maintenance company should have the means, including necessary spare parts and documentation, to meet the recommendations given here.
Note: This recommendation does not place an obligation upon customers who purchase their systems to have them maintained by the installing company. Maintenance is a matter of agreement between the customer and the installing company or a separate maintenance company. Maintenance comes under BS EN 62676-4 Clause 17 & SC CoP Guiding Principle 10.

The preservation of security within the maintenance company is of paramount importance and steps should be taken to ensure the safe keeping of all customers’ equipment and documentation relating to a particular installation/contract.

Note: BS EN 50132-7 states that “CCTV systems should be maintained in accordance with the schedule supplied by the system designer or supplier”, but does not detail any specific maintenance requirements. These guidelines give specific advice for the maintenance of CCTV surveillance systems, and provide examples of the type of documentation required to be used by the service company.

A maintenance company should ensure that adequate vetting of all employees is carried out. All employees, who visit a customer’s premises, shall carry identification cards which should include a photograph and signature of the bearer, the company’s name, contact details and a date of expiry (maximum of 3 years).
Each service technician employed by the maintenance company should carry a range of tools, test equipment and other equipment to enable them to perform their functions satisfactorily. Specialist tools, test equipment and plant should be available for deeper investigation if necessary.
Note: Disconnections, for whatever reason, should be recorded on a maintenance record and authorised by the client or his representative.
The maintenance company’s organisation should be so staffed as to ensure that the recommendations of this Code of Practice can be met at all times. The following factors should be taken into consideration:
1.       the number of installations to be serviced
2.       the complexity of the installations;
3.       the geographical spread of the installations in relation to the location of the maintenance company, its branches and its service personnel
4.       the method of calling out service personnel outside normal office hours, where applicable.
5.       Service personnel should be adequately trained and training should be updated whenever appropriate.
Maintenance Service is 3 types but scope of work is same.
A.   Preventive Maintenance service.
B.   Corrective Maintenance service.
C.   Performance Maintenance service.

http://arindamcctvaccesscontrol.blogspot.in/2014/09/service-and-maintenance-for-cctv.html


Note: The BS EN standards BS EN 62676-2-X comprising part 1, 2 and 3, provide detailed guidelines to manufacturers as to how they should implement IP video transmission products.

An end user is unlikely to benefit by reading the 62676-2-X standards. They may instead be involved in a buying decision which could place reliance on claims of conformance to the part of the BS EN standard the manufacturer chose to implement. Interoperability of equipment is not solely reliant on the requirements included in the BS EN standards in their current form. There is no guarantee that a product which simply claims BS EN 62676 compliance will provide full compatibility with another claiming the same compliance although it should allow for a minimum level of image transfer. 

Installers, users and specifiers should treat claims of interoperability between manufacturers products with caution. The parts of the BS EN standard which focus on interoperability, are 62676-2-2, which describes the PSIA guidelines for interoperability of IP Video devices, and 62676-2-3, which describes the ONVIF guidelines for interoperability.

ONVIF and PSIA, are at their base level, a common set of commands allowing basic communication between devices but this does not guarantee that the devices will function to the full potential of their design. Issues with product firmware and software should also be considered: a change of firmware / software versions should be tested separately to ensure continued interoperability. Whilst the specifications try to take this into account, the number of products claiming to be conformant currently makes this an impossible task.

Claims by product manufacturers that PSIA or ONVIF compliance means that users do not have to check that the products work together should be treated with great caution. It is strongly recommended that all such products are tested before being deployed.

Saturday, July 18, 2015

Difference between 1080p and 2160p

Difference between 1080p and 2160p 

1080p

1080p (aka Full HD/ FHD and BT.709) is a set of HDTV high-definition video modes characterized by 1080 horizontal lines of vertical resolution and progressive scan(p), as opposed to interlaced, as is the case with the 1080i display standard. The term usually assumes a Wide screen aspect ratio of 16:9, implying a resolution of 1920x1080 (2.1megapixel) often marketed as Full HD.



2160p
2160p is an alternative name for 4K UHD, a resolution supported by UHDTV products and which offers four times the definition of 1080p. The number 2160 stands for a display resolution which has 2160 pixels along the shortest side, while the letter p stands for progressive scan or non-interlaced. In a progressive image, the lines of resolution of the image go from the top of the screen to the bottom. The only planned higher definition format for television is 8K UHD.

Saturday, July 4, 2015

Fiber cabling with PoE for long-distance IP camera installation

Fiber optic cabling with PoE converters allows long-distance IP camera placement

Power over Ethernet (PoE) technology enables powering IP surveillance cameras through the transfer of DC electrical power along with data over standard unshielded twisted pair (UTP) cabling. This cabling connects to a network device through an RJ-45 port that injects the power from power sourcing equipment such as a PoE switch or midspan PoE injector. PoE provides a flexible and convenient means of powering devices that are located in out-of-the-way locations, and saves money by eliminating the expense and difficulty of direct electrical wiring. A challenge with PoE is reaching remote locations outside the distance limitation of UTP cabling. According to the TIA/EIA 568-5-A standard for category 5e cable, the maximum length for a cable segment is 100 meters (328 ft), and PoE power injectors or midspans do not increase the distance of the data link.

So, how do you get beyond that 100-meter limit? Once answer is through fiber optics. Fiber optic cabling is an effective method to overcome the distance and bandwidth limitations of UTP, and media converters are a commonly used to integrate copper network equipment and fiber. Since DC power cannot be conducted over fiber, PoE media converters are the solution to extend network distances via fiber to remote IP cameras. A PoE media converter converts the fiber to copper, and sends DC power to the camera over the UTP cabling.
How PoE Media Converters Work
On the main article image/PoE schematic that appears at right, an Ethernet switch with RJ-45 ports resides in a control room or data closet. The copper UTP cabling is converted to fiber with a standard media converter. The fiber is run a long distance to the PoE media converter located near a convenient AC or DC power source, where it converts the fiber back to copper UTP. The PoE media converter also functions as a power-sourcing mini switch, and injects PoE (DC power) over the UTP cable. At the other end of the UTP cable is the IP camera, located up to 100 meters away from the PoE media converter.

PoE media converters are available with Gigabit Ethernet and Fast Ethernet data rates and can support PoE (15.4 watts) or PoE+ (25.5 watts). PoE media converters function like PoE mini-switches, and are available in a variety of multi-port configurations, including dual RJ-45 and dual fiber ports. They can support fixed fiber connectors or small form pluggable transceivers.

To understand those power specifications, it’s worth knowing that in 2003, the IEEE ratified the 802.3af PoE Standard. That standard provides up to 15.4 watts of power per port. Late in 2009, the IEEE ratified the 802.3at PoE Standard known as PoE+ that provides up to 25.5 watts of power for each port. PoE+ can be required to power IP cameras with Pan-Tilt-Zoom (PTZ) capabilities, and weather-hardened cameras used in cold environments.
Key Features to Consider When Selecting a PoE Media Converter:
• PoE+ to future proof applications
• Out-of-the-box support for IEEE Alternative A and B, and Legacy Power detection
options (without the need for jumper wires or external cables)
• Jumbo Ethernet Frames to enhance throughput for reliable data flow
• Multiple port configurations for deploying a variety of architectures and topologies:
– Daisy chain media converters or install in ring topology
– Redundant fiber with less than 50ms switch over time
– Dual UTP ports for powering two PoE devices per converter
• Ability to be powered by either AC or DC power source
• Industrial hardened temperature ranges for outdoor applications
• Determines and delivers the specific power level required by the PD
• Fully configurable DIP-switches for easy set up:
– Link Fault Propagation Modes
– PoE Power Reset on fiber Rx loss that automatically resets



Leverage the Benefits of Fiber
There are several solutions available to extend the distances of PoE network links, including LAN extenders that convert Ethernet to DSL, UTP to coax converters and wireless technology. When you’re going long distance, however, fiber optic cabling provides several advantages over these technologies.

Unlike copper, fiber extends network distances up to 87 miles (140 kilometers) per link with no data deterioration over distance (signal deterioration is to be expected in copper cabling). LAN extenders can only extend network distances about 3,300 feet, but a data rate of 100 Mbps can drop by 70 percent at longer distances.

Fiber cabling provides security benefits as well. It is a secure medium that generates no electro-magnetic emission and is very difficult to tap. Fiber is also very reliable because it is not susceptible to electrical interference, or data loss due to temperature or atmospheric conditions.

Installation Steps
1) Please turn off the signal source and the device's power, installation with power on may damage the device;
2) Check if the network cable and other transmission line that will be used is occupied by other device;
3) Use a network cable to connect video to POE Ethernet Optical Transceiver's LAN port with PoE IP camera or other PoE network device;
4) Use two single mode double optical fibers to connect two converter's optical port, please attention the optical fiber which connect the RX and TX port should be across; that means one optical fiber, one side is to connect the optical module TX port, the other side should connect the RX port;
5) Check if the installation is correct and device is good, make sure all the connection is reliable and power up the system;
6) Make sure the Ethernet and PoE power supply is working normal.
Another Application:

Wednesday, June 17, 2015

Selecting a PoE Switch

You just picked up some new Power over Ethernet devices – a few of the hottest new IP cameras. However, after opening the box you run into a series of unexpected problems. No its a really powerful decision.
First: Each camera comes equipped with its PoE injector capable of supplying the appropriate level of power.  However, prior to even mocking up your panel it becomes clear – four PoE injectors and a standard Ethernet switch will not fit.
In an effort to maintain a reasonable panel size, you ditch the PoE injectors in favor of a Power over Ethernet switch, a single product that will replace all four injectors and provide Ethernet switching.  So far so good.

Second: After deciding that a PoE switch will best suit your need, you set out on a search for the cheapest PoE switch you can find.  Before long you realize the injectors were provided so that the cameras receive the exact amount of power they are optimized to run at.  With this new concern in mind, the search moves from the “cheapest switch” to the ”right switch.” In order to identify the right switch, you will need some information… but where do you look?

You are able to find a small label printed on the bottom near the Ethernet port of the camera – something that specifies how this camera can be powered. Now you have some numbers to shoot for, but what exactly do they mean?
While listed on the label in the above order, Power over Ethernet is best addressed in this order:-

1.     Is this a Power over Ethernet device?
A.     Will the device accept Power and data through the Ethernet port? Has the device been designed to make use of Power over Ethernet.

2.     Is this device IEEE 802.3af or IEEE 802.3at compliant?
A.     How much power will the device draw? Both IEEE 802.3af and 802.3at are based off +48VDC voltage but differ in wattage.
B.     IEEE 802.3af = “Standard PoE” = devices consuming up to 12.95W of PoE power IEEE 802.3at = “PoE Plus, High-Power PoE” = devices consuming up to 25.50W of PoE power

3.     Which class of Powered Devices (PD) is the device a member of?
A.     PoE capability and power level compliance – the class level of Powered Devices further specifies how much power the device will draw
Class 1 = 0.44 – 3.84W “Very low power”
Class 2 = 3.84 – 6.49W “Low power” 
Class 3 = 6.49 – 12.95W “Mid power” 
Class 4 = 12.95 – 25.5W “High power, suitable only for IEEE 802.3at PoE”


Translating the above power label again we find:
1.     Is this a Power over Ethernet device? Yes, this camera can accept PoE
2.     Is this device IEEE 802.3af or IEEE 802.3at compliant? IEEE 802.3af – the maximum it will draw is 12.95W at 48VDC
3.     Which class of Powered Devices (PD) is the device a member of? Class 2 – this device will draw between 3.84 and 6.49W – it is a “low power” device

After finding a Power over Ethernet switch that will provide suitable power conditions on a per-port basis, there is one final element to consider – power budget.
Will the switch you choose provide enough power per port for each camera? You bought four cameras to use four cameras, not to use just one or two.  Your choice in a Power over Ethernet switch needs to reflect this… Will the switch provide suitable power to all ports at all times?
Finally, after considering space in your panel, power demands of one camera, power ability of a switch for one port, and powering ability of a switch across all ports, you are prepared to make a decision!