Showing posts with label 720P. Show all posts
Showing posts with label 720P. Show all posts

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.

Friday, May 1, 2015

Resolution of Network Camera

Resolution of Network Camera
This time I will try to discuss the resolution of the image of the network camera. Resolution which is the number of pixels (pixel) different in each dimension that can be displayed. The greater the resolution of an image, the more have the number of dots and more detailed image will be displayed.
If you want to buy a camera network device that can display video images are detailed and clear, then you should choose a network camera that has high resolution. Currently network video camera technology has a lot to offer features Full HD resolution (1080p).But perhaps for the people of Indonesia arguably the price is still relatively expensive, because there are around 4 million more.
The following table resolution network camera.
Term
Horizontal Px
Vertical Px
Pixel
QSXGA
2560
2048
5.2MP
WQXGA
2560
1600
4.1MP
QXGA
2048
1536
3.1MP
WUXGA
1920
1200
2.3MP
UXGA
1600
1200
1.9MP
Full HD (1080p)
1920
1080
2MP
SXGA
1280
1024
1.3MP
960P
1280
720
HD
720P
1280
720
0.9MP
D1
720
480
NTSC/PAL
VGA
640
480
0.3MP
QVGA
320
240
0.1MP


Saturday, April 4, 2015

1080i VS 1080p The Difference

1080i vs. 1080p: What's the Difference?

Progressive (1080p) video is considered better than interlaced (1080i), but it's not always clear why; here's what's actually happening on your TV screen.
Today's HDTVs can display beautiful, 1,920 X 1,080-pixel video, but the actual quality of what you're viewing depends on the source material. A lot of the time, you're not seeing exactly 1080p. In fact, most TVs today have two modes with similar names: 1080i and 1080p. Both have the same screen resolution, so what's the difference between the two? Here are five things you need to know:

1080i video is "interlaced." 1080i video plays back at 60 frames per second, but that's a bit deceptive, because it's actually broadcast at 30 frames per second. The TV then displays those frames twice, the first pass is 1,920 X 540 for the even scan line field, and the second pass is 1,920 X 540 for the odd scan line field. The process by which this occurs is called interlacing. It contributes to a sense of motion and reduces perceived flicker.

1080p video is called "progressive scan." In this format, 1,920-by-1,080-pixel high-definition movies are progressively drawn line after line, so they're not interlaced. On paper, that may not seem like a huge deal. But in the real world, what you end up seeing looks sharper and more defined than 1080i, particularly during scenes with a lot of fast motion.
Sometimes 1080p is termed "Full HD" or "True HD," to distinguish it from 1080i or 720p video. Blu-ray discs contain 1080p video at 24 Frames Per Second, and then, using a method known as 3:2 pulldown, display it at 30 frames per second on screen.
Data compression can confuse the issue. Sometimes cable companies will deliver a 1080i picture, but then compress the data significantly in order to use up less bandwidth. The result can mean smeared details or pixelated color gradations in certain scenes. It's still technically HD, and still looks better than standard-definition cable, but it's not as good as it could be.
This also happens with 1080p streaming Internet video, but in that case, it's usually dependent on the speed of your data connection. In fact, Blu-ray is currently the only practical format for watching lots of pure 1080p content. Even the latest Apple TV, which supports 1080p streaming, does so in a compressed format that loses a bit of quality (although it still looks quite good).

Both formats look similar on smaller TVs. As a general rule, you need a larger TV to notice the difference between 1080i and 1080p. Depending on your eyesight, you can probably pick up the difference on a 32-inch LCD if you're particular about it. But most consumers don't really see a marked difference until at least a 42-inch screen, if not larger. In fact, many people are perfectly happy with 720p HDTV sets even at higher sizes; we recently named one, the 51" Samsung PN51E490B4F, best Choice for budget large-screen HDTVs.

1080p isn't even the best anymore. Technology never stands still, of course. Five years from now, you'll probably just want Ultra High Definition (aka 4K) video instead. (For a closer look at 4K video, check out What is Ultra HD?) But for now, if you're a videophile who appreciates a sharper picture, 1080p is definitely the way to go—both in HDTV capability and in the source material you're viewing.

Friday, February 27, 2015

Choose an HDMI Cable

How to Choose an HDMI Cable

Choosing an HDMI cable can be a complex task. There are several factors that must be considered in order to select the best HDMI cable to meet the user’s requirements:
·         HDMI standards compliance
·         HDMI Cable Categories
·         Cable length
·         Cable quality
·         Active cables
·         HDMI devices
·         Price

HDMI Standards Compliance
Each HDMI cable is rated to comply with a specific revision of the HDMI standards. A cable rated for HDMI 1.2a should meet the requirements of HDMI 1.0, 1.1 and 1.2, but is not guaranteed to meet the standards for HDMI 1.3.
HDMI Cable Categories
The HDMI standards define two cable categories. Category 1 HDMI cables support HDTV resolutions and frame rates. Category 2 cables are required for higher resolutions or higher frame rates.
Cable Length
The HDMI specification does not define a maximum cable length. HDMI cables are commonly available in 3′ to 50′ lengths.
Purchasing a cable longer than necessary will cost more money, but it will also increase signal loss due to attenuation.
Cable Quality
All other factors being equal, a cable that is built to higher tolerances using better materials will outperform a cable that is built merely to meet a standards specification. In addition, these premium cables will often provide longer service lives.
An HDMI cable can be made using 28 AWG wire, but a 24 AWG wire will create a sturdier cable that is more resistant to attenuation.
As with traditional analog stereo cables, premium HDMI cables are often furnished with gold plated connectors to ensure the best possible signal quality.
Active Cables
For specialized high end applications, some manufacturers are selling active HDMI cables. These cables use a variety of technologies that involve boosting the transmission distance or quality through the addition of electrical power to the cable connection.
Some of these active cables run over fiber optics or Cat-5 cable.
HDMI Devices
Another approach to supporting extremely long cable runs is to chain multiple HDMI cables together with amplifiers, repeaters, or equalizers.

Saturday, January 31, 2015

Principles of Surveillance System Installation

8 principles surveillance system installation

Safety awareness increases, Video surveillance systems into our lives. Video surveillance program are also more and more, So the first thing to consider installing surveillance systems of the following 8 major principles:

1.Real-time monitoring system
Real-time monitoring is very important, and it’s necessary for the Monitoring System.

2.Security
Security and confidentiality measures to prevent the illegal invasion and illegal operation system.

3.Scalability
Monitoring system equipment used modular structure, The system can be extended no need to change the structure of the network and hardware and software.

4.Openness
The system provides software, hardware , communications, networking , operating systems and database management systems and other aspects of the interface and tools that meet international standards , so that the system has good flexibility , compatibility , scalability and portability.The entire network is an open system that is compatible with a number of monitor manufacturers of products, and to support the secondary development.

5.Normative
Equipment and technology used in line with internationally accepted standards.

6.flexibility
System features full use of existing video surveillance subsystem networks. Monitoring can be used in different business, it is full-featured and easy to configure.

7.Advancement
Monitoring systems will become an advanced , future-proof , high reliability, confidentiality, easy network expansion , strong connection data processing capabilities, the system is running manipulate simple security system .

8.Applicability
Video surveillance systems have to complete the project in the required functional capacity and standards. Comply with the requirements of norms of domestic and foreign, and the advantages include ease of operation, Low- cost and high-performance.

Saturday, January 17, 2015

720p and 1080p explained

720p explained
720p is the shorthand name for a category of HDTV video modes. The number 720 stands for the 720 horizontal scan lines of display resolution (also known as 720 pixels of vertical resolution), while the letter p stands for progressive scan or non-interlaced.

Progressive scanning reduces the need to prevent flicker by filtering out fine details, so sharpness is much closer to 1080i than the number of scan lines would suggest. A 720p frame has about 1 million pixels. Compared to it, a 1080p frame has 2 million pixels so the amount of detail doubles. However in practice the difference between 1080p vs 720p is not as obvious as the one between standard definition vs high definition (480p vs 720p). For example a regular DVD isn’t even considered high definition because it is either 720×480 (NTSC) or 720×576 (PAL) but it looks much better than regular NTSC or PAL TV broadcasts and not as great as 720p. That being said, you do get more detail from 1080p than from any resolution if you have the “winning” formula for screen size, resolution and viewing distance – that is if you have the optimum conditions to get the most out of 1080p.

1080p explained:
The number 1080 represents 1,080 lines of vertical resolutions (1,080 horizontal scan lines), while the letter p stands for
progressive scan (meaning the image is not interlaced). 1080p can be referred to as full HD or full high definition although 1080i is also “Full HD” (1920×1080 pixels). The term usually assumes a widescreen aspect ratio of 16:9, implying a horizontal resolution of 1920 pixels. This creates a frame resolution of 1920×1080, or 2,073,600 pixels in total.

The only pure 1080p content comes from high definition DVDs like Blue Ray and HD DVD. Regular DVDs are way below that, having just 480p or 576p. You also get HD content from TV broadcasts but for now only 1080i and 720p. Basically 1080i offers pretty much the same amount of detail as 1080p but the quality of fast moving scenes is a bit inferior to 1080p. To understand this better read the 1080p vs 1080i guide. 720p content will of course look the same (or very similar) on a 1080p screen as it does on a 720p screen because what also matters is the content resolution not just the screen resolution.

Here is a sample with the difference between 720p and 1080p:
480i - Total image resolution 337,920 pixels
480p - Total image resolution 337,920 pixels
720p - Total image resolution 921,600 pixels (roughly equivalent to a 1 mega pixel camera)
1080i - Total image resolution 2,073,600 pixels (equivalent to a 2 mega pixel camera)
1080p - Total image resolution 2,073,600 pixels (equivalent to a 2 mega pixel camera)

More lines is nice but don't forget about the 'p' and 'i' in the 720p, 1080i and 1080p. The letter is an abbreviation for the type of scan the TV uses -- 'p' stands for progressive and 'i' stands for interlaced.

Monday, November 24, 2014

To 4K or not 4K video or Ultra HD

To 4K or not to 4K video or Ultra HD
Our industry’s seemingly insatiable appetite for more and more resolution has now produced a wave of interest in 4K cameras that promise exceptional clarity and sharpness, akin to the big screen, Ultra HD television sets found in consumer electronics stores and an increasing number of North American homes.
The jury is still out on whether there is an immediate need for the resolution that can overcome the downsides of increased storage and bandwidth required for running 4K cameras in a surveillance operation. Like so many things, if the cost of the camera, cost of the supporting system infrastructure and components were of no concern, this new format would likely be a more viable and attractive option for many security applications.

Here are four things to consider before making the leap to investing in and deploying 4K video:

1. What will I get with 4K that is not possible at lower resolution?
There’s no doubt that 4K technology is light years ahead of analog quality, but the reality is that the increased clarity and sharpness provided by that level of resolution is often over and beyond what is required and able to be managed by a typical security operation. For many reasons, full HD/1080P is the most commonly used resolution for new systems. The majority of security systems in use for live monitoring situation do not really benefit from such a resolution, as the human eye is well served with the details of a 1080P picture. Higher resolutions pay out when more details are required in forensic investigations.

2. Double the resolution, double the processing requirements
Users typically want to see more than one camera on one monitor, and only  occasionally switch to full screen modes. With 4K, the clarity of that multi camera view would be no clearer than what would be viewed from a lower resolution camera. In addition, delivering streams from multiple 4K cameras presents some technical challenges. The client PC and graphics card must handle a significant flow of data. The best approach is to have the live view limited to only enough resolution for the video size and screen resolution of the display.
Today a typical approach to balance PC power requirements and quality uses lower resolution streams for live view, while recording in the highest resolutions. 4K resolution taxes the workload on the network because recording the highest resolution means the full stream content moves from the camera to the NVR.

3. Limitations on form factors, lenses
The availability of affordable high resolution optics is just not there yet, and a dome style camera with a typical curved dome bubble cannot transmit the 4K resolution. In addition, a true 8MP resolution lens with appropriate coverage for the 4K sensor is quite large, which would render a 4K version of the compact dome camera (the market’s favorite form factor) essentially not possible.  The dome camera would get physically bigger which, for many customers, is a negative.

4.  Bandwidth and storage requirements
From a cost perspective, quadrupling the resolution from full HD to 4K won’t quite double the camera price. However, on the recording side it will most definitely demand more than double the storage requirements when operating under the same conditions.

Bandwidth consumption is related to processor power available on the camera. For example, the average full HD cameras deliver about 6Mbps at 30 ips. On the bright side, some manufacturers are offering full HD models with advanced compression capabilities that can reduce bandwidth consumption to about 3Mbps, with the next iteration to handle 4K video at full HD bandwidth consumption levels. Additionally new compression standards such as H.265 HVEC (High Efficiency Video Encoding) will make higher resolution bandwidth more practical for surveillance.

So where does this leave you, 4K today or not just yet? For some customers a bigger number is frequently perceived as a better solution but surveillance installations should focus on the reason the system investment is being made in the first place; protection of personnel and protection of assets. It is far from a one size fits all decision and resolution is an important tool in the system solution.

Next benchmark for video surveillance cameras is going to be the Ultra HD standard, with a resolution of 3840 x 2160 – around 8MP. Given the challenges networks may face carrying Ultra HD video streams it’s hard to say just when we will see the technology reach a tipping point.

THERE are a couple of signs worth paying attention to with Ultra HD (commonly called 4K in consumer and CCTV industries). The first is that UHD consumer monitors, which are now dropping in price at a time many homeowners’ first 1080p HD monitors may be starting to look a little tired. Something else to bear in mind is the consensus forming in digital photography that 8MP is the sweet spot that allows the best balance of low light performance and high resolution.

As most readers know, the more pixels you cram onto an imager, the smaller those pixels must be. And the smaller the pixels, the less light they can absorb. Double the number of pixels on a 1/3-inch HD sensor and you halve the light reaching the sensor. The result is that more pixels does not a perfect camera make – not unless sensor sizes increase. If it’s all about display images today, then 3MP cameras with a 1080p resolution are ideal.

But if you need digital zoom or you use a UHD monitor, then Ultra HD cameras should be a consideration. If you zoom in 2x digital with an Ultra HD image then you are viewing at 2MP, which is pretty good considering how quickly it takes an HD camera to burrow down under 4CIF when digital zoom is applied. 

Something else to bear in mind when considering digital image quality is that pixels on a digital camera’s sensor capture light in red, blue or green – not all colours at once. A layout will be a pair of green, a red and a blue in a grid pattern and onboard software then nuts out the colour value for pixels. This means there’s signal attenuating averaging going on in the background - one colour per 4 pixels.

A camera’s digital engine is also working hard to stave off false colours and moire – spacial aliasing that causes false patterns in a scene. Camera engines will blur an image slightly then sharpen it in order to lose such artifacts. Clearly, the more pixels, the more work the camera processor has to get through and this can be noticeable as latency or blurring if there’s sudden movement – like cars moving at right angles across a scene.

Lenses are another issue. An Ultra HD camera is going to need a quality lens and there’s no doubt that plenty of 1080p cameras are being sold with lenses that are not perfect. Sure, things look good in the centre of the image but out towards the edges details get muddy, especially on the sorts of deep zooms that might motivate a buyer to choose Ultra HD in the first place.

Sensor noise is also something that has to be considered at multiple levels. In low light, cameras increase exposure, elevating noise levels. Furthermore, pixel measurements are never perfect and the flaws in these signals show up on a monitor as noise. It’s unhelpful during the day and blinding at night. Digital noise reduction is the answer but DNR processing doesn’t just lose noise, it sloughs fine detail off a scene. When you look at a camera being tested in low light you can often see the areas where DNR has scrubbed and smudged a scene free of detail. It’s not a good look.

Engineers can build high resolution imagers with fewer noise problems but they need to be big – 1-inch or 1/1.5 inch sensors are ideal. A 1/1.5-inch sensor has 4x the area of the 1/3-inch sensors that typically run inside 1080p CCTV cameras. No wonder GBO’s S1080 camera (BGWT sells them in Australia) with its monster 1-inch sensor has such a great image in low light.

If the sensors are large enough, the lenses are good enough, the network is capable enough and the storage sufficient, then Ultra HD cameras will give end users a lot more detail than 3MP 1080p cameras can. But this capability has to be balanced against many things. Image quality is about more than megapixel count. 

“If a sensor is of the similar size as the equivalent HD sensor and it has 4x the pixels - low light performance will be 4x lower. And streaming bandwidth will be close to 4x larger unless better compression is used”

Keep in mind,
4K =     8.3 megapixels, aspect ratio 16:9 Horizontal resolution
1080p= 2.1 megapixel,  aspect ratio 16:9 Vertical resolution
720p=   1.3 megapixel,  aspect ratio 16:9 Vertical resolution

D1=      0.4 megapixel,  aspect ratio   4:3 Vertical resolution

Friday, August 15, 2014

Embedded Network Video Recorders (NVRs) over Windows-based NVRs Comparison

Embedded Network Video Recorders (NVRs) over Windows-based NVRs Comparison
Video surveillance users who opt for an NVR using an embedded, dedicated Linux operating system within a self-contained unit will benefit from performance which is superior to that offered by a Windows-based NVR in terms of ease of use, system stability and decoding capability.

Embedded NVRs are distinguished from WINDOWS-based NVRs primarily on how they operate and the features they provide. The stand-alone NVR comes in a single, compact enclosure. By contrast, a WINDOWS-based NVR is a peripheral addition to a system involving a CPU, keyboard and monitor. In confined locations, an embedded unit performs a similar if not wider range of functions while occupying less space. Embedded NVRs have overcome their perceived shortcomings in terms of storage capacity and types of storage medium through use of devices including IP-SAN, eSATA, NAS (network-attached storage) and Fire wire.  Furthermore, embedded NVRs can support interfaces to other surveillance devices which can be conveniently integrated with alarm systems and access control systems as well as PTZ remote control systems.

Functions common to the two approaches
Some common functions between the two video recording solutions in the surveillance market, it will be useful to list the core functions that are common to both approaches. These include: recording; archiving; display; playback; search on parameters such as date, timeline and event; camera management; triggered recording on prescribed events and export to removable media. NVRs are also usually expected to be able to handle VoIP packets. Once digitalized video has been streamed, end-users expect to be able to treat it like any other network data, viewing it locally, on LANs and remotely from web browsers. They also expect to be able to exercise PTZ control over cameras remotely, configure settings and even perform upgrades remotely.

Storage
Although NVRs have ample internal recording and storing space, the PC-based systems offer as much as seven times more storage, when compared to an NVR. This advantage is, however, addressed by NVRs, through the provision for external storage options (USB storage devices, eSATA devices, Firewire storage devices, NAS appliances, etc.)

Reliability
The precise architecture of the embedded NVR units makes them less prone to crash. However, the WINDOWS methodology for NVRs is certainly 'open' in terms of the addition of external storage, installation of software etc. The controls are embedded into the NVR; they are an integral part of the panel rather than an adjunct, and the activity of operators can therefore be more easily restricted to legitimate usage.

Stability
Unlike a WINDOWS-based unit which is likely to run a range of Windows™ applications, an embedded NVR benefits from the stability that comes with Linux code which is optimized to run only applications relevant to the surveillance tasks required. An embedded operating system contains only the software components necessary for the specific functions of the NVR, and the unit will be supplied with optimum configurations straight from the factory after rigorous testing.

Scalability
An NVR is designed to offer optimal performance for a set number of cameras, and is normally less scalable than a WINDOWS -based system. This makes the unit suitable for smaller systems where the number of cameras stays within the limits of an NVR’s designed capacity.

Boot Time
The NVR runs an embedded operating system as compared to a WINDOWS -based system, which needs to run an application under the Windows OS before it begins recording. This means that the NVR will start faster as compared to the WINDOWS -based system; which will take longer to load.

Complex decoding
Embedded NVRs consistently outperform WINDOWS-based solutions in their ability not only to perform complex decoding but also to give the user reliable video playback and preview. Currently, certain NVRs are among the few units which can perform both local decoding and playback, with decoding of up to 16 channels at 1080p being achievable. The processing demands made on a WINDOWS-based solution to achieve comparable performance are far higher than those required of an embedded device, and necessitate powerful, expensive CPUs.

Power consumption and manufacturing carbon footprint
Embedded technologies are helping the surveillance industry to go green in marked contrast with the WINDOWS approach. The power consumption of an embedded NVR is approximately 70W which is less than an incandescent light bulb. By contrast, the likely power consumption of a WINDOWS capable of running an NVR is approximately 200 watts and together with a large enterprise-grade monitor, the total figure will be about 300 watts. For any end-user mindful of their carbon footprint, these figures alone must do much to settle the debate.

Ease of Use
Embedded NVRs can have operating panels based on the very best intuitive design principles. LED signals, digital inputs and outputs, push buttons and dials can all be arranged in an ergonomic way. Sensible layout in a panel approach rather than a screen-based GUI can replicate the ease of use found in a WINDOWS but without the vulnerabilities described above.

ONVIF
Linux based Network Video Recorder for multi-brand and ONVIF compliant multi-megapixel IP cameras and basic automation.