Comparison XGIMI Horizon vs XGIMI H3
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|---|---|---|
| XGIMI Horizon | XGIMI H3 | |
from $952.90 | Outdated Product | |
| TOP sellers | ||
Harman/Kardon audio system. The difference between XGIMI Horizon models and XGIMI Horizon Pro is the real resolution. | Intelligent lateral tilt compensation. | |
| Main function | home | home |
| Operating system | Android TV 10.0 | Android 8.1 |
Lamp and image | ||
| Lamp type | LED | Laser-LED |
| Service life | 30000 h | 30000 h |
| Brightness ANSI Lumens | 1500 lm | 1900 lm |
| Colour rendering | 1.07 billion colours | 1.07 billion colours |
Projection system | ||
| Technology | DLP | DLP |
| Size | 0.47" | 0.47" |
| Real resolution | 1920x1080 px | 1920x1080 px |
| Max. video resolution | 4096x2160 px | |
| Image format support | 4:3, 16:9, 16:10 | 4:3, 16:9, 16:10 |
| HDR support | HDR10 / HLG | + |
Projecting | ||
| Rear projection | ||
| Throw distance, min | 1 m | |
| Throw distance, max | 7 m | |
| Image size | 40 – 200 " | 30 – 300 " |
| Throw ratio | 1.2:1 | 1.2:1 |
| Zoom and focus | motorized (remote-controlled) | motorized (remote-controlled) |
| Autofocus | ||
| Auto keystone correction | ||
| Keystone correction (vert), ± | 40 ° | 40 ° |
| Keystone correction (horizontal), ± | 40 ° | 40 ° |
Features | ||
| Features | light sensor DLNA support voice control voice assistant | DLNA support 3D support voice control voice assistant |
| Bluetooth | v 5.0 | v 4.0 |
| Wi-Fi | Wi-Fi 5 (802.11ac) | Wi-Fi 5 (802.11ac) |
| AirPlay | + | |
| Google Cast (Chromecast) | ||
| Miracast | ||
| Audio decoders | DTS, DTS-HD, Dolby Digital | |
Hardware | ||
| CPU | Mstar 6A848 | |
| RAM | 2 GB | 3 GB |
| Built-in memory | 32 GB | 16 GB |
| USB-A 2.0 | 2 pcs | 2 pcs |
| Speaker system | Harman Kardon | Harman Kardon |
| Number of speakers | 2 | 2 |
| Subwoofer | ||
| Sound power | 16 W | 16 W |
| HDMI inputs | 2 | 2 |
| HDMI version | v 2.0 | v 1.4 |
| Audio connectors | 3.5 mm output (mini-Jack) optical | 3.5 mm output (mini-Jack) optical |
| Service connectors | LAN (RJ-45) | LAN (RJ-45) |
General | ||
| Noise level (nominal) | 28 dB | |
| Power source | mains | mains |
| Power consumption | 180 W | |
| Size (HxWxD) | 136x208x218 mm | 144x215x205 mm |
| Weight | 2.9 kg | 2.75 kg |
| Color | ||
| Added to E-Catalog | july 2021 | april 2020 |
Compare XGIMI Horizon and H3
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Glossary
Operating system
— Smart TV (proprietary system). The operating system of the projector is represented by the proprietary software shell of the manufacturer. Usually such operating systems have an attractive and convenient menu, similar to a traditional Smart TV. A proprietary operating system is developed by the manufacturer for the hardware resources of a particular projector model or a whole line. But, as practice shows, compared to the classic Smart TV, the functionality of proprietary system often has significant limitations, and the system itself, in fact, is a stripped-down version of a full-fledged Smart TV.
— Smart TV (Android AOSP). This type of operating system is a modification of the popular Android OS, mainly notable for being open source. It is a versatile operating system that gives the user much more freedom to create changes and customizations within the system. At the same time, the installation and work stability of certain applications on this platform are not guaranteed, and the overall system management was not specially “tailored” for large screens, which may cause some inconvenience. First of all, such solutions will will generate interest among users who understand the features of the Android OS, like to customize and control everything, and have time for this.
— Android TV. This type of projector has full-fledged Android TV software, spec...ially adapted to work on large screens. In accordance with the name, it is a type of Android OS, specially designed for projectors/TVs, etc. In addition to the common features of all “Androids” (such as the ability to install additional applications, including even games), it has a number of special features: optimized interface, integration with smartphones (including the ability to use them as a remote control), voice search, etc. Thanks to this, TVs with this feature are significantly superior in functionality to models with a Smart TV. Of course, a dedicated processor, graphics subsystem and memory are provided for the operation of a multifunctional OS, and the presence of such hardware resources is reflected in the total cost of the projector. Given the same optical design, models with Android TV will cost more than classic projectors with a simple multi-line menu.
Lamp type
— HD (High-intensity discharge). General name for gas discharge lamps, i.e. lamps in which the light flow is created by an electrical discharge between the electrodes inside the bulb. In the case of projectors, such lamps can be mercury, metal-halide, and xenon (see above for more details).
— LED. LEDs are used as a light source. They provide high brightness with low power consumption.
— Laser-LED. Light source based on laser LEDs. It has even greater brightness than classic LED, with relatively low power consumption.
— UHP (Ultra-high performance) — a high-pressure mercury lamp, developed by Philips. Compared to other lamps, it consumes less power, while not inferior in brightness. Projectors on such lamps are smaller and lighter than conventional ones due to a smaller power supply, the cooler operates with a lower noise level. The creators claimed a service life of up to 10,000 hours. One of the most popular types of lamps for projectors today
– UHE (Ultra-High Energy). Variety of UHP lamps (see above).
— UHB (Ultra-high brightness). Another kind of UHP lamps (see above).
— NSH (New Super High Pressure). Also applies to high pressure mercury lamps manufactured by Ushio. Somewhat less popular than UHP and its peers, but also widespread. Estimated operating time is about...2000 hours.
— SHP. High pressure mercury lamps manufactured by Phoenix.
— P-VIP (Video Projector) — a high-pressure mercury lamp from OSRAM. High brightness lamps, service life — 4000 — 6000 hours.
—UHM (Ultra High Performance Lamp of Matsushita) is a high pressure mercury lamp manufactured by Panasonic. Сan be easily changed, operating time, depending on type — 2000 — 5000 hours.
— Xenon. The design and principle of operation of such lamps are similar to high-pressure mercury lamps — light is created due to a discharge in a gaseous medium. However, instead of mercury vapor, in this case, an inert xenon gas under high pressure is used. This allows to create high power lamps (from 2 kW) with the appropriate light flow. Xenon lamps are used primarily in professional models.
— HPM. High-pressure mercury lamp technology developed by Sony and used primarily in its projectors (although other brands are also available). Combines compact size and relatively low cost with high brightness.
— DC. Abbreviation for "direct current". In the case of projector lamps, this designation usually refers to mercury lamps powered by direct current. The operating voltage of such lamps in different models of projectors may be different. Their design usually uses various tricks to improve performance compared to conventional lamps of this type — in particular, increase service life and reduce power consumption without sacrificing brightness.
— AC. This abbreviation stands for "alternating current". Such lamps are similar in almost everything to the DC ones described above, differing from them only in the type of power supply.
— LED. LEDs are used as a light source. They provide high brightness with low power consumption.
— Laser-LED. Light source based on laser LEDs. It has even greater brightness than classic LED, with relatively low power consumption.
— UHP (Ultra-high performance) — a high-pressure mercury lamp, developed by Philips. Compared to other lamps, it consumes less power, while not inferior in brightness. Projectors on such lamps are smaller and lighter than conventional ones due to a smaller power supply, the cooler operates with a lower noise level. The creators claimed a service life of up to 10,000 hours. One of the most popular types of lamps for projectors today
– UHE (Ultra-High Energy). Variety of UHP lamps (see above).
— UHB (Ultra-high brightness). Another kind of UHP lamps (see above).
— NSH (New Super High Pressure). Also applies to high pressure mercury lamps manufactured by Ushio. Somewhat less popular than UHP and its peers, but also widespread. Estimated operating time is about...2000 hours.
— SHP. High pressure mercury lamps manufactured by Phoenix.
— P-VIP (Video Projector) — a high-pressure mercury lamp from OSRAM. High brightness lamps, service life — 4000 — 6000 hours.
—UHM (Ultra High Performance Lamp of Matsushita) is a high pressure mercury lamp manufactured by Panasonic. Сan be easily changed, operating time, depending on type — 2000 — 5000 hours.
— Xenon. The design and principle of operation of such lamps are similar to high-pressure mercury lamps — light is created due to a discharge in a gaseous medium. However, instead of mercury vapor, in this case, an inert xenon gas under high pressure is used. This allows to create high power lamps (from 2 kW) with the appropriate light flow. Xenon lamps are used primarily in professional models.
— HPM. High-pressure mercury lamp technology developed by Sony and used primarily in its projectors (although other brands are also available). Combines compact size and relatively low cost with high brightness.
— DC. Abbreviation for "direct current". In the case of projector lamps, this designation usually refers to mercury lamps powered by direct current. The operating voltage of such lamps in different models of projectors may be different. Their design usually uses various tricks to improve performance compared to conventional lamps of this type — in particular, increase service life and reduce power consumption without sacrificing brightness.
— AC. This abbreviation stands for "alternating current". Such lamps are similar in almost everything to the DC ones described above, differing from them only in the type of power supply.
Brightness ANSI Lumens
This parameter largely determines the ability of the projector to work in a well-lit room. For a dark room, 1000 lumens is enough to make the projection picture bright, rich, clear and understandable. But when working in a lit room, the projector will need at least 3500-4000 lumens. Do not confuse ANSI lumens with Peak lumens. These are two different brightness standards. To convert one type of brightness to another, you need to multiply Peak lumens by 10-12. The result will be an approximate value of ANSI Lumens.
However, experts do not recommend chasing high ANSI lumen brightness values. There are many professional projectors with brightness up to 3500 lm. The lower the brightness, the lower the power consumption, and at the same time, the life of the illuminator increases. Of course, if the projector will be installed in a work office or classroom where good lighting is required, it is recommended to purchase a model with ANSI Lumens brightness of 4000 lumens and more.
Max. video resolution
The actual maximum frame resolution that the projector is capable of processing and displaying.
Many models allow project images at a higher resolution than the actual resolution of the projector matrix (see above). For example, a 1920x1080 video can be displayed on a device with a frame size of 1024x768. However, the quality of such an image will be noticeably lower than on a projector, which initially has a resolution of 1920x1080.
The maximum resolution is closely related to both the overall picture quality and the size of the projection screen. The higher the resolution, the sharper the image details become. Of course, the screen size itself should be taken into account. The fact is that on a 40-50″ projection surface there will not be much difference between the Quad HD and 4K formats. A high-resolution picture will be able to show itself on a truly large screen.
Many models allow project images at a higher resolution than the actual resolution of the projector matrix (see above). For example, a 1920x1080 video can be displayed on a device with a frame size of 1024x768. However, the quality of such an image will be noticeably lower than on a projector, which initially has a resolution of 1920x1080.
The maximum resolution is closely related to both the overall picture quality and the size of the projection screen. The higher the resolution, the sharper the image details become. Of course, the screen size itself should be taken into account. The fact is that on a 40-50″ projection surface there will not be much difference between the Quad HD and 4K formats. A high-resolution picture will be able to show itself on a truly large screen.
HDR support
Support for HDR technology — expanded dynamic range — by the projector.
This technology allows for extending the brightness range displayed within a single frame — in simpler terms, it enables displaying both very bright and very dark colors on screen simultaneously. This significantly improves color reproduction; furthermore, small details on very bright or very dark parts of the frame that would be invisible on a regular image remain visible. However, it's worth noting that all the advantages of HDR become noticeable only on a high-quality screen with maximum dimming. Additionally, this function significantly affects the cost of the projector, and the content being played back must initially be recorded in HDR — using exactly the technology supported by the projector (this detail can be clarified in the manual). In light of this, HDR support is mainly found among high-end models for home theaters. It should also be noted that there are several different HDR technologies that are not compatible with each other. Therefore, when purchasing a projector with this function, it's crucial to clarify which exact version of HDR it supports. The following are available:
— HDR10. Historically the first of the consumer HDR formats, less advanced than the options described below but extremely widespread. In particular, HDR10 is supported by virtually all streaming services that provide HDR content at all, and it's also standard for...Blu-ray discs. It allows for working with a color depth of 10 bits (hence the name). At the same time, devices with this format are compatible with HDR10+ content, although its quality will be limited by the capabilities of the original HDR10.
— HDR10+. An enhanced version of HDR10. With the same color depth (10 bits), it uses so-called dynamic metadata, which allows transmitting information about color depth not only for groups of several frames but also for individual frames. This leads to further improvement in color reproduction.
— Dolby Vision. An advanced standard used, for example, in professional filmmaking. It achieves a color depth of 12 bits, uses the aforementioned dynamic metadata, and also allows transmitting two image variants simultaneously in one video stream — HDR and regular (SDR). Dolby Vision is based on the same technology as HDR10, so in modern video equipment, this format is usually combined with HDR10 or HDR10+.
— HLG. An HDR format initially designed for TV broadcasting and live transmissions; hence, it is designed for "working without metadata" and is easier to transfer between different sources. Unlike HDR10, which uses static metadata, and particularly HDR10+ / Dolby Vision, which can dynamically adjust the picture frame by frame, HLG often provides a more universal and predictable HDR signal, although not as precisely tuned for a specific display. However, HLG has a strong point — excellent compatibility: the same stream can appear acceptable even on devices that are not fully HDR-capable, which is crucial for broadcast/satellite content. An example of use is viewing HDR broadcasts and TV content from a set-top box/tuner or streaming where HLG is encountered: the projector will correctly receive the signal and display the extended brightness range and more vibrant colors without manual tweaking of settings.
This technology allows for extending the brightness range displayed within a single frame — in simpler terms, it enables displaying both very bright and very dark colors on screen simultaneously. This significantly improves color reproduction; furthermore, small details on very bright or very dark parts of the frame that would be invisible on a regular image remain visible. However, it's worth noting that all the advantages of HDR become noticeable only on a high-quality screen with maximum dimming. Additionally, this function significantly affects the cost of the projector, and the content being played back must initially be recorded in HDR — using exactly the technology supported by the projector (this detail can be clarified in the manual). In light of this, HDR support is mainly found among high-end models for home theaters. It should also be noted that there are several different HDR technologies that are not compatible with each other. Therefore, when purchasing a projector with this function, it's crucial to clarify which exact version of HDR it supports. The following are available:
— HDR10. Historically the first of the consumer HDR formats, less advanced than the options described below but extremely widespread. In particular, HDR10 is supported by virtually all streaming services that provide HDR content at all, and it's also standard for...Blu-ray discs. It allows for working with a color depth of 10 bits (hence the name). At the same time, devices with this format are compatible with HDR10+ content, although its quality will be limited by the capabilities of the original HDR10.
— HDR10+. An enhanced version of HDR10. With the same color depth (10 bits), it uses so-called dynamic metadata, which allows transmitting information about color depth not only for groups of several frames but also for individual frames. This leads to further improvement in color reproduction.
— Dolby Vision. An advanced standard used, for example, in professional filmmaking. It achieves a color depth of 12 bits, uses the aforementioned dynamic metadata, and also allows transmitting two image variants simultaneously in one video stream — HDR and regular (SDR). Dolby Vision is based on the same technology as HDR10, so in modern video equipment, this format is usually combined with HDR10 or HDR10+.
— HLG. An HDR format initially designed for TV broadcasting and live transmissions; hence, it is designed for "working without metadata" and is easier to transfer between different sources. Unlike HDR10, which uses static metadata, and particularly HDR10+ / Dolby Vision, which can dynamically adjust the picture frame by frame, HLG often provides a more universal and predictable HDR signal, although not as precisely tuned for a specific display. However, HLG has a strong point — excellent compatibility: the same stream can appear acceptable even on devices that are not fully HDR-capable, which is crucial for broadcast/satellite content. An example of use is viewing HDR broadcasts and TV content from a set-top box/tuner or streaming where HLG is encountered: the projector will correctly receive the signal and display the extended brightness range and more vibrant colors without manual tweaking of settings.
Rear projection
The ability of the projector to operate in the rear projection mode (“mirroring” the image).
There are two main types of rear projection. Most often, horizontal mirroring is found in projectors — it is used when installing the device behind a translucent screen. Vertical inversion, in turn, is used in projectors with fixed keystone correction — due to their design, when mounted under the ceiling, such devices must be turned upside down, which requires the corresponding correction of the displayed image.
There are two main types of rear projection. Most often, horizontal mirroring is found in projectors — it is used when installing the device behind a translucent screen. Vertical inversion, in turn, is used in projectors with fixed keystone correction — due to their design, when mounted under the ceiling, such devices must be turned upside down, which requires the corresponding correction of the displayed image.
Throw distance, min
The closest distance to the screen that the projector can be used on. Typically, this is the minimum distance at which the image from the projector remains in focus.
This parameter is especially important if the device is to be placed at a small distance from the screen (for example, in a cramped room). Some modern projectors are able to work normally at a distance of 10 – 20 cm. Also note that the throw distances are determined primarily by the lens, and if the initial range of these distances does not suit you, perhaps the situation can be solved by replacing the optics.
This parameter is especially important if the device is to be placed at a small distance from the screen (for example, in a cramped room). Some modern projectors are able to work normally at a distance of 10 – 20 cm. Also note that the throw distances are determined primarily by the lens, and if the initial range of these distances does not suit you, perhaps the situation can be solved by replacing the optics.
Throw distance, max
The farthest distance from the screen that the projector can be used on. This is the maximum distance at which the image remains in focus and maintains acceptable brightness — at least enough for viewing in a darkened room on a high-quality screen.
It is necessary to choose according to this parameter taking into account the expected operating conditions and the distances to be dealt with. At the same time, it's ok to have a certain margin for the maximum distance — since, as already mentioned, it is usually indicated for an perfect screen and a darkened room, and such conditions are not always available. Also note that although the throw distances depend on the lens, not every projector with an interchangeable lens allows the installation of more "long-range" optics than the standard one — the device may simply not have enough brightness for an increased distance.
It is necessary to choose according to this parameter taking into account the expected operating conditions and the distances to be dealt with. At the same time, it's ok to have a certain margin for the maximum distance — since, as already mentioned, it is usually indicated for an perfect screen and a darkened room, and such conditions are not always available. Also note that although the throw distances depend on the lens, not every projector with an interchangeable lens allows the installation of more "long-range" optics than the standard one — the device may simply not have enough brightness for an increased distance.
Image size
Size of the image projected by the projector. Usually, it is indicated as a range — from the smallest, at the minimum throw distance, to the largest, at the maximum. About throw distances, see above; here it is worth saying that the choice of diagonal size depends both on the distance between the screen and the audience, and on the format of the projector. For example, to watch a video, the best option is the situation when the distance from the viewer to the image corresponds to 3-4 diagonals, and a relatively large picture can be useful for working with presentations. More detailed recommendations for different situations can be found in special sources; here we only recall that the image must fit on the screen used with the projector.











