Comparison Overmax Multipic 6.1 vs Wanbo X5
Add to comparison | ![]() | ![]() |
|---|---|---|
| Overmax Multipic 6.1 | Wanbo X5 | |
| Outdated Product | from $399.99 | |
| TOP sellers | ||
| Main function | portable | portable |
| Operating system | Android 9.0 | Android 9.0 |
Lamp and image | ||
| Lamp type | LED | LED |
| Service life | 50000 h | 20000 h |
| Brightness | 7000 lm | |
| Brightness ANSI Lumens | 1100 lm | |
| Static contrast | 4 500:1 | 2 500:1 |
| Colour rendering | 1.07 billion colours | |
Projection system | ||
| Technology | LCD | |
| Real resolution | 1920x1080 px | 1920x1080 px |
| Max. video resolution | 1920x1080 px | |
| Image format support | 4:3, 16:9 | 4:3, 16:9 |
| HDR support | + | |
Projecting | ||
| Rear projection | ||
| Throw distance, min | 1.3 m | |
| Throw distance, max | 4 m | |
| Image size | 39.5 – 150 " | 40 – 120 " |
| Throw ratio | 1.50:1 | 1.5:1 |
| Autofocus | ||
| Auto keystone correction | ||
Features | ||
| Features | voice assistant | |
| Bluetooth | Bluetooth ready | v 5.0 |
| Wi-Fi | Wi-Fi ready | Wi-Fi 6 (802.11ax) |
| Miracast | ||
Hardware | ||
| CPU | Hisilicon 352 | |
| RAM | 1 GB | 1 GB |
| Built-in memory | 8 GB | 16 GB |
| USB-A 2.0 | 2 pcs | |
| Number of speakers | 1 | 2 |
| Sound power | 15 W | 10 W |
| Video connectors | composite AV-input | |
| HDMI inputs | 2 | 1 |
| Audio connectors | 3.5 mm output (mini-Jack) RCA (audio) | 3.5 mm output (mini-Jack) |
| Service connectors | LAN (RJ-45) | |
General | ||
| Noise level (nominal) | 35 dB | |
| Power source | mains | mains |
| Size (HxWxD) | 119x265x235 mm | |
| Weight | 1.86 kg | |
| Color | ||
| Added to E-Catalog | june 2024 | february 2024 |
Compare Overmax Multipic 6.1 and Wanbo X5
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Glossary
Service life
Minimum projector lamp life as stated by the manufacturer. Specified by the total time of continuous operation. Note that if the projector was operated without violations, then upon reaching this time, the lamp will not necessarily fail — on the contrary, it can work for quite a long time. However, when evaluating durability, it is best to focus on the claimed service life.
Brightness
The brightness of the image produced by the projector at maximum backlight brightness. Usually, the average brightness of the screen, derived from a special formula, is indicated. The higher it is, the less the image depends on ambient light: a bright projector can provide a clearly visible image even in daylight, but a dim one will require dimming. On the other hand, increasing brightness reduces contrast and accuracy of colour reproduction.
Accordingly, when choosing this parameter, you need to consider the conditions in which you plan to use the projector. So, for office or school/university use, a brightness of at least 3000 lm is desirable — this allows you to get normal visibility without obscuring the room. In turn, among the top models a very low brightness can be found, because. such projectors are usually installed in rooms specially designed for them with good darkness level. And in ultra-compact devices it is impossible to achieve high brightness for technical reasons.
Detailed recommendations on the optimal brightness for certain conditions can be found in special sources. Here we note that anyway, it is worth choosing according to this indicator with some margin. As mentioned above, as brightness increases, contrast and colour quality decrease, and you may need to use the projector at a reduced brightness to achieve the desired picture quality.
Accordingly, when choosing this parameter, you need to consider the conditions in which you plan to use the projector. So, for office or school/university use, a brightness of at least 3000 lm is desirable — this allows you to get normal visibility without obscuring the room. In turn, among the top models a very low brightness can be found, because. such projectors are usually installed in rooms specially designed for them with good darkness level. And in ultra-compact devices it is impossible to achieve high brightness for technical reasons.
Detailed recommendations on the optimal brightness for certain conditions can be found in special sources. Here we note that anyway, it is worth choosing according to this indicator with some margin. As mentioned above, as brightness increases, contrast and colour quality decrease, and you may need to use the projector at a reduced brightness to achieve the desired picture quality.
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.
Static contrast
The static contrast of the image provided by the projector.
Static contrast refers to the maximum difference between the brightest white light and the darkest black that a projector can provide within a single frame. Unlike dynamic contrast (see below), this parameter describes not conditional, but quite real capabilities of the device, achievable without the use of any additional tricks like auto-brightness. And since the quality of colour reproduction and detailing depend on contrast, the higher this indicator, the lower the likelihood that details will be indistinguishable in bright or dark areas.
Static contrast refers to the maximum difference between the brightest white light and the darkest black that a projector can provide within a single frame. Unlike dynamic contrast (see below), this parameter describes not conditional, but quite real capabilities of the device, achievable without the use of any additional tricks like auto-brightness. And since the quality of colour reproduction and detailing depend on contrast, the higher this indicator, the lower the likelihood that details will be indistinguishable in bright or dark areas.
Colour rendering
The number of individual colour shades that the projector is capable of displaying.
The minimum indicator for modern projection technology is actually 16 million colours (more precisely, 16.7 million is a standard number associated with the features of digital image processing). In the most advanced models, this value can exceed 1 billion. However, two nuances should be taken into account here: firstly, the human eye is able to recognize only about 10 million colour shades, and secondly, not a single modern image output device (projectors, monitors, etc.) cannot cover the entire spectrum of colours visible to the human eye. Therefore, impressive colour performance is more of a marketing ploy than a real indicator of image quality, and in fact it makes sense to pay attention to other characteristics — primarily brightness and contrast (see above), as well as specific data like a colour gamut chart.
The minimum indicator for modern projection technology is actually 16 million colours (more precisely, 16.7 million is a standard number associated with the features of digital image processing). In the most advanced models, this value can exceed 1 billion. However, two nuances should be taken into account here: firstly, the human eye is able to recognize only about 10 million colour shades, and secondly, not a single modern image output device (projectors, monitors, etc.) cannot cover the entire spectrum of colours visible to the human eye. Therefore, impressive colour performance is more of a marketing ploy than a real indicator of image quality, and in fact it makes sense to pay attention to other characteristics — primarily brightness and contrast (see above), as well as specific data like a colour gamut chart.
Technology
The technology by which the projector sensor is built.
— DLP. This technology is based on a chip with thousands of rotary micromirrors. Each such mirror corresponds to one pixel and has two fixed positions — “lit” and “darkened”. In most DLP projectors, there is only one sensor, and the output of a colour image is provided by the colour wheel, thanks to which the projector alternately displays the red, green and blue image; they are replaced so quickly that the viewer perceives not individual frames, but a whole colour picture. Compared to LCD models (see related section), these single-sensor projectors are more compact and offer better image contrast with deep black levels (which improves black and white image quality). However, the brightness of the colour image in DLP devices is relatively low, in addition, they are subject to the "rainbow effect": in dynamic scenes, colour artifacts may be noticeable due to the mismatch of red, green and blue image components. Three-sensor DLP projectors don`t have these shortcomings; however, such a design is very expensive, so it is found rarely, mainly among premium devices.
— 3LCD. Technology based on the use of translucent LCD sensors. There are three such sensors, each of them is translucent with its base colour (red, green or blue), and the final colour “picture” is formed from three images simultaneously superimposed on each other. Thanks to...this format of operation, you can achieve brighter, more saturated colours than in single-sensor DLP projectors (see the relevant paragraph); in addition, this technology is completely devoid of the "rainbow effect". Among its shortcomings are the relatively low contrast ratio (in particular, due to the low black depth) and the larger size of the projectors.
— LCD(Liquid Crystal Display) — a colour rendering technology based on the modulation of light by liquid crystals. Do not confuse LCD and 3LCD sensors. 3LCD technology forms an image from three separate light streams, and in an LCD sensor, the image follows immediately from a single light beam. Sensors of this type provide a stable, contrasting and colour-rich image. Among the shortcomings of the technology, one can note the glimpse of the light grating, if you look at the picture from a close distance. Additionally, the substrate of LCD sensors is prone to fading, due to which the blue colour may begin to turn yellow over time (note that this can happen after a long time of active operation). LCD sensors require periodic maintenance, the service comes down to cleaning the air filter. LCD-sensor projectors are usually compact in size and light in weight, such models are prone to heat, and the noise threshold is above average.
— LCoS. A technology that combines the properties of DLP and LCD. Like LCD, it provides three separate sensors for the three primary colours (red, green, blue), and the final colour image is formed by the simultaneous superposition of these three components. The difference lies in the fact that in LCoS projectors the sensors are not translucent, but reflective. Thanks to this, you can achieve excellent contrast (as in DLP) combined with bright, high-quality colours without the "rainbow effect" (as in LCD). The main drawback of this technology is the impressive cost, which is why it is used mainly in premium projectors.
— DLP. This technology is based on a chip with thousands of rotary micromirrors. Each such mirror corresponds to one pixel and has two fixed positions — “lit” and “darkened”. In most DLP projectors, there is only one sensor, and the output of a colour image is provided by the colour wheel, thanks to which the projector alternately displays the red, green and blue image; they are replaced so quickly that the viewer perceives not individual frames, but a whole colour picture. Compared to LCD models (see related section), these single-sensor projectors are more compact and offer better image contrast with deep black levels (which improves black and white image quality). However, the brightness of the colour image in DLP devices is relatively low, in addition, they are subject to the "rainbow effect": in dynamic scenes, colour artifacts may be noticeable due to the mismatch of red, green and blue image components. Three-sensor DLP projectors don`t have these shortcomings; however, such a design is very expensive, so it is found rarely, mainly among premium devices.
— 3LCD. Technology based on the use of translucent LCD sensors. There are three such sensors, each of them is translucent with its base colour (red, green or blue), and the final colour “picture” is formed from three images simultaneously superimposed on each other. Thanks to...this format of operation, you can achieve brighter, more saturated colours than in single-sensor DLP projectors (see the relevant paragraph); in addition, this technology is completely devoid of the "rainbow effect". Among its shortcomings are the relatively low contrast ratio (in particular, due to the low black depth) and the larger size of the projectors.
— LCD(Liquid Crystal Display) — a colour rendering technology based on the modulation of light by liquid crystals. Do not confuse LCD and 3LCD sensors. 3LCD technology forms an image from three separate light streams, and in an LCD sensor, the image follows immediately from a single light beam. Sensors of this type provide a stable, contrasting and colour-rich image. Among the shortcomings of the technology, one can note the glimpse of the light grating, if you look at the picture from a close distance. Additionally, the substrate of LCD sensors is prone to fading, due to which the blue colour may begin to turn yellow over time (note that this can happen after a long time of active operation). LCD sensors require periodic maintenance, the service comes down to cleaning the air filter. LCD-sensor projectors are usually compact in size and light in weight, such models are prone to heat, and the noise threshold is above average.
— LCoS. A technology that combines the properties of DLP and LCD. Like LCD, it provides three separate sensors for the three primary colours (red, green, blue), and the final colour image is formed by the simultaneous superposition of these three components. The difference lies in the fact that in LCoS projectors the sensors are not translucent, but reflective. Thanks to this, you can achieve excellent contrast (as in DLP) combined with bright, high-quality colours without the "rainbow effect" (as in LCD). The main drawback of this technology is the impressive cost, which is why it is used mainly in premium projectors.
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.













