Comparison HP OmniStudio X 27 D3SB7EA vs HP OmniStudio X All-in-One B46JMEA
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|---|---|---|
| HP OmniStudio X 27 D3SB7EA | HP OmniStudio X All-in-One B46JMEA | |
| Expecting restock | Outdated Product | |
| TOP sellers | ||
| Product type | monoblock | monoblock |
Screen | ||
| Screen size | 27 " | 31.5 " |
| Resolution | 3840x2160 (16:9) px | 3840x2160 (16:9) px |
| Panel type | IPS | IPS |
| Surface treatment | anti-glare | anti-glare |
| Brightness | 550 cd/m2 | |
CPU | ||
| Type | portable | portable |
| Series | Core Ultra 7 | Core Ultra 7 |
| Model | 256V | 155H |
| Code name | Lunar Lake (Series 2) | Meteor Lake (Series 1) |
| Cores | 8 | 16 |
| Threads | 8 | 22 |
| Speed | 2.2 GHz | 3.8 GHz |
| TurboBoost / TurboCore | 4.8 GHz | 4.8 GHz |
| Passmark CPU Mark test | 19537 points | 24972 points |
Memory | ||
| RAM | 16 GB | 16 GB |
| Memory type | DDR5 | DDR5 |
| Speed | 5600 MHz | |
| Number of slots | 2 | |
Graphics card | ||
| Graphics card type | integrated | integrated |
| Graphics card model | Intel Arc 140V | Intel Arc |
Storage | ||
| Drive type | SSD | SSD |
| Drive capacity | 1 TB | 1 TB |
| NVMe | ||
| M.2 connector | ||
Back panel | ||
| Connectors | HDMI output | HDMI output HDMI input v1.4 DisplayPort v1.4 |
| USB-A 2.0 | 2 pcs | |
| USB-A 5Gbps | 2 pcs | |
| USB-A 10Gbps | 2 pcs | |
| USB-C 5Gbps | 1 pcs | |
| USB-C 20Gbps | 1 pcs | |
| Monitors connection | 1 | 2 |
Front Panel | ||
| Optical drive | in absent | in absent |
| USB-A 10Gbps | 2 pcs | |
| USB-C 10Gbps | 1 pcs | |
Multimedia | ||
| LAN (RJ-45) | 1 Gbps | 1 Gbps |
| LAN controller | Realtek RTL8125BGH-CG | |
| Wi-Fi | Wi-Fi 6 (802.11ax) | Wi-Fi 7 (802.11be) |
| Bluetooth | v5.4 | v5.4 |
| Speakers | ||
| Built-in microphone | ||
| Webcam | ||
General | ||
| Keyboard and mouse | wireless | wireless |
| PSU power | 280 W | |
| PS certificate | 80+ Platinum | |
| Preinstalled OS | Win 11 Home | Win 11 Home |
| Material | plastic | plastic |
| Dimensions (HxWxD) | 566x715x20 mm | |
| Weight | 9.56 kg | |
| Color | ||
| Added to E-Catalog | march 2026 | may 2025 |
Compare HP OmniStudio X 27 and OmniStudio X All-in-One
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Glossary
Screen size
Diagonal of the screen installed in a monoblock (see "Type").
In general, the larger the diagonal, the more advanced both the screen and the computer as a whole are considered. The large display size is convenient for games, movies, and some special tasks like layout of large printed materials; in addition, a higher resolution can be provided for such a screen, and more space is available inside the case for advanced components. On the other hand, a larger monoblock will cost much more than a relatively small one, even if the other characteristics of such models are completely the same. In addition, the power of the hardware is not directly related to the size of the screen — high-end monoblocks can be quite small.
As for specific numbers, a diagonal of 20" or less is considered very limited nowadays, monoblocks of 21.5" are small, a 24" screen is medium, and values of 27" and 32" indicate large sizes.
In general, the larger the diagonal, the more advanced both the screen and the computer as a whole are considered. The large display size is convenient for games, movies, and some special tasks like layout of large printed materials; in addition, a higher resolution can be provided for such a screen, and more space is available inside the case for advanced components. On the other hand, a larger monoblock will cost much more than a relatively small one, even if the other characteristics of such models are completely the same. In addition, the power of the hardware is not directly related to the size of the screen — high-end monoblocks can be quite small.
As for specific numbers, a diagonal of 20" or less is considered very limited nowadays, monoblocks of 21.5" are small, a 24" screen is medium, and values of 27" and 32" indicate large sizes.
Brightness
The maximum brightness provided by the monoblock screen (see "Type").
The more intense the ambient light, the higher the screen brightness should be for normal visibility. The most "dim" screens in monoblocks are capable of delivering up to 200 cd / m2 — this is more than enough to work under ordinary artificial lighting, but under sunlight it will take at least 300 cd / m2. At the same time, modern monoblocks can also have a larger margin of brightness — in some models up to 500 cd / m2. This expands the possibilities for customizing the screen for different situations and user preferences. In addition, high brightness has a positive effect on image quality and colour saturation, in light of which it is often a sign of a fairly advanced screen.
The more intense the ambient light, the higher the screen brightness should be for normal visibility. The most "dim" screens in monoblocks are capable of delivering up to 200 cd / m2 — this is more than enough to work under ordinary artificial lighting, but under sunlight it will take at least 300 cd / m2. At the same time, modern monoblocks can also have a larger margin of brightness — in some models up to 500 cd / m2. This expands the possibilities for customizing the screen for different situations and user preferences. In addition, high brightness has a positive effect on image quality and colour saturation, in light of which it is often a sign of a fairly advanced screen.
Model
The specific model of the processor installed in the PC, or rather, its index within its series (see "Processor"). The full model name consists of the series name and this index — for example, Intel Core i3 3220; knowing this name, you can find detailed information about the processor (characteristics, reviews, etc.) and determine how suitable it is for your purposes.
Code name
The code name for CPU that the PC is equipped with.
This parameter characterizes, first of all, the generation to which the processor belongs, and the microarchitecture used in it. At the same time, chips with different code names can belong to the same microarchitecture/generation; in such cases, they differ in other parameters — general positioning, belonging to certain series (see above), the presence / absence of certain specific functions, etc.
Nowadays, chips with the following code names are relevant among Intel processors: Coffee Lake (8th generation), Coffee Lake (9th generation), Comet Lake (10th generation) and Rocket Lake (11th generation), Alder Lake (12th generation), Raptor Lake (13th generation), Raptor Lake-S (14th generation), Arrow Lake (Series 2). For AMD, the list looks like this: Zen+ Picasso (3rd gen), Zen2 Matisse (3rd gen), Zen2 Renoir (4th gen), Zen 3 Cezanne (5th gen), Zen 3 Vermeer (5th gen), Zen 4 Raphael (6th gen), Zen 5 Granite Ridge (9th gen)....
This parameter characterizes, first of all, the generation to which the processor belongs, and the microarchitecture used in it. At the same time, chips with different code names can belong to the same microarchitecture/generation; in such cases, they differ in other parameters — general positioning, belonging to certain series (see above), the presence / absence of certain specific functions, etc.
Nowadays, chips with the following code names are relevant among Intel processors: Coffee Lake (8th generation), Coffee Lake (9th generation), Comet Lake (10th generation) and Rocket Lake (11th generation), Alder Lake (12th generation), Raptor Lake (13th generation), Raptor Lake-S (14th generation), Arrow Lake (Series 2). For AMD, the list looks like this: Zen+ Picasso (3rd gen), Zen2 Matisse (3rd gen), Zen2 Renoir (4th gen), Zen 3 Cezanne (5th gen), Zen 3 Vermeer (5th gen), Zen 4 Raphael (6th gen), Zen 5 Granite Ridge (9th gen)....
Cores
The number of cores in a complete PC processor.
The core is a part of the processor designed to process one stream of commands (and sometimes more, for such cases, see "Number of threads"). Accordingly, the presence of several cores allows the processor to work simultaneously with several such threads, which has a positive effect on performance. However note that a larger number of cores does not always mean higher computing power — a lot depends on how the interaction between command streams is organized, what special technologies are implemented in the processor, etc. So, only chips of the same purpose (desktop, mobile) and similar series (see "Processor") can be compared by the number of cores.
In general, single-core processors are practically not found in modern PCs. Mainly desktop chips of the initial and middle level are made dual-core. Four cores are found both in desktop CPUs of the middle and advanced class, and in mobile solutions. And six-core and eight-core processors are typical for high-performance desktop processors used in workstations and gaming systems.
The core is a part of the processor designed to process one stream of commands (and sometimes more, for such cases, see "Number of threads"). Accordingly, the presence of several cores allows the processor to work simultaneously with several such threads, which has a positive effect on performance. However note that a larger number of cores does not always mean higher computing power — a lot depends on how the interaction between command streams is organized, what special technologies are implemented in the processor, etc. So, only chips of the same purpose (desktop, mobile) and similar series (see "Processor") can be compared by the number of cores.
In general, single-core processors are practically not found in modern PCs. Mainly desktop chips of the initial and middle level are made dual-core. Four cores are found both in desktop CPUs of the middle and advanced class, and in mobile solutions. And six-core and eight-core processors are typical for high-performance desktop processors used in workstations and gaming systems.
Threads
The number of threads supported by the bundled PC processor.
A thread in this case is a sequence of instructions executed by the kernel. Initially, each individual core is able to work with only one such sequence. However, among modern CPUs, more and more often there are models in which the number of threads is twice the number of cores. This means that the processor uses multi-threading technology, and each core works with two instruction sequences: when pauses occur in one thread, the core switches to another, and vice versa. This allows you to significantly increase performance without increasing the clock frequency and heat dissipation, however, such CPUs are also more expensive than single-threaded counterparts.
A thread in this case is a sequence of instructions executed by the kernel. Initially, each individual core is able to work with only one such sequence. However, among modern CPUs, more and more often there are models in which the number of threads is twice the number of cores. This means that the processor uses multi-threading technology, and each core works with two instruction sequences: when pauses occur in one thread, the core switches to another, and vice versa. This allows you to significantly increase performance without increasing the clock frequency and heat dissipation, however, such CPUs are also more expensive than single-threaded counterparts.
Speed
Clock speed of the CPU installed in the PC.
In theory, higher clock speeds have a positive effect on performance because they allow the CPU to perform more operations per unit of time. However, this indicator is rather weakly related to real productivity. The fact is that the actual capabilities of the CPU strongly depend on a number of other factors - the overall architecture, cache size, number of cores, support for special instructions, etc. As a result, you can compare by this indicator only chips from the same or similar series (see “CPU”), and ideally, also from the same generation. And that's pretty approximate.
In theory, higher clock speeds have a positive effect on performance because they allow the CPU to perform more operations per unit of time. However, this indicator is rather weakly related to real productivity. The fact is that the actual capabilities of the CPU strongly depend on a number of other factors - the overall architecture, cache size, number of cores, support for special instructions, etc. As a result, you can compare by this indicator only chips from the same or similar series (see “CPU”), and ideally, also from the same generation. And that's pretty approximate.
Passmark CPU Mark test
The result shown by the PC processor in the test (benchmark) Passmark CPU Mark.
Passmark CPU Mark is a comprehensive test that allows you to evaluate CPU performance in various modes and with a different number of processed threads. The results are displayed in points; the more points, the higher the overall performance of the processor. For comparison: as of 2020, in low-cost solutions, the results are measured in hundreds of points, in mid-range models they range from 800 – 900 to more than 6,000 points, and individual top-end chips are capable of showing 40,000 points or more.
Passmark CPU Mark is a comprehensive test that allows you to evaluate CPU performance in various modes and with a different number of processed threads. The results are displayed in points; the more points, the higher the overall performance of the processor. For comparison: as of 2020, in low-cost solutions, the results are measured in hundreds of points, in mid-range models they range from 800 – 900 to more than 6,000 points, and individual top-end chips are capable of showing 40,000 points or more.
Speed
The clock speed of the RAM that comes with the PC. This is one of the parameters that determine the capabilities of RAM: with the same amount and type of memory (see above), a higher clock frequency will mean faster performance. However such details are rarely required by an ordinary user, but they are important for enthusiasts and professionals.
Also note that this indicator can be used to determine the possibilities for upgrading the system: the motherboard will be able to work normally with brackets that have the same or lower clock frequency, but compatibility with faster memory should be specified separately.
Also note that this indicator can be used to determine the possibilities for upgrading the system: the motherboard will be able to work normally with brackets that have the same or lower clock frequency, but compatibility with faster memory should be specified separately.




