CN111124973A - Reinforced server mainboard based on FT-1500A-16 processor - Google Patents

Abstract

The invention discloses a reinforced server mainboard based on a Feiteng FT-1500A-16 processor, wherein the mainboard is integrated with the Feiteng FT-1500A-16 processor and a first PCIE SWITCH bridge piece, a second PCIE SWITCH bridge piece and a third PCIE SWITCH bridge piece; the first PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 16 bus; the second PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus; the third PCIE SWITCH bridge chip is connected to the FT-1500A-16 processor via a PCIE 8 bus. The invention adopts a domestic FT-1500A-16 processor, the processor is connected with an PCIE SWITCH bridge chip through a PCIE bus, and the processor and the bridge chip are domestic products, thereby realizing autonomous control; and secondly, a PCIE bus design is adopted, and each module has the advantages of high transmission bandwidth, low delay, high operation efficiency, high speed and the like.

Description

Reinforced server mainboard based on FT-1500A-16 processor

Technical Field

The invention relates to the technical field of computers, in particular to a reinforced server mainboard based on a Feiteng FT-1500A-16 processor.

Background

In the past, foreign products are adopted in software and hardware products of reinforcing servers in China, core technologies such as foreign high-performance processors and operating systems are completely closed, the core technical principle of the software and hardware products cannot be deeply mastered, and technical risks and uncontrollable potential safety hazards in maintenance exist in the using process of the software and hardware products.

Information security is an important index in future information-based warfare, and in the environment of network combat, places where enemies can initiate information attacks are ubiquitous, so that the enemies cannot defend the warfare. In order to realize autonomous controllability, the requirement of a domestic high-performance server platform is imperative.

The reinforcing server is a server with more rigorous requirements on functions compared with a common server, and is mainly applied to occasions with more severe environments, higher expandability requirements, stronger computing capability and higher bandwidth.

However, the existing servers are still limited to foreign software and hardware products, and although the limitation degree is reduced, the product use still has relatively large technical risk and uncontrollable potential safety hazard in maintenance.

Based on this, there is an urgent need for a reinforced server motherboard based on the FT-1500A-16 processor, in order to improve the above-mentioned drawbacks of the prior art.

The above is only for the purpose of assisting understanding of the technical aspects of the present invention, and does not represent an admission that the above is prior art.

Disclosure of Invention

The invention mainly aims to provide a reinforced server mainboard based on a Feiteng FT-1500A-16 processor, aims to solve the potential safety hazard that technical risks and maintenance cannot be controlled in the reinforced server mainboard in the prior art, and adopts a domestic hardware product to improve the autonomous security control and the security credibility of the mainboard, so that the potential safety hazard in the aspects of technical risks and maintenance controllability when the reinforced server mainboard is used is reduced to a certain extent.

In order to achieve the purpose, the invention provides a reinforced server main board based on a FT-1500A-16 processor, which integrates the FT-1500A-16 processor and a first PCIE SWITCH bridge plate, a second PCIESWITCH bridge plate and a third PCIE SWITCH bridge plate;

the first PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 16 bus;

the second PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus;

and the third PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus.

Preferably, the first PCIE SWITCH bridge is expanded by the PCIE bus to have 1 PCIE 16 physical expansion slot with actual bandwidth of 8 and 2 PCIE 16 physical slots with actual bandwidth of 8.

Preferably, the second PCIE SWITCH bridge chip expands 1 PCIE x 16 physical expansion slot with actual bandwidth of 8 and 2 PCIE x 8 physical slots with actual bandwidth of 4 through the PCIE bus.

Preferably, the third PCIE SWITCH bridge chip expands out of the BMC management module through the PCIE bus; a video signal interface is connected to a BMC management chip integrated on the BMC management module, the BMC management chip is connected with a W83795 chip through an IIC bus, and the W83795 chip is connected with a PWM fan interface; the BMC manages the integrated USB signal on the chip.

Preferably, the third PCIE SWITCH bridge chip further expands a USB controller through a PCIE bus, and the USB controller expands 4 USB3.0 paths and 1 USB HUB path; the 1 path of USB HUB expands 2 paths of USB3.0, 1 path of USB2.0HUB and 1 path of USB2. OHUB; the USB interface is interconnected with the BMC management module through the AST 2400.

Preferably, the third PCIE SWITCH bridge expands the MAC over a PCIE 1 bus; the MAC is connected with an i350 network card, and the i350 network card is connected with a gigabit network interface.

Preferably, the third PCIE SWITCH bridge chip expands out of the SATA controller through the PCIE bus, and the SATA controller controls 4 SATA3.0 interfaces.

Preferably, the third PCIE SWITCH bridge chip expands a 1-way MINIPCIE bus through a PCIE bus, and the MINIPCIE bus is used to expand a solid-state disk and a wireless network card module of a MINIPCIE interface.

Preferably, the FT-1500A-16 comprises a first memory cell and a second memory cell; the first memory unit and the second memory unit both adopt 2 DDR3 memories, each DDR3 memory adopts a DDR3 memory bank or a DDR3 memory granule chip, and the first memory unit and the second memory unit form a double channel.

Preferably, the extension mode of the first PCIE SWITCH bridge chip and the second PCIE SWITCH bridge chip adopts a serial interconnection mode, data transmission is carried out in a point-to-point mode, and each device can separately share the bandwidth; the physical expansion slot is used for expanding a GPU, an optical fiber and a RAID expansion module.

The FT-1500A-16 processor, the first PCIE SWITCH bridge piece, the second PCIE SWITCH bridge piece and the third PCIE SWITCH bridge piece which are integrated on the reinforcing server mainboard are all made of domestic products, so that the autonomous controllability of the reinforcing server mainboard is improved to a certain extent, and further the potential safety hazard in the aspects of technical risk and maintenance controllability when the reinforcing server mainboard is used is reduced to a certain extent; in addition, the processor is connected with the PCIESWITCH bridge chip through a PCIE bus, and the PCIE bus design is adopted, so that each module has the advantages of high transmission bandwidth, low delay, high operation efficiency, high speed and the like.

Drawings

FIG. 1 is a schematic structural diagram of a reinforced server motherboard based on a FT-1500A-16 processor in an embodiment.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Examples

Referring to fig. 1: the embodiment provides a reinforced server main board based on a Feiteng FT-1500A-16 processor, wherein the main board is integrated with the Feiteng FT-1500A-16 processor and a first PCIE SWITCH bridge piece, a second PCIE SWITCH bridge piece and a third PCIE SWITCH bridge piece;

the first PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 16 bus;

the second PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus;

and the third PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus.

It should be noted that the FT-1500A-16 processor, the first PCIE SWITCH bridge, the second PCIE SWITCH bridge and the third PCIE SWITCH bridge integrated on the main board of the reinforcement server in this embodiment are all domestic products, which improves the autonomous controllability of the main board of the reinforcement server to a certain extent, and further reduces the potential safety hazard in the aspects of technical risk and maintenance controllability when the main board of the reinforcement server is used to a certain extent; in addition, the processor is connected with the PCIE SWITCH bridge chip through a PCIE bus, and the PCIE bus design is adopted, so that each module has the advantages of high transmission bandwidth, low delay, high operation efficiency, high speed and the like.

In a specific example, the first PCIE SWITCH bridge chip expands 1 PCIE 16 physical expansion slot with an actual bandwidth of 8 and 2 PCIE 16 physical expansion slots with an actual bandwidth of 8 through the PCIE bus; the second PCIE SWITCH bridge chip expands 1 PCIE 16 physical expansion slot with actual bandwidth of 8 and 2 PCIE 8 physical slots with actual bandwidth of 4 through the PCIE bus; the expansion mode adopts a serial interconnection mode, data transmission is carried out in a point-to-point mode, and each device can independently enjoy bandwidth; thereby greatly improving the transmission rate and creating conditions for higher frequency; the physical expansion slot can also be used for expanding a GPU, an optical fiber and a RAID expansion module.

In a specific example, the third PCIE SWITCH bridge chip is extended out of the BMC management module through a PCIE bus; a video signal interface is connected to a BMC management chip integrated on the BMC management module, the BMC management chip is connected with a W83795 chip through an IIC bus, and the W83795 chip is connected with a PWM fan interface; the BMC manages the integrated USB signal on the chip.

It should be noted that the BMC management chip may adopt an ASPEED AST2400BMC management chip. Through the BMC management chip, the mainboard supports remote BMC management.

In concrete implementation, even there are 6 PWM fan interfaces on the W83795 chip, the video signal interface adopt the VGA interface, still can adopt DVI interface and HDMI interface according to actual conditions in addition.

The third PCIE SWITCH bridge chip also expands a USB controller through a PCIE bus, and the USB controller expands 4 paths of USB3.0 and 1 path of USB HUB; the 1 path of USB HUB expands into 2 paths of USB3.0, 1 path of USB2.0HUB and 1 path of USB2.O HUB; the USB interface is interconnected with the BMC management module through the AST 2400; the third PCIE SWITCH bridge chip expands the MAC through a PCIE 1 bus; the MAC is connected with an i350 network card, and the i350 network card is connected with a gigabit network interface; the third PCIE SWITCH bridge piece expands out of the SATA controller through the PCIE bus, the SATA controller controls 4 SATA3.0 interfaces, and the 4 SATA3.0 can support storage hard disks with different capacities, such as HDDs and SSDs of SATA3.0 and SATA 2.0.

In a specific implementation, the third PCIE SWITCH bridge chip is connected to the i350 network card through a PCIE2.0 bus, and the i350 network card is connected to 4 gigabit network interfaces. The PCIE SWITCH bridge piece is connected with 4 SATA3.0 interfaces through PCI 2.0X 1 bus, 4 USB3.0 interfaces through PCI 2.0X 1 bus, 3 PCIE 16 slots, 1 bandwidth 16 and 2 bandwidth 8 through PCIE 16 bus, and 3 PCIE 8 slots, 1 bandwidth 8 and 2 bandwidth 4 through PCIE 8 bus.

In a specific example, the third PCIE SWITCH bridge chip expands a 1-path mini PCIE bus through a PCIE bus, the mini PCIE bus is used to expand a solid-state disk and a wireless network card module of a mini PCIE interface, and the FT-1500A-16 includes a first memory unit and a second memory unit; the first memory unit and the second memory unit both adopt 2 DDR3 memories, each DDR3 memory adopts a DDR3 memory bank or a DDR3 memory granule chip, and the first memory unit and the second memory unit form a double channel.

In summary, the reinforced server motherboard of this embodiment supports a large-capacity memory, supports multiple PCIE × 8 slots, and supports one PCIE × 16 slot, can improve the I/0 bandwidth of the motherboard, is suitable for the field with high computational performance requirements and relatively high I/0 bandwidth requirements, and can meet the requirements of resource-intensive applications to a certain extent. In addition, the reinforced server mainboard supports 4 gigabit network ports, supports remote BMC management, improves the manageability of the server, and is convenient for realizing the functions of out-of-band management, remote startup and shutdown, voltage and temperature monitoring, data access and the like of the server. In addition, the mainboard of this embodiment supports wide temperature, low atmospheric pressure, three proofings performance.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., a rom/ram, a magnetic disk, an optical disk) and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A reinforced server mainboard based on a Feiteng FT-1500A-16 processor is characterized in that the Feiteng FT-1500A-16 processor and a first PCIE SWITCH bridge plate, a second PCIE SWITCH bridge plate and a third PCIESWITCH bridge plate are integrated on the mainboard;

the first PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 16 bus;

the second PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus;

and the third PCIE SWITCH bridge chip is connected with the FT-1500A-16 processor through a PCIE 8 bus.

2. The flyover FT-1500A-16 processor-based hardened server motherboard of claim 1, wherein said first PCIE SWITCH bridge is expanded via a PCIE bus into 1 PCIE 16 physical expansion slot with an actual bandwidth of 8 and 2 PCIE 16 physical slots with an actual bandwidth of 8.

3. The FT-1500A-16 processor-based hardened server motherboard of claim 1, wherein said second PCIE SWITCH bridge is expanded via PCIE bus to 1 PCIE 16 physical expansion slot with actual bandwidth 8 and 2 PCIE 8 physical slots with actual bandwidth 4.

4. The FT-1500A-16 processor-based hardened server motherboard of claim 1, wherein the third PCIE SWITCH bridge is extended out of the BMC management module over a PCIE bus; a video signal interface is connected to a BMC management chip integrated on the BMC management module, the BMC management chip is connected with a W83795 chip through an IIC bus, and the W83795 chip is connected with a PWM fan interface; the BMC manages the integrated USB signal on the chip.

5. The FT-1500A-16 processor-based hardened server motherboard of claim 4, wherein said third PCIE SWITCH bridge further extends a USB controller over a PCIE bus, the USB controller extending 4 USB lanes 3.0, 1 USB HUB; the 1 path of USB HUB expands into 2 paths of USB3.0, 1 path of USB2.0HUB and 1 path of USB2.O HUB; the USB interface is interconnected with the BMC management module through the AST 2400.

6. The FT-1500A-16 processor-based hardened server motherboard of claim 1, wherein said third PCIE SWITCH bridge extends the MAC over a PCIE 1 bus; the MAC is connected with an i350 network card, and the i350 network card is connected with a gigabit network interface.

7. The FT-1500A-16 processor-based ruggedized server motherboard of claim 1, wherein the third PCIE SWITCH bridge is extended out of the SATA controller via a PCIE bus, the SATA controller controlling 4 SATA3.0 interfaces.

8. The reinforced server motherboard based on a FT-1500A-16 processor of claim 1, wherein the third PCIE SWITCH bridge is extended out of a 1-way MINICIE bus through a PCIE bus, and the MINICIE bus is used for extending a solid-state disk and a wireless network card module of a MINICIE interface.

9. The reinforced server motherboard based on a FT-1500A-16 processor as recited in claim 1, wherein said FT-1500A-16 comprises a first memory unit and a second memory unit; the first memory unit and the second memory unit both adopt 2 DDR3 memories, each DDR3 memory adopts a DDR3 memory bank or a DDR3 memory granule chip, and the first memory unit and the second memory unit form a double channel.

10. The FT-1500A-16 processor-based hardened server motherboard as claimed in claim 2 or 3, wherein said first PCIE SWITCH bridge chip and second PCIE SWITCH bridge chip are extended by serial interconnection for data transmission in point-to-point manner, each device enjoys bandwidth separately; the physical expansion slot is used for expanding a GPU, an optical fiber and a RAID expansion module.

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