Integrated Device Testing
Audio Subsystem Testing
Audio Playback Testing
Using a selection of Hard Rock and Heavy Metal music tracks and Windows Media Player, the audio subsystem playback performance was tested for playback accuracy and fidelity.
Playback using the audio test tracks was clear and distortion free using a 5.1 speaker setup through the on-board analogue audio ports.
Listening tests using the selected audio tracks were performed with a Razer Carcharias audio headset as well as a 5.1 speaker setup to exercise the subsystem's audio fidelity. The integrated Creative audio chipset is impressive with distortion-free audio reproduction coming through the listening medium. Sound through the headset connected to the dedicated analogue audio port was especially enticing with its crispness and audio clarity.
Microphone Port Testing
For testing the board's Microphone input port, the microphone from a Razer Carcharias audio headset was used to capture a 10 second spoken phrase with the assistance of the Microsoft Sound Recorder application. The resulting audio file was saved to the desktop and played back using Windows Media Player.
The recorded audio was distortion-free during all test run, requing recording volume set to a minimum of 75 and Microphone Boost enabled with a +30dB setting. Any lower volume settings resulting in muted pickup. Note that the Crystal Voice functionality did not appear to impact audio pickup ability of the system, but resulted in an increase in pickup quality when enabled.
ATTO Disk Benchmark
To validate that the board’s device ports were functioning correctly, we connected an OCZ Vertex 460 240GB SATA III SSD to the system and ran the ATTO Disk Benchmark against the drive. The SSD was directly connected to the native SATA 3 ports. NGFF port testing was performed using an M.2 based Plextor PCIe M.2 2280 128GB SSD. The M.2 device was tested in the integrated secondary M.2 slot only (located to the upper left of the chipset cooler). ATTO was configured to test against transfer sizes from 0.5 to 8192 KB with Total Length set to 512 MB and Queue Depth set to 10. The M.2 SSD selected for testing has a maximum read throughput of 770 MB/s and a write throughput of 335 MB/s over a PCI-Express x2 bus. The selected SSD has a maximum maximum read throughput of 540 MB/s and a write throughput of 525 MB/s on a SATA III controller. The drive tests were repeated three times with the highest repeatable read and write speeds recorded.
Across all ports, SSD performance on the X99 Classified board pushed the device rated transfer speeds to their limits. The SATA-based Intel controllers exhibited similar performance with the SSD, making the decision on what port to use come down to whether or not you require hardware RAID support for your configuration.
SoftPerfect Research NetWorx Speed Test
In conjunction with Windows Performance Monitor, SoftPerfect Research NetWorx Speed Meter application was used to measure the upload and download performance of the motherboards integrated network controllers. Speed Meter was used to measure average network throughput in MB/s with Windows Performance Monitor used to measure average CPU utilization during the tests.
The LanBench network benchmarking software was used to generate send and receive traffic between the local and remote systems over a five minute period with packet size set to 4096 and connection count set to 20. A LanBench server was set up on the remote system to generate or receive traffic for the tests performed. The upload and download tests were repeated three times with the highest repeatable average throughput and the lowest repeatable average CPU utilization percentage recorded.
Note that that theoretical maximum throughput for a Gigabit Ethernet adapter is 125 MB/s (1.0 Gbps).
Performance on both network controllers was superb. The I217-LM controller uplaod and download average transfer speeds matched, while the I210 controller showed better performance during upload operations over download. In all cases, the CPU utilization remained under 5% averaged and spike usage during the test runs.
My favorite product of all
My favorite product of all time is a bit different. I love the EVBot I got to push my Classified cards to the max… or whatever classified products I happen to be holding.
Nice write-up. My only gripe
Nice write-up. My only gripe is with EVGA going with angled connectors at the edge of the boar. This is clearly meant to be setup as a benching system or a very top-end full size ATX or EATX case with plenty of room.
The lack of a cmos jumper
The lack of a cmos jumper shouldn’t be listed as a weakness, considering there is a cmos reset button on the motherboard backplane.
CMOS reset button just clears
CMOS reset button just clears current CMOS settings but retains profile information and any internally configured settings. The reset jumper physically shorts the CMOS to reset it to factory defaults, including profile information, time, and internally configured settings (like memory and cpu-dependent settings that are not user configurable). That is why it is listed as a weakness.
Unfortunately, it seems to be the norm with x99 boards rather than the exception. You can remove the CMOS battery for the same effect most of the time, but I have seen boards retain profile and time settings even after removing the CMOS battery for elongated periods (> 20-30m)…
Weakness indeed. I tried
Weakness indeed. I tried every possible way to reset Cmos but it just doesnt work.