Acourate-Wiki

This method creates a set of correction filters using n-1 stereo pairs (where n is the number of main channels in the system). A single channel is nominated as the “reference” channel and is used in each stereo pair.

The following factors may be relevant for a complete correction but are out of scope of this document;

• any basic room correction issues (what crossover to use, macro parameters, use of prefilters etc)
• subwoofer time alignment
• multisub configuration 
• multiway main channels
• driver linearisation

The example provided is for a 5.1 system using JRiver for playback.

There is no right answer here as it depends on the layout of your room.

In my setup I choose a position that places the mic at exactly the same distance from L and R and which is also the same distance from SL and SR, since my LCR are on wall then this places C slightly closer to the mic than L and R.

Use the mic alignment tool and measure offsets between the reference channel and each other channel. For example, if you use L as the reference channel then you need to know the delay (in samples) for

• L-R
• L-C
• L-SL
• L-SR

Record these delays. I recommend recording them permanently and returning the mic to the same position for future measurement sessions.

Create a workspace for the LR pair Create an XO to cross LR to the subwoofer, time align and apply any other adjustments required to the XO (Optional) Apply L-R delay adjustment to XO2R (Optional) Add prefilters using Macro 0 Create a target curve

For each of LC, LSL, LSR

• either manually initialise the workspace as above OR copy the entire LR directory and do a search and replace in the acourate.ini to replace the folder name (using scripting language of choice)
• apply delay adjustment to XO2R to account for delays found using mic alignment tool

Open the LR workspace

Configure signal chain to measure LR/SW

Open the logsweep recorder Check “freeze gain” box Do a quick log sweep Run macro 1

Load the target curve into slot 3 Adjust the target curve level to ensure the response is fully corrected using TD-Functions/Gain Save the target curve as a dbl, this is your “reference” target curve

For each of LC, LSL, LSR

• open the workspace
• configure the signal chain to route channels accordingly
• do a quick log sweep
• run macro 1
• load the “reference” target curve into slot 3
• if a negative gain adjustment is required, apply the negative gain adjustment and save as a dbl overwriting your “reference” target curve

Copy the “reference” target curve file into every workspace

For each of LR, LC, LSL, LSR

Open the workspace

Run a log sweep

Run macro 1

Run macro 3

Compare inverse curves against pulses, run “phase extract” to avoid unnecessary boost at extremities and save phase extracted pulses over the Pulse48Linv/Pulse48Rinv as necessary

Iterate over macro 4 & macro 5 until an acceptable result is achieved (NB: it is advisable to use the same parameters on the reference L channel in every workspace)

If there is a non zero delay between XO2L and XO2R (i.e. the mic alignment tool did not report 0 offset)

• Load Cor1L and Cor1R, find the peaks, calculate peakoffset = Cor1L-Cor1R
• Rotate Cor1R by (Cor1L-Cor1R) samples, save over Cor1R
• Rotate Cor2R by (Cor1L-Cor1R) samples, save over Cor2R
• Remember to update the Cor wav files if using (e.g. Load Cor1L into slot 1, Cor1R into slot 2, save as stereo wav and overwrite Cor1S)
• Remember to repeat for all sample rates if generating filters for multiple sample rates

Special note for surround channels…. if you find that there is a markedly different correction applied to the surround channels then it may be better to compare SL to SR rather than SL to L and SR to L. Use your eyes and ears to judge this.

The LFE channel can contain high(er) frequency content than your subwoofer is really capable of playing. It is therefore common to apply a low pass filter to the LFE input channel to avoid your subwoofer(s) making bad noises when presented with such content. 120Hz is a common option but you may choose to apply this at a higher or lower frequency as you prefer.

To implement this, just create another workspace as per the LR with the desired crossover in place. Use the resulting Cor1L filter as your LFE channel correction.

This step assumes you are using jriver for playback as this is the only known convolver aware video playback engine (and hence can cope with the high latency induced by acourate filters).

Create a named folder to hold the filters, lets call it final (and assume it has the same parent dir as LR, LC etc)

Copy files as follows (assuming 48kHz filters here, change sample rate as necessary)

copy LR\Cor1S48.wav final\Cor1S48_LR.wav
copy LR\Cor2S48.wav final\Cor2S48_LR.wav
copy LC\Cor1S48.wav final\Cor1S48_LC.wav
copy LC\Cor2S48.wav final\Cor2S48_LC.wav
copy LSL\Cor1S48.wav final\Cor1S48_LSL.wav
copy LSL\Cor2S48.wav final\Cor2S48_LSL.wav
copy LSR\Cor1S48.wav final\Cor1S48_LSR.wav
copy LSR\Cor2S48.wav final\Cor2S48_LSR.wav

Create file named acourate_5.1_48.cfg and enter the following (replace the path as appropriate)

48000 6 6 0
0 0 0 0 0 0
0 0 0 0 0 0
<PATH TO YOUR WORKSPACE>\Cor1S48_LR.wav
0
0.0
3.0
<PATH TO YOUR WORKSPACE>\Cor1S48_LR.wav
1
1.0
3.0
<PATH TO YOUR WORKSPACE>\Cor1S48_LC.wav
1
2.0
3.0
<PATH TO YOUR WORKSPACE>\Cor1S48_LSR.wav
1
3.0
3.0
<PATH TO YOUR WORKSPACE>\Cor1S48_LSL.wav
1
4.0
3.0
<PATH TO YOUR WORKSPACE>\Cor1S48_LSR.wav
1
5.0
3.0
<PATH TO YOUR WORKSPACE>\Cor2S48_LR.wav
0
0.0
0.0
<PATH TO YOUR WORKSPACE>\Cor2S48_LR.wav
1
1.0
1.0
<PATH TO YOUR WORKSPACE>\Cor2S48_LC.wav
1
2.0
2.0
<PATH TO YOUR WORKSPACE>\Cor2S48_LSL.wav
1
4.0
4.0
<PATH TO YOUR WORKSPACE>\Cor2S48_LSR.wav
1
5.0
5.0

COMING SOON!