🗊Презентация DAVE. Technology Presentation

DAVE An introduction into Chord's DAC Technology

WHY DAVE? DAVE is an acronym of Digital to Analogue Veritas in Extremis DAVE’s development was centered upon a question: why was Hugo so musical? Where was Hugo’s sound quality performance coming from in technical terms? DAVE has an FPGA ten times the capacity of Hugo This gave opportunities to further improve performance: Improved time domain (transient timing accuracy) Improved noise-shaper performance DAVE has much more advanced analogue electronics

TIME DOMAIN The primary purpose of a DAC is to reproduce the un-sampled continuous analogue waveform from sampled digital data Conventional DACs do a poor job of reproducing the original continuous analogue signal, with timing errors on transients Increasing tap-length of FIR filters gives better time domain accuracy in terms of timing of transients The ear/brain is extremely sensitive to very small timing errors Timing accuracy upsets the perception of the start and stopping of notes It also degrades the ability to perceive instrument timbre and power It degrades soundstage precision

DAVE WTA FILTERING DAVE has 164,000-tap WTA filter The WTA algorithm was subjectively optimised and improved to suit the longer tap lengths WTA filtering is now up to 256 FS – no other DAC has ever FIR filtered at such a high rate DAVE has massively parallel processing with 166 DSP cores Further advanced filtering to 2048 FS This means DAVE more accurately retrieves the original continuous analogue un-sampled signal

DAVE NOISE-SHAPER The noise-shaper takes the high-resolution 2048 FS data and converts to 5 bits It also creates the 20-element Pulse Array outputs, so is the heart of the DAC Initially, Hugo-standard noise-shapers were employed But increased FPGA capacity and 20-element operation allows better performance Over 3 months of continuous listening tests and redesign pushing to improve sound stage depth perception – I (Rob) would not stop until performance would no longer increase Constantly pushing for better sound stage depth-perception led to world’s most advanced and complex noise-shaper It employs 17th order noise-shaping, with a total of 46 integrators; the design of the noise shaper alone would not fit into Hugo’s FPGA.

ANALOGUE 20-element Pulse Array DAC Unique 2nd order analogue noise-shaper for output stage – this gives ultra-high HF linearity and no increase in distortion with difficult loads Still employs single global feedback path with equivalent of simple 2 resistors and two polypropylene capacitors in direct signal path Ultra-low-noise sub-milli-ohm power planes for Pulse Array element flip-flops Digital DC servo Headphone drive 6V and 0.5A RMS OP capability

MEASURED PERFORMANCE Maximum output voltage 6V RMS – the reference voltage dBA, measured using APx 555 THD and noise at 5V RMS 1kHz -124 dBA A wt THD and noise at 2.5V RMS 1kHz - 127 dBA A wt (-124 dBA into 33 ohms) THD 1kHz 2.5V RMS 0.000015% Dynamic Range at -60 dBFS 1kHz -127 dBA A wt No measurable noise floor modulation, no anharmonic distortion Analogue distortion characteristic – no distortion for small signals

FFT 2.5v RMS OUTPUT Blue 2.5v RMS, red no signal zero noise floor modulation. Noise floor at -178 dBA, distortion peaks -150 dBA, no anharmonic distortion.

JITTER TEST No measurable jitter artefacts

TWO TONE 19/20kHZ TEST 1kHz is extraordinarily low at -152 dB I suspect that the APX555 audio analyzer is adding more distortion than DAVE Elevated noise floor is the APX555

16bit -90.3dB 16 bit levels are perfectly reproduced Note how similar left/right channels are

24bit -90.3dB No small-signal distortion Note how similar left/right channels are Extremely low noise

DAVE: CONCLUSION Most advanced DAC technology in the world! Redefines DAC measured performance In my view, it sets new DAC sound quality and musicality performance