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WARRANTY2 years warrantyDedicated support


EASY RETURN 14 days satisfied or refunded

What's new in the R-28 (Edition 2019)  :
The R-28 (Edition 2019) had applied the new gain technology ,no any switches,relays or parameter of the amp change while change the gain modes so the sound quality is exact same in different gain modes. Users just want to choice the better mode for easy adjust the volume level.
        The R-28 had applied the new control mode, all digital setting can selection on the front plate, don't need open the unit to push or pull the jumpers.

Pros and cons of R-2R DAC  :
         1.R-2R will not convert the clock signal into the output signal.
         2. R-2R is not sensitive to jitter .Delta-Sigma D/A is much more sensitive to jitter.
         3. The output signal is much more precise compared to Delta-Sigma D/A .
        1.THD today is extremely good with Sigma Delta chips in comparison to R2R ladders are good too but not as good.
        2. Glitches and accuracy of the ladder resistors are very difficult to avoid and require complex technology to resolve it.

R-2R basic design in the market:
 The R-2R DAC is very popular nowadays and available from DIY kits up to  completely   high-end products. 
          In the low range DIY market, the R-2R design is often based on old technology designed a long time ago by MSB and only includes basic R2R ladder design and do not include the wonderful correction design of the original MSB technology. This design uses data shift registers logic chips in series mode to convert the data to an analog signal. The structural R2R technology issues cannot be avoided, and performance is solely depending on the accuracy of the ladder resistors. 

In the High-End market the R2R design is much more complex and achieves better performance. A basic R2R ladder is simply not sufficient enough to achieve good performance and high sound quality! Some manufacturers are using shift registers design. A less complex and less efficient design based on traditional logic chips working in serial mode to correct the ladder.
         A far better design switches resistors in parallel mode. An ultra-fast FPGA controls and corrects the R2R ladder. The parallel design mode controls every bit respectively and therefore achieve unprecedented performance. (In parallel mode only 1 clock cycle is needed to output all data; serial design mode needs at minimum 8 up to 24 clock cycles) The parallel design is much more complicated. Once designed properly it can correct every bit of the ladder.  Photo below shows a design with such FPGA,  can correct the unavoidable imperfections of the R2R ladder caused by intolerance of resistors glitches and achieve  best performance.


Accuracy of the ladder resistors (tolerance):
  Many people believe the tolerance of the resistors in the ladder is most important to reach best performance. Nowadays 24 bit resolution is standard. What tolerance is needed to achieve 24 bit resolution?
            When we look at 16 bit the tolerance of 1/66536, 0.1% (1/1000) is far not enough, even a tolerance of 0.01% (1/10000), the best tolerance available in the world today, still cannot handle 16 bit correctly; we are not even calculating 24 bit here!
           The tolerance of the resistor will never solve Imperfections of a ladder. This would require resistors with a tolerance of 0.00001% and ability to  handle 24 bit resolution. This is only in theory because the discreteness of the switch logic chips have already too much internal impedance and will destroy the impossible tolerance of a the resistor.
            The solution is to correct the ladder and not to depend on the tolerance of resistors. It’s a combination of both: Ultra-low tolerance resistors controlled by a correction technology and very high speed FPGA which is applied  in in our design.


Importunacy of the FPGA :
FPGA stands for Programmable Array Logic. 
            Nowadays the FPGA is applied in a lot of high end DACs; like the popular ROCKNA WAVEDREAM DAC. 
            The internal hardware design is fully controlled by complex software. A huge advantage is the fact that the software in the FPGA can easily be upgraded offering new features or improve the performance. Such design is much more flexible and future proof!

FPGA tasks 
 The FPGA  is responsible for:
           1. High performance SPDIF interface, replacing traditional less good performing SPDIF interface chips like DIR9001, WM8805 or AK411X,etc.
           2. Full re-clocking process with FIFO design applicable on all inputs. This way the output data keeps fully synchronized with the clock signal to reject any jitter.
           3. Built in 2X, 4X and 8X oversampling and digital filters and on top of this 4 different true NOS (only analog 6dB filtering) modes. To completely configure it to your liking!


Built in an excellent real balance discrete amp
 The signal last stage is the analog output stages, which have paramount  effect the final DAC sound quality. 
          After d/a conversion by the R2R D/A modules the analogue signal is transported by fully discrete matched-transistor output stages. 
          The high speed special ACSS output stages are non-feedback and current driven design. 
          They are Special because almost all other designs need to convert the signal multiple times from and to current or voltage, resulting in less detail and less defined soundstage .
The output stages have built in  4 pair 15W transistors  to offer strong drive capanility .The diamond differential  design can avoid switch distortion , it is working in a class A but don't draw large  current while idle . The balance drive mode can kill the noise and distortion and improves the soundstage presentation ,background and the transparency ,ect.

0.05% tolerance volume control system
  There 4 channels volume boards are  built in into the unit for a balance volume are control by digital signal applied relaies control the resistors in analog area . The 0.1% Vishay or KOA resistors working in parallel mode to got the 0.05% tolerance . ( I don’t know technical design so I can’t correct this part)


Heavy power supplies design:
 The DAC has the high quality low noise, low flux leakage, R-cores transformers to supply all digital parts as well as left and right analog boards. 
            There are in total 11 groups ultra-high speed and ultra-low noise PSUs built in and applied in a double stage PSUs technology for stable power delivery. That design allowes get very clean power supply for the digital parts of DAC.
             There are two groups of pure class A PSUs built in for the analog amps .


S/N Ratio

THD (Whole unit)
<0.002% (0DBV output level ) R28THDs.JPG
THD (Built in amps) <0.0003% (0DBV output level ) R28ATHDs.JPG


L mode : +7DB
H mode : +17DB

Volume characteristic
Gain.JPG  M8Svol3s.JPG

Channels imbalance
< 0.05DB
Frequency Breadth (Whole unit)
20Hz - 20KHz  (< - 0.5DB)
1Hz - 140KHz    ( - 3DB amp only ) 
 Output Level
 Headphone output : 19V RMS  (balance)

Preamp Variable output : 10V RMS (balance)

DAC Fixed output : 5 V RMS (balance)
Headphone amp output power level
(Only for  headphone over 15 ohms.)

Balanced mode

9500mW / 25 ohm
8000MW / 40 ohm 
 3500MW / 100 ohm
1200MW / 300 ohm
600MW / 600 ohm


Output impedance
1 ohm /  Headphone output

5 ohm / DAC / Preamp output
Input Sensitivity
0.5 Vp-p(75 Ohms, Coaxial)
19 dBm (Optical)
Support Operate Systems (USB)
Windows, OSX, Linux, ISO
Support Sampling  
USB & IIS : 44.1kHz - 384kHz /32Bit DSD64-512
 Coaxial mode: 44.1kHz - 192kHz
Optical mode: 44.1kHz - 96kHz
Power Requirement
1 Version  100-120V  AC 50/60 Hz

2 Version  220-240V  AC 50/60 Hz
Power Consumption
Package Weight
Approximately 7.5KG

W360 X L360 X H85(MM, Fully aluminium )  

AC power cord            X1
USB cable X1 

1 Item

Specific References

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