![RME M-32 DA [39/57] Steadyclock](/img/pdf.png)
RME M-32 DA [39/57] Steadyclock
![RME M-32 DA [39/57] Steadyclock](/views2/2007998/page39/bg27.png)
User’s Guide M-32 DA © RME
39
16.7 SteadyClock
The SteadyClock technology of the M-series guarantees an excellent performance in all clock
modes. Its highly efficient jitter suppression refreshes and cleans up any clock signal, and pro-
vides it as reference clock at the word clock output.
Usually a clock section consists of an analog PLL for external synchronization and several
quartz oscillators for internal synchronisation. SteadyClock requires one quartz only, using a
frequency not equalling digital audio. Latest circuit designs like hi-speed digital synthesizer,
digital PLL, 100 MHz sample rate and analog filtering allow RME to realize a completely newly
developed clock technology, right within the FPGA at lowest costs. The clock's performance
exceeds even professional expectations. Despite its remarkable features, SteadyClock reacts
quite fast compared to other techniques. It locks in fractions of a second to the input signal,
follows even extreme varipitch changes with phase accuracy, and locks directly within a range
of 28 kHz up to 200 kHz.
SteadyClock has originally been de-
veloped to gain a stable and clean
clock from the heavily jittery MADI data
signal. The embedded MADI clock
suffers from about 80 ns jitter, caused
by the time resolution of 125 MHz
within the format. Common jitter values
for other devices are 5 ns, while a very
good clock will have less than 2 ns.
The picture to the right shows the
MADI input signal with 80 ns of jitter
(top graph, yellow). Thanks to Steady-
Clock this signal turns into a clock with
less than 2 ns jitter (lower graph, blue).
Using the other input sources of the M-
32 DA, word clock and ADAT, you'll
most probably never experience such
high jitter values. But SteadyClock is
not only ready for them, it would also
handle them just on the fly.
The screenshot to the right shows an
extremely jittery word clock signal of
about 50 ns jitter (top graph, yellow).
Again SteadyClock provides an ex-
treme clean-up. The filtered clock
shows less than 2 ns jitter (lower
graph, blue).
The cleaned and jitter-freed signal can be used as reference clock for any application, without
any problem. The signal processed by SteadyClock is of course not only used internally, but
also available at the units word clock output. It is also used to clock the digital outputs MADI
and ADAT.
Содержание
- I o steadycloc 1
- M 16 da 1
- M 32 da 1
- Madi i o 1
- Professional 32 16 channel d a converter double balanced output stages 32 16 channel analog to madi adat interface 24 bit 192 khz digital audio midi remote control 1
- Syncchec 1
- Totalremot 1
- User s guide 1
- General 2
- Inputs and outputs 2
- Usage and operation 2
- Application examples 3
- Technical reference 3
- Important safety instructions 4
- General 5
- M 16 da 5
- M 32 da 5
- User s guide 5
- Brief description and characteristics 6
- Introduction 6
- Package contents 6
- Controls connectors displays 7
- First usage quick start 7
- Quick start 9
- Accessories 10
- Appendix 11
- Warranty 11
- Ce fcc compliance 12
- Iso 9001 12
- Note on disposal 12
- M 16 da 13
- M 32 da 13
- Usage and operation 13
- User s guide 13
- Analog input 14
- Front panel controls 14
- Madi in 14
- Madi input 14
- Madi output 14
- Adat sync 15
- Clock section 15
- Lock keys 17
- Remote 17
- Midi over madi 18
- Remote control 18
- Remote control software 19
- Inputs and outputs 21
- M 16 da 21
- M 32 da 21
- User s guide 21
- Analog outputs 22
- Adat optical 23
- Digital inputs outputs 23
- Madi input 23
- Madi output 24
- Word clock 25
- Word clock input and output 25
- Operation and technical background 26
- Cabling and termination 27
- M 16 da 29
- M 32 da 29
- Technical reference 29
- User s guide 29
- Analog 30
- Digital inputs 30
- Technical specifications 30
- Digital 31
- Digital outputs madi 31
- Firmware 32
- General 32
- Madi user bit chart 32
- Connector pinouts d sub analog outputs 33
- Trs jacks analog outputs 33
- Technical background 34
- Terminology 34
- Lock and synccheck 35
- Latency and monitoring 36
- Ds double speed 37
- Qs quad speed 37
- Madi basics 38
- Steadyclock 39
- Block diagram m 32 da 40
- Block diagram m 16 da 41
- Basic sysex format 42
- Message types 42
- Midi implementation m series 42
- Application examples 47
- M 16 ad 47
- M 32 ad 47
- User s guide 47
- Formats and number of channels 48
- Multichannel playback 49
- Multichannel recording 51
- Multichannel recording and playback 53
- Digital multicore 56
- Multiple playbacks 57
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