MAS9138S Просмотр технического описания (PDF) - Micro Analog Systems Oy
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MAS9138S Datasheet PDF : 10 Pages
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FUNCTIONS
u Asynchronous to synchronous converter
The synchronous start-stop character, TDI
(transmitter data input), is read into the Tx buffer.
When the character is available the data bits are
transferred as TDO (transmitter data output) with the
synchronous timing signal TXC (transmitter clock).
The bit rate of TDI must be the same as the TDO rate
within -2.5%...+1% or -2.5%...+2.3% tolerance
depending on XESR (extended signalling rate) signal.
The transmitter adds extra stop bits to the
synchronous data stream, if TDI is slower than TDO.
The over speed is handled by deleting one stop bit in
u Synchronous to asynchronous converter
The synchronous RDI (receiver data input) is buffered
to recognize the stop and start bits. If a missing stop
bit is detected, it is added to the RDO (receiver data
output). In this case the stop bits are shortened 12.5%
u Converting with higher speed timing
An alternative method to handle the over speed in
asynchronous data is to boost synchronous timing
TXC and RXC by 1-2%. In this mode XHST (higher
speed timing) = 0. In this case there is no need to
u Timing selection
The MAS9138 requires clock signals in order to
function properly. The synchronous data transfer
always requires the TXC clock. The clock is used
internally for:
-shifting data out from the TX buffer (to pin TDO)
-detection of the bit rate in order to adjust the internal
baud rate generator (only if TSL = 1)
The asynchronous data transfer (pins TDI, TDO) is
accomplished by generating an internal timing signal
for the asychronous circuits. This internal timing signal
(16T) is 16 times the TXC bit rate in order to sample
the asynchronous data stream (TDI) at the proper
DA9138.003
29 January, 2001
every 8th character at maximum in the synchronous
output data TDO. When extended signal rate (XESR =
0) is used 4th stop bit may be deleted. When the
transmitter detects a break signal( at least M bits of
start polarity, where M is length of character), it sends
2M + 3 bits of start - polarity to TDO. If the break is
longer than 2M + 3 bits, then all bits are transferred to
TDO. After a break signal, at least 2M bits of stop
polarity must be transmitted before sending further
data.
(25% if XESR = 0) during each character. When the
receiver gets at least 2M + 3 bits of start polarity, it
does not add stop bits to RDO. This enables the break
signal to go through the buffer.
delete any stop bits in the transmitter buffer. The
break signal goes through unchanged. On the receiver
side the synchronous data, RDI, is transferred directly
to the asynchronous output RDO with RXC.
speed. The internal clock 16T is either generated from
a crystal frequency by dividing it by 8, 16, 21 1/3, 25
3/5, 32, 42 2/3,64,128,256 or 512. Or it can also be
generated externally and fed to pin TMG (TSL = 0).
This is especially useful if the system already
generates a clock which is 16 times the bit clock TXC
as shown or if the bit rate is higher than 38.4 kHz. The
divider is automatically selected by internal logic by
measuring the TXC clock speed (TSL = 1). A crystal
oscillator or a resonator can also be connected
between pins 2 and 3. The crystal frequency should
be 128 x TXCmax.
Timing Circuits
16 x TXC
MAS 9138
TXC
EXTERNALLY GENERATED 16T CLOCK
u Character Length CL1,CL2
CL1
1
0
1
0
CL2
0
0
1
1
Conditions
8 bits
9 bits
10 bits
11 bits
6 (10)
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