DALLAS DS21Q41B

DS21Q41B
Quad T1 Framer
www.dalsemi.com
FEATURES
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Four T1 DS1/ISDN-PRI framing transceivers
All four framers are fully independent
Frames to D4, ESF, and SLC-96 formats
8-bit parallel control port that can be
connected to either multiplexed or nonmultiplexed buses
Each of the four framers contains dual twoframe elastic stores that can connect to
asynchronous or synchronous backplanes up
to 8.192 MHz
Extracts and inserts robbed bit signaling
Framer and payload loopbacks
Large counters for BPVs, LCVs, EXZs,
CRC6, PCVs, F-bit errors and the number of
multiframes out of sync
Contains ANSI 1s density monitor and
enforcer
CSU loop code generator and detector
Programmable output clocks for Fractional
T1, ISDN-PRI, Actual Size and per channel
loopback applications
Onboard FDL support circuitry
Pin-compatible with DS21Q43 Quad E1
Framer
5V supply; low power CMOS
Available in 128-pin TQFP
Industrial (-40°C to +85°C) grade version
available (DS21Q41BTN)
FUNCTIONAL DIAGRAM
RECEIVE
FRAMER
ELASTIC
STORE
TRANSMIT
FORMATTER
ELASTIC
STORE
FRAMER #0
FRAMER #1
FRAMER #2
FRAMER #3
CONTROL PORT
ACTUAL SIZE
QUAD
T1
FRAMER
DESCRIPTION
The DS21Q41B combines four of the popular DS2141A T1 Controllers onto a single monolithic die. The
“B” designation denotes that some new features are available in the Quad version that were not available
in the single T1 device. The added features in the DS21Q41B are listed in Section 1. The DS21Q41B
offers a substantial space savings to applications that require more than one T1 framer on a card. The
Quad version is only slightly bigger than the single T1 device. All four framers in the DS21Q41B are
totally independent; they do not share a common framing synchronizer. Also, the transmit and receive
sides of each framer are totally independent. The dual two-frame elastic stores contained in each of the
four framers can be independently enabled and disabled as required. The DS21Q41B meets all of the
latest specifications including ANSI T1.403 (and the emerging T1.403-199X), ANSI T1.231-1993,
AT&T TR62411, AT&T TR54016, ITU G.704 and G.706.
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092299
DS21Q41B
1.0 INTRODUCTION
The DS21Q41B Quad T1 Framer is made up of five main parts: framer #0, framer #1, framer #2, framer
#3, and the control port which is shared by all four framers. See the Block Diagram in Figure 1-1. Each
of the four framers within the DS21Q41B maintain the same register structure that appeared in the
DS2141A. The two framer select inputs (FS0 and FS1) are used to determine which framer within the
DS21Q41B is being accessed. In this manner, software written for the DS2141A can also be used with
only slight modifications, in the DS21Q41B.
Several new features have been added to the framers in the DS21Q41B over the DS2141A. Below is short
list of the new features. More details can be found in Sections 2 through 12.
ADDED FEATURE
Non-multiplexed parallel control port operation
SECTION
2
ANSI ones density monitor (transmit and receive sides) and enforcer (transmit side only)
CSU loop code generator
3 and 4
3
Elastic store reset and minimum delay mode
3 and 10
Divide RSYNC output by two for D4 to ESF conversion applications
3
TCLK keep alive
3
Indications of transmit side elastic store slip direction
4
Ability to decouple the receive and transmit elastic stores
10
Counting of excessive 0s (EXZs)
5
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DS21Q41B
DS21Q41B BLOCK DIAGRAM Figure 1-1
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DS21Q41B
TRANSMIT PIN LIST Table 1-1
PIN
19
SYMBOL
TCLK0
TYPE
I
DESCRIPTION
Transmit Clock for Framer 0
53
TCLK1
I
Transmit Clock for Framer 1
87
TCLK2
I
Transmit Clock for Framer 2
113
TCLK3
I
Transmit Clock for Framer 3
126
TSER0
I
Transmit Serial Data for Framer 0
32
TSER1
I
Transmit Serial Data for Framer 1
66
TSER2
I
Transmit Serial Data for Framer 2
92
TSER3
I
Transmit Serial Data for Framer 3
128
TCHCLK0
O
Transmit Channel Clock from Framer 0
34
TCHCLK1
O
Transmit Channel Clock from Framer 1
68
TCHCLK2
O
Transmit Channel Clock from Framer 2
94
TCHCLK3
O
Transmit Channel Clock from Framer 3
1
TCHBLK0
O
Transmit Channel Block from Framer 0
35
TCHBLK1
O
Transmit Channel Block from Framer 1
69
TCHBLK2
O
Transmit Channel Block from Framer 2
95
TCHBLK3
O
Transmit Channel Block from Framer 3
20
TLCLK0
O
Transmit Link Clock from Framer 0
54
TLCLK1
O
Transmit Link Clock from Framer 1
88
TLCLK2
O
Transmit Link Clock from Framer 2
114
TLCLK3
O
Transmit Link Clock from Framer 3
22
TLINK0
I
Transmit Link Data for Framer 0
56
TLINK1
I
Transmit Link Data for Framer 1
90
TLINK2
I
Transmit Link Data for Framer 2
116
TLINK3
I
Transmit Link Data for Framer 3
2
TPOS0
O
Transmit Bipolar Data from Framer 0
36
TPOS1
O
Transmit Bipolar Data from Framer 1
70
TPOS2
O
Transmit Bipolar Data from Framer 2
96
TPOS3
O
Transmit Bipolar Data from Framer 3
3
TNEG0
O
Transmit Bipolar Data from Framer 0
37
TNEG1
O
Transmit Bipolar Data from Framer 1
71
TNEG2
O
Transmit Bipolar Data from Framer 2
97
TNEG3
O
Transmit Bipolar Data from Framer 3
21
TSYNC0
I/O
Transmit Sync for Framer 0
55
TSYNC1
I/O
Transmit Sync for Framer 1
89
TSYNC2
I/O
Transmit Sync for Framer 2
115
TSYNC3
I/O
Transmit Sync for Framer 3
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DS21Q41B
127
TFSYNC0
I
Transmit Sync for Elastic Store in Framer 0
33
TFSYNC1
I
Transmit Sync for Elastic Store in Framer 1
67
TFSYNC2
I
Transmit Sync for Elastic Store in Framer 2
93
TFSYNC3
I
Transmit Sync for Elastic Store in Framer 3
125
TSYSCLK0
I
Transmit System Clock for Elastic Store in Framer 0
31
TSYSCLK1
I
Transmit System Clock for Elastic Store in Framer 1
65
TSYSCLK2
I
Transmit System Clock for Elastic Store in Framer 2
91
TSYSCLK3
I
Transmit System Clock for Elastic Store in Framer 3
RECEIVE PIN LIST Table 1-2
PIN
SYMBOL
TYPE
DESCRIPTION
6
RCLK0
I
Receive Clock for Framer 0
40
RCLK1
I
Receive Clock for Framer 1
74
RCLK2
I
Receive Clock for Framer 2
100
RCLK3
I
Receive Clock for Framer 3
13
RSER0
O
Receive Serial Data from Framer 0
49
RSER1
O
Receive Serial Data from Framer 1
83
RSER2
O
Receive Serial Data from Framer 2
107
RSER3
O
Receive Serial Data from Framer 3
9
RCHCLK0
O
Receive Channel Clock from Framer 0
43
RCHCLK1
O
Receive Channel Clock from Framer 1
77
RCHCLK2
O
Receive Channel Clock from Framer 2
103
RCHCLK3
O
Receive Channel Clock from Framer 3
10
RCHBLK0
O
Receive Channel Block from Framer 0
44
RCHBLK1
O
Receive Channel Block from Framer 1
80
RCHBLK2
O
Receive Channel Block from Framer 2
104
RCHBLK3
O
Receive Channel Block from Framer 3
5
RLCLK0
O
Receive Link Clock from Framer 0
39
RLCLK1
O
Receive Link Clock from Framer 1
73
RLCLK2
O
Receive Link Clock from Framer 2
99
RLCLK3
O
Receive Link Clock from Framer 3
4
RLINK0
O
Receive Link Data from Framer 0
38
RLINK1
O
Receive Link Data from Framer 1
72
RLINK2
O
Receive Link Data from Framer 2
98
RLINK3
O
Receive Link Data from Framer 3
8
RPOS0
I
Receive Bipolar Data for Framer 0
42
RPOS1
I
Receive Bipolar Data for Framer 1
76
RPOS2
I
Receive Bipolar Data for Framer 2
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DS21Q41B
102
RPOS3
I
Receive Bipolar Data for Framer 3
7
RNEG0
I
Receive Bipolar Data for Framer 0
41
RNEG1
I
Receive Bipolar Data for Framer 1
75
RNEG2
I
Receive Bipolar Data for Framer 2
101
RNEG3
I
Receive Bipolar Data for Framer 3
12
RSYNC0
I/O
Receive Sync for Framer 0
48
RSYNC1
I/O
Receive Sync for Framer 1
82
RSYNC2
I/O
Receive Sync for Framer 2
106
RSYNC3
I/O
Receive Sync for Framer 3
17
RFSYNC0
O
Receive Frame Sync from Framer 0
51
RFSYNC1
O
Receive Frame Sync from Framer 1
85
RFSYNC2
O
Receive Frame Sync from Framer 2
109
RFSYNC3
O
Receive Frame Sync from Framer 3
16
RMSYNC0
O
Receive Multiframe Sync from Framer 0
50
RMSYNC1
O
Receive Multiframe Sync from Framer 1
84
RMSYNC2
O
Receive Multiframe Sync from Framer 2
108
RMSYNC3
O
Receive Multiframe Sync from Framer 3
11
RSYSCLK0
I
Receive System Clock for Elastic Store in Framer 0
45
RSYSCLK1
I
Receive System Clock for Elastic Store in Framer 1
81
RSYSCLK2
I
Receive System Clock for Elastic Store in Framer 2
105
RSYSCLK3
I
Receive System Clock for Elastic Store in Framer 3
18
RLOS/LOTC0
O
Receive Loss of Sync/Loss of Transmit Clock from Framer 0
52
RLOS/LOTC1
O
Receive Loss of Sync/Loss of Transmit Clock from Framer 1
86
RLOS/LOTC2
O
Receive Loss of Sync/Loss of Transmit Clock from Framer 2
112
RLOS/LOTC3
O
Receive Loss of Sync/Loss of Transmit Clock from Framer 3
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DS21Q41B
CONTROL PORT/TEST/SUPPLY PIN LIST Table 1-3
PIN
57
SYMBOL
TEST
TYPE
I
DESCRIPTION
3-State Control for all Output and I/O Pins
60
CS
I
Chip Select
58
FS0
I
Framer Select 0 for Parallel Control Port
59
FS1
I
Framer Select 1 for Parallel Control Port
61
BTS
I
Bus Type Select for Parallel Control Port
63
WR (R/ W )
I
Write Input (Read/Write)
62
RD (DS)
I
Read Input (Data Strobe)
23
A0
I
Address Bus Bit 0; LS
24
A1
I
Address Bus Bit 1
25
A2
I
Address Bus Bit 2
26
A3
I
Address Bus Bit 3
27
A4
I
Address Bus Bit 4
28
A5
I
Address Bus Bit 5
29
A6 or ALE (AS)
I
Address Bus Bit 6; MSB or Address Latch Enable (Address
Strobe)
30
INT
O
Receive Alarm Interrupt for all Four Framers
64
MUX
I
Non-Multiplexed or Multiplexed Bus Select
117
D0 or AD0
I/O
Data Bus Bit 0 or Address/Data Bus Bit 0; LSB
118
D1 or AD1
I/O
Data Bus Bit 1 or Address/Data Bus Bit 1
119
D2 or AD2
I/O
Data Bus Bit 2 or Address/Data Bus Bit 2
120
D3 or AD3
I/O
Data Bus Bit 3 or Address/Data Bus Bit 3
121
D4 or AD4
I/O
Data Bus Bit 4 or Address/Data Bus Bit 4
122
D5 or AD5
I/O
Data Bus Bit 5 or Address/Data Bus Bit 5
123
D6 or AD6
I/O
Data Bus Bit 6 or Address/Data Bus Bit 6
124
D7 or AD7
I/O
Data Bus Bit 7 or Address/Data Bus Bit 7; MSB
15
VDD
-
Positive Supply Voltage
47
VDD
-
Positive Supply Voltage
79
VDD
-
Positive Supply Voltage
111
VDD
-
Positive Supply Voltage
14
VSS
-
Signal Ground
46
VSS
-
Signal Ground
78
VSS
-
Signal Ground
110
VSS
-
Signal Ground
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DS21Q41B
DS21Q41B PIN DESCRIPTION Table 1-4
Transmit Clock [TCLK]. 1.544 MHz primary clock. Used to clock data through the transmit side
formatter.
Transmit Serial Data [TSER]. Transmit NRZ serial data. Sampled on the falling edge of TCLK when
the transmit side elastic store is disabled. Sampled on the falling edge of TSYSCLK when the transmit
side elastic store is enabled.
Transmit Channel Clock [TCHCLK]. 192 kHz clock which pulses high during the LSB of each
channel. Synchronous with TCLK when the transmit side elastic store is disabled. Synchronous with
TSYSCLK when the transmit side elastic store is enabled. Useful for parallel to serial conversion of
channel data, locating robbed-bit signaling bits, and for blocking clocks in DDS applications. See Section
12 for timing details.
Transmit Bipolar Data [TPOS and TNEG]. Updated on rising edge of TCLK. Can be programmed to
output NRZ data on TPOS via the TCR1.7 control bit.
Transmit Channel Block [TCHBLK]. A user programmable output that can be forced high or low
during any of the 24 T1 channels. Synchronous with TCLK when the transmit side elastic store is
disabled. Synchronous with TSYSCLK when the transmit side elastic store is enabled. Useful for
blocking clocks to a serial UART or LAPD controller in applications where not all T1 channels are used
such as Fractional T1, 384k bps service, 768k bps, or ISDN-PRI. Also useful for locating individual
channels in drop-and-insert applications and for per-channel loopback. See Section 12 for timing details.
Transmit System Clock [TSYSCLK]. 1.544 MHz or 2.048 MHz clock. Only used when the transmit
side elastic store function is enabled. Should be tied low in applications that do not use the transmit side
elastic store.
Transmit Link Clock [TLCLK]. 4 kHz or 2 kHz (ZBTSI) demand clock for the TLINK input. See
Section 12 for timing details.
Transmit Link Data [TLINK]. If enabled via TCR1.2, this pin will be sampled during the F-bit time on
the falling edge of TCLK for data insertion into either the FDL stream (ESF) or the Fs bit position (D4)
or the Z-bit position (ZBTSI). See Section 12 for timing details.
Transmit Sync [TSYNC]. A pulse at this pin will establish either frame or multiframe boundaries for the
DS21Q41B. Via TCR2.2, the DS21Q41B can be programmed to output either a frame or multiframe
pulse at this pin. If this pin is set to output pulses at frame boundaries, it can also be set via TCR2.4 to
output double-wide pulses at signaling frames. See Section 12 for timing details.
Transmit Frame Sync [TFSYNC]. 8 kHz pulse. Only used when the transmit side elastic store is
enabled. A pulse at this pin will establish frame boundaries for the DS21Q41B. Should be tied low in
applications that do not use the transmit side elastic store. See Section 12 for timing details.
Receive Link Data [RLINK]. Updated with either FDL data (ESF) or Fs bits (D4) or Z bits (ZBTSI) one
RCLK before the start of a frame. See Section 12 for timing details.
Receive Link Clock [RLCLK]. 4 kHz or 2 kHz (ZBTSI) demand clock for the RLINK input. See
Section 12 for timing details.
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DS21Q41B
Receive Clock [RCLK]. 1.544 MHz primary clock. Used to clock data through the receive side of the
framer.
Receive Channel Clock [RCHCLK]. 192 kHz clock which pulses high during the LSB of each channel.
Synchronous with RCLK when the receive side elastic store is disabled. Synchronous with RSYSCLK
when the receive side elastic store is enabled. Useful for parallel to serial conversion of channel data,
locating robbed-bit signaling bits, and for blocking clocks in DDS applications. See Section 12 for timing
details.
Receive Channel Block [RCHBLK]. A user programmable output that can be forced high or low during
any of the 24 T1 channels. Synchronous with RCLK when the receive side elastic store is disabled.
Synchronous with RSYSCLK when the receive side elastic store is enabled. Useful for blocking clocks to
a serial UART or LAPD controller in applications where not all T1 channels are used such as Fractional
T1, 384k bps service, 768k bps, or ISDN-PRI. Also useful for locating individual channels in drop-andinsert applications and for per-channel loopback. See Section 12 for timing details.
Receive Serial Data [RSER]. Received NRZ serial data. Updated on rising edges of RCLK when the
receive side elastic store is disabled. Updated on the rising edges of RSYSCLK when the receive side
elastic store is enabled.
Receive Sync [RSYNC]. An extracted pulse, one RCLK wide, is output at this pin which identifies either
frame (RCR2.4=0) or multiframe boundaries (RCR2.4=1). If set to output frame boundaries, then via
RCR2.5, RSYNC can also be set to output double-wide pulses on signaling frames. If the receive side
elastic store is enabled, then this pin can be enabled to be an input at which a frame boundary pulse is
applied. See Section 12 for timing details.
Receive Frame Sync (RFSYNC). An extracted 8 kHz pulse, one RCLK wide, is output at this pin which
identifies frame boundaries. See Section 12 for timing details.
Receive Multiframe Sync [RMSYNC]. Only used when the receive side elastic store is enabled. An
extracted pulse, one RSYSCLK wide, is output at this pin which identifies multiframe boundaries. If the
receive side elastic store is disabled, then this output should be ignored. See Section 12 for timing details.
Receive Bipolar Data Inputs [RPOS and RNEG]. Sampled on falling edge of RCLK. Tie together to
receive NRZ data and disable bipolar violation monitoring circuitry.
Receive System Clock [RSYSCLK]. 1.544 MHz or 2.048 MHz clock. Only used when the elastic store
function is enabled. Should be tied low in applications that do not use the elastic store. Allowing this pin
to float can cause the device to 3-state its outputs.
Receive Loss of Sync/Loss of Transmit Clock [RLOS/LOTC]. A dual function output. If CCR1.6=0,
then this pin will toggle high when the synchronizer is searching for the T1 frame and multiframe. If
CCR1.6=1, then this pin will toggle high if the TCLK pin has not been toggled for 5 µs.
Receive Alarm Interrupt [ INT ]. Flags host controller during conditions defined in the Status Registers
of the four framers. User can poll the Interrupt Status Register (ISR) to determine which status register in
which framer is active (if any). Active low, open drain output.
3-State Control [Test]. Set high to 3-state all output and I/O pins (including the parallel control port). Set
low for normal operation. Useful in board-level testing.
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DS21Q41B
Bus Operation [MUX]. Set low to select non-multiplexed bus operation. Set high to select multiplexed
bus operation.
Data Bus [D0 to D7] or Address/Data Bus [AD0 to AD7]. In non-multiplexed bus operation (MUX=0),
serves as the data bus. In multiplexed bus operation (MUX=1), serves as an 8-bit multiplexed
address/data bus.
Address Bus [A0 to A5]. In non-multiplexed bus operation (MUX=0), serves as the address bus. In
multiplexed bus operation (MUX=1), these pins are not used and should be tied low.
Bus Type Select [BTS]. Strap high to select Motorola bus timing; strap low to select Intel bus timing.
This pin controls the function of the RD (DS), ALE(AS), and WR (R/ W ) pins. If BTS=1, then these pins
assume the function listed in parentheses ().
Read Input [ RD ] (Data Strobe [DS]).
Framer Selects [FS0 and FS1]. Selects which of the four framers to be accessed.
Chip Selects [ CS ]. Must be low to read or write to any of the four framers.
A6 or Address Latch Enable [ALE] (Address Strobe [AS]). In non-multiplexed bus operation
(MUX=0), serves as the upper address bit. In multiplexed bus operation (MUX=1), serves to demultiplex
the bus on a positive-going edge.
Write Input [ WR ] (Read/Write [R/ W ]).
Positive Supply [VDD]. 5.0 volts ±0.5 volts.
Signal Ground [VSS]. 0.0 volts.
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DS21Q41B
DS21Q41B REGISTER MAP Table 1-5
ADDRESS
20
R/W
R/W
REGISTER NAME
Status Register 1
21
R/W
Status Register 2
22
R/W
Receive Information Register 1
23
R
Line Code Violation Count Register 1
24
R
Line Code Violation Count Register 2
25
R
Path Code Violation Count Register 1(1)
26
R
Path Code Violation Count Register 2
27
R
Multiframe Out of Sync Count Register 2
28
R
Receive FDL Register
29
R/W
Receive FDL Match Register 1
2A
R/W
Receive FDL Match Register 2
2B
R/W
Receive Control Register 1
2C
R/W
Receive Control Register 2
2D
R/W
Receive Mark Register 1
2E
R/W
Receive Mark Register 2
2F
R/W
Receive Mark Register 3
30
R/W
Common Control Register 3
31
R/W
Receive Information Register 2
32
R/W
Transmit Channel Blocking Register 1
33
R/W
Transmit Channel Blocking Register 2
34
R/W
Transmit Channel Blocking Register 3
35
R/W
Transmit Control Register 1
36
R/W
Transmit Control Register 2
37
R/W
Common Control Register 1
38
R/W
Common Control Register 2
39
R/W
Transmit Transparency Register 1
3A
R/W
Transmit Transparency Register 2
3B
R/W
Transmit Transparency Register 3
3C
R/W
Transmit Idle Register 1
3D
R/W
Transmit Idle Register 2
3E
R/W
Transmit Idle Register 3
3F
R/W
Transmit Idle Definition Register
60
R
Receive Signaling Register 1
61
R
Receive Signaling Register 2
62
R
Receive Signaling Register 3
63
R
Receive Signaling Register 4
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DS21Q41B
ADDRESS
R/W
REGISTER NAME
64
R
Receive Signaling Register 5
65
R
Receive Signaling Register 6
66
R
Receive Signaling Register 7
67
R
Receive Signaling Register 8
68
R
Receive Signaling Register 9
69
R
Receive Signaling Register 10
6A
R
Receive Signaling Register 11
6B
R
Receive Signaling Register 12
6C
R/W
Receive Channel Blocking Register 1
6D
R/W
Receive Channel Blocking Register 2
6E
R/W
Receive Channel Blocking Register 3
6F
R/W
Interrupt Mast Register 2
70
R/W
Transmit Signaling Register 1
71
R/W
Transmit Signaling Register 2
72
R/W
Transmit Signaling Register 3
73
R/W
Transmit Signaling Register 4
74
R/W
Transmit Signaling Register 5
75
R/W
Transmit Signaling Register 6
76
R/W
Transmit Signaling Register 7
77
R/W
Transmit Signaling Register 8
78
R/W
Transmit Signaling Register 9
79
R/W
Transmit Signaling Register 10
7A
R/W
Transmit Signaling Register 11
7B
R/W
Transmit Signaling Register 12
7C
R/W
Test Register(2)
7D
R/W
Test Register(2)
7E
R/W
Transmit FDL Register
7F
R/W
Interrupt Mask Register 1
NOTES:
1. Address 25 also contains Multiframe Out of Sync Count Register 1.
2. The Test Registers are used only by the factory; these registers must be cleared (set to all 0s) on
power-up initialization to insure proper operation.
3. Any unused register address will allow the status of the interrupts to appear on the bus.
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DS21Q41B
DS21Q41B FRAMER DECODE Table 1-6
FS1
0
FS0
0
FRAMER ACCESSED
#0
0
1
#1
1
0
#2
1
1
#3
2.0 PARALLEL PORT
The DS21Q41B is controlled via either a non-mutliplexed (MUX=0) or multiplexed (MUX=1) by an
external microcontroller or microprocessor. The DS21Q41B can operate with either Intel or Motorola bus
timing configurations. If the BTS pin is tied low, Intel timing will be selected; if tied high, Motorola
timing will be selected. All Motorola bus signals are listed in parenthesis (). See the timing diagrams in
the A.C. Electrical Characteristics for more details.
3.0 CONTROL REGISTERS
The operation of each framer within the DS21Q41B is configured via a set of seven registers. Typically,
the control registers are only accessed when the system is first powered up. Once the DS21Q41B has
been initialized, the control registers will only need to be accessed when there is a change in the system
configuration. There are two Receive Control Registers (RCR1 and RCR2), two Transmit Control
Registers (TCR1 and TCR2), and three Common Control Registers (CCR1, CCR2, and CCR3).
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DS21Q41B
RCR1: RECEIVE CONTROL REGISTER 1 (Address=2B Hex)
(MSB)
LCVCRF
ARC
OOF1
OOF2
SYNCC
CYNCT
SYNCE
(LSB)
RESYNC
SYMBOL
POSITION
NAME AND DESCRIPTION
LCVCRF
RCR1.7
Line Code Violation Count Register Function Select.
0=do not count excessive 0s
1=count excessive 0s
ARC
RCR1.6
Auto Resync Criteria.
0=Resync on OOF or RCL event
1=Resync on OOF only
OOF1
RCR1.5
Out Of Frame Select 1.
0=2/4 frame bits in error
1=2/5 frame bits in error
OOF2
RCR1.4
Out Of Frame Select 2.
0=follow RCR1.5
1=2/6 frame bits in error
SYNCC
RCR1.3
Sync Criteria. In D4 Framing Mode.
0=search for Ft pattern, then search for Fs pattern
1=cross couple Ft and Fs pattern
In ESF Framing Mode.
0=search for FPS pattern only
1=search for FPS and verify with CRC6
SYNCT
RCR1.2
Sync Time.
0=qualify 10 bits
1=qualify 24 bits
SYNCE
RCR1.1
Sync Enable.
0=auto resync enabled
1=auto resync disabled
RESYNC
RCR1.0
Resync. When toggled from low to high, a resynchronization of
the receive side framer is initiated. Must be cleared and set again
for a subsequent resync.
14 of 61
DS21Q41B
RCR2: RECEIVE CONTROL REGISTER 2 (Address=2C Hex)
(MSB)
RCS
ZBTSI
RSDW
RSM
RSIO
D4YM
FSBE
(LSB)
MOSCRF
SYMBOL
POSITION
NAME AND DESCRIPTION
RCS
RCR2.7
Receive Code Select.
0=idle code (7F Hex)
1=digital milliwatt code (1E/0B/0B/1E/9E/8B/8B/9E Hex)
ZBTSI
RCR2.6
ZBTSI Enable.
0=ZBTSI disabled
1=ZBTSI enabled
RSDW
RCR2.5
RSYNC Double-Wide.
0=do not pulse double-wide in signaling frames
1=do pulse double-wide in signaling frames (note: this bit must
be set to 0 when RCR2.4=1 or when RCR2.3=1)
RSM
RCR2.4
RSYNC Mode Select.
0=frame mode (see the timing in Section 12)
1=multiframe mode (see the timing in Section 12)
RSIO
RCR2.3
RSYNC I/O Select.
0=RSYNC is an output
1=RSYNC is an input (only valid if elastic store enabled) (note:
this bit must be set to 0 when CCR1.2=0)
D4YM
RCR2.2
D4 Yellow Alarm Select.
0=0s in bit 2 of all channels
1=a one in the S-bit position of frame 12
FSBE
RCR2.1
PCVCR Fs Bit Error Report Enable.
0=do not report bit errors in Fsbit position; only Ft bit position
1=report bit errors in Fs bit position as well as Ft bit position
MOSCRF
RCR2.0
Multiframe Out of Sync Count Register Function Select.
0=count errors in the framing bit position
1=count the number of multiframes out of sync
15 of 61
DS21Q41B
TCR1: TRANSMIT CONTROL REGISTER 1 (Address=35 Hex)
(MSB)
LOTCMC
TFPT
TCPT
RBSE
GB7S
TLINK
TBL
(LSB)
TYEL
SYMBOL
POSITION
NAME AND DESCRIPTION
LOTCMC
TCR1.7
Loss Of Transmit Clock Mux Control. Determines whether
the transmit side formatter should switch to the ever present
RCLK if the TCLK input should fail to transition (see Figure 1-1
for details).
0=do not switch to RCLK if TCLK stops
1=switch to RCLK if TCLK stops
TFPT
TCR1.6
Transmit Framing Pass Through. (see note below)
0=Ft or FPS bits sourced internally
1=Ft or FPS bits sampled at TSER during F-bit time
TCPT
TCR1.5
Transmit CRC Pass Through. (see note below)
0=source CRC6 bits internally
1=CRC6 bits sampled at TSER during F-bit time
RBSE
TCR1.4
Robbed Bit Signaling Enable. (see note below)
0=no signaling is inserted in any channel
1=signaling is inserted in all channels (the TTR registers can be
used to block insertion on a channel by channel basis)
GB7S
TCR1.3
Global Bit 7 Stuffing. (see note below)
0=allow the TTR registers to determine which channels
containing all 0s are to be Bit 7 stuffed
1=force Bit 7 stuffing in all 0-byte channels regardless of how
the TTR registers are programmed
TLINK
TCR1.2
TLINK Select. (see note below)
0=source FDL or Fs bits from TFDL register
1=source FDL or Fs bits from the TLINK pin
TBL
TCR1.1
Transmit Blue Alarm. (see note below)
0=transmit data normally
1=transmit an unframed all ones code at TPOS and TNEG
TYEL
TCR1.0
Transmit Yellow Alarm. (see note below)
0=do not transmit yellow alarm
1=transmit yellow alarm
Note: for a detailed description of how the bits in TCR1 affect the transmit side formatter of the
DS21Q41, please see Figure 12-9.
16 of 61
DS21Q41B
TCR2: TRANSMIT CONTROL REGISTER 2 (Address=36 Hex)
(MSB)
TEST1
TEST0
ZBTSI
TSDW
TSM
TSIO
D4YM
(LSB)
B7ZS
SYMBOL
POSITION
NAME AND DESCRIPTION
TEST1
TCR2.7
Test Mode Bit 1 for Output Pins. See Table 3-1.
TEST0
TCR2.6
Test Mode Bit 0 for Output Pins. See Table 3-1.
ZBTSI
TCR2.5
ZBTSI Enable.
0=ZBTSI disabled
1=ZBTSI enabled
TSDW
TCR2.4
TSYNC Double-Wide. (Note: this bit must be set to 0 when
TCR2.3=1 or when TCR2.2=0)
0=do not pulse double-wide in signaling frames
1=do pulse double-wide in signaling frames
TSM
TCR2.3
TSYNC Mode Select.
0=frame mode (see the timing in Section 12)
1=multiframe mode (see the timing in Section 12)
TSIO
TCR2.2
TSYNC I/O Select.
0=TSYNC is an input
1=TSYNC is an output
D4YM
TCR2.1
D4 Yellow Alarm Select.
0=0s in bit 2 of all channels
1=a 1 in the S-bit position of frame 12
B7ZS
TCR2.0
Bit 7 0 Suppression Enable.
0=no stuffing occurs
1=Bit 7 force to a 1 in channels with all 0s
OUTPUT PIN TEST MODES Table 3-1
TEST1
0
TEST0
0
EFFECT ON OUTPUT PINS
0
1
Force all output pins 3-state (including all I/O pins and parallel port pins)
1
0
Force all output pins low (including all I/O pins except parallel port pins)
1
1
Force all output pins high (including all I/O pins except parallel port pins)
Operate normally
17 of 61
DS21Q41B
CCR1: COMMON CONTROL REGISTER 1 (Address=37 Hex)
(MSB)
TESE
ODF
RSAO
TSCLKM
RSCLKM
RESE
PLB
SYMBOL
POSITION
NAME AND DESCRIPTION
TESE
CCR1.7
Transmit Elastic Store Enable.
0=elastic store is bypassed
1=elastic store is enabled
ODF
CCR1.6
Output Data Format.
0=bipolar data at TPOS and TNEG
1=NRZ data at TPOS; TNEG=0
RSAO
CCR1.5
Receive Signaling All ones.
0=allow robbed signaling bits to appear at RSER
1=force all robbed signaling bits at RSER to 1
TSCLKM
CCR1.4
TSYSCLK Mode Select.
0=if TSYSCLK is 1.544 MHz
1=if TSYSCLK is 2.048 MHz
RSCLKM
CCR1.3
RSYSCLK Mode Select.
0=if RSYSCLK is 1.544 MHz
1=if RSYSCLK is 2.048 MHz
RESE
CCR1.2
Receive Elastic Store Enable.
0=elastic store is bypassed
1=elastic store is enabled
PLB
CCR1.1
Payload Loopback.
0=loopback disabled
1=loopback enabled
FLB
CCR1.0
Framer Loopback.
0=loopback disabled
1=loopback enabled
(LSB)
FLB
PAYLOAD LOOPBACK
When CCR1.1 is set to a one, the DS21Q41B will be forced into Payload LoopBack (PLB). Normally,
this loopback is only enabled when ESF framing is being performed. In a PLB situation, the DS21Q41B
will loop the 192 bits of payload data (with BPVs corrected) from the receive section back to the transmit
section. The FPS framing pattern, CRC6 calculation, and the FDL bits are not looped back; they are
reinserted by the DS21Q41B. When PLB is enabled, the following will occur:
1. Data will be transmitted from the TPOS and TNEG pins synchronous with RCLK instead of TCLK.
2. All of the receive side signals will continue to operate normally.
.
3. The TCHCLK and TCHBLK signals are forced low.
4. Data at the TSER pin is ignored.
5. The TLCLK signal will become synchronous with RCLK instead of TCLK.
18 of 61
DS21Q41B
FRAMER LOOPBACK
When CCR1.0 is set to a 1, the DS21Q41B will enter a Framer LoopBack (FLB) mode. This loopback is
useful in testing and debugging applications. In FLB, the DS21Q41B will loop data from the transmit
side back to the receive side. When FLB is enabled, the following will occur:
1. An unframed all 1s code will be transmitted at TPOS and TNEG.
2. Data at RPOS and RNEG will be ignored.
3. All receive side signals will take on timing synchronous with TCLK instead of RCLK.
CCR2: COMMON CONTROL REGISTER 2 (Address=38 Hex)
(MSB)
TFM
TB8ZS
TSLC96
TFDL
RFM
RB8ZS
RSLC96
SYMBOL
POSITION
NAME AND DESCRIPTION
TFM
CCR2.7
Transmit Frame Mode Select.
0=D4 framing mode
1=ESF framing mode
TB8ZS
CCR2.6
Transmit B8ZS Enable.
0=B8ZS disabled
1=B8ZS enabled
TSLC96
CCR2.5
Transmit SLC-96/Fs Bit Insertion Enable.
0=SLC-96 disabled
1=SLC-96 enabled
TFDL
CCR2.4
Transmit 0 Stuffer Enable.
0=0 stuffer disabled
1=0 stuffer enabled
RFM
CCR2.3
Receive Frame Mode Select.
0=D4 framing mode
1=ESF framing mode
RB8ZS
CCR2.2
Receive B8ZS Enable.
0=B8ZS disabled
1=B8ZS enabled
RSLC96
CCR2.1
Receive SLC-96 Enable.
0=SLC-96 disabled
1=SLC-96 enabled
RFDL
CCR2.0
Receive 0 Destuffer Enable.
0=0 destuffer disabled
1=0 destuffer enabled
19 of 61
(LSB)
RFDL
DS21Q41B
CCR3: COMMON CONTROL REGISTER 3 (Address=30 Hex)
(MSB)
ESMDM
ESR
RLOS
RSMS
PDE
TLD
TLU
(LSB)
-
SYMBOL
POSITION
NAME AND DESCRIPTION
ESMDM
CCR3.7
Elastic Store Minimum Delay Mode. See Section 10.3 for
details.
0=elastic stores operate at full two-frame depth
1=elastic stores operate at 32-bit depth
ESR
CCR3.6
Elastic Store Reset. Setting this bit from a 0 to a 1 will force the
elastic stores to a known depth. Should be toggled after
RSYSCLK and TSYSCLK have been applied and are stable.
Must be cleared and set again for a subsequent reset.
RLOS
CCR3.5
Function of the RLOS/LOTC Output.
0=Receive Loss of Sync (RLOS)
1=Loss of Transmit Clock (LOTC)
RSMS
CCR3.4
RSYNC Multiframe Skip Control. Useful in framing format
conversions from D4 to ESF.
0=RSYNC will output a pulse at every multiframe
1=RSYNC will output a pulse at every other multiframe note:
for this bit to have any affect, the RSYNC must be set to output
multiframe pulses (RCR2.4=1 and RCR2.3=0).
PDE
CCR3.3
Pulse Density Enforcer Enable.
0=disable transmit pulse density enforcer
1=enable transmit pulse density enforcer
TLD
CCR3.2
Transmit Loop Down Code (001).
0=transmit data normally
1=replace normal transmitted data with loop down code
TLU
CCR3.1
Transmit Loop Up Code (00001).
0=transmit data normally
1=replace normal transmitted data with loop up code
-
CCR3.0
Not Assigned. Must be set to 0 when written
LOOP CODE GENERATION
When either the CCR3.1 or CCR3.2 bits are set to one, the DS21Q41B will replace the normal
transmitted payload with either the Loop Up or Loop Down code respectively. The DS21Q41B will
overwrite the repeating loop code pattern with the framing bits. The SCT will continue to transmit the
loop codes as long as either bit is set. It is an illegal state to have both CCR3.1 and CCR3.2 set to 1 at the
same time.
20 of 61
DS21Q41B
PULSE DENSITY ENFORCER
The DS21Q41B always examines both the transmit and receive data streams for violations of the
following rules which are required by ANSI T1.403-1989: - no more than 15 consecutive 0s - at least N
ones in each and every time window of 8 x (N +1) bits where N=1 through 23. Violations for the transmit
and receive data streams are reported in the RIR2.2 and RIR2.1 bits, respectively.
When the CCR3.3 is set to 1, the DS21Q41B will force the transmitted stream to meet this requirement
no matter the content of the transmitted stream. When running B8ZS, the CCR3.3 bit should be set to 0
since B8ZS encoded data streams cannot violate the pulse density requirements.
POWER-UP SEQUENCE
On power-up, after the supplies are stable, the DS21Q41B should be configured for operation by writing
to all of the internal registers (this includes setting the Test Registers to 00Hex) since the contents of the
internal registers cannot be predicted on power-up. Finally, after the TSYSCLK and RSYSCLK inputs
are stable, the ESR bit should be toggled from a 0 to a 1 (this step can be skipped if the elastic stores are
disabled).
4.0 STATUS AND INFORMATION REGISTERS
There is a set of four registers that contain information on the current real time status of the DS21Q41B,
Status Register 1 (SR1), Status Register 2 (SR2), Receive Information Register 1 (RIR1), and Receive
Information Register 2 (RIR2). When a particular event has occurred (or is occurring), the appropriate bit
in one of these four registers will be set to a 1. All of the bits in these registers operate in a latched
fashion. This means that if an event occurs and a bit is set to a 1 in any of the registers, it will remain set
until the user reads that bit. The bit will be cleared when it is read and it will not be set again until the
event has occurred again or if the alarm(s) is still present.
The user will always precede a read of these registers with a write. The byte written to the register will
inform the DS21Q41B which bits the user wishes to read and have cleared. The user will write a byte to
one of these four registers, with a 1 in the bit positions he or she wishes to read and a 0 in the bit positions
he or she does not wish to obtain the latest information on. When a 1 is written to a bit location, the read
register will be updated with current value and it will be cleared. When a 0 is written to a bit position, the
read register will not be updated and the previous value will be held. A write to the status and information
registers will be immediately followed by a read of the same register. The read result should be logically
AND’ed with the mask byte that was just written and this value should be written back into the same
register to insure that the bit does indeed clear. This second write is necessary because the alarms and
events in the status registers occur asynchronously in respect to their access via the parallel port. The
write-read-write scheme is unique to the four status registers and it allows an external microcontroller or
microprocessor to individually poll certain bits without disturbing the other bits in the register. This
operation is key in controlling the DS21Q41B with higher-order software languages.
The SR1 and SR2 registers have the unique ability to initiate a hardware interrupt via the INT output pin.
All four framers within the DS21Q41B share the INT output. Each of the alarms and events in the SR1
and SR2 can be either masked or unmasked from the interrupt pins via the Interrupt Mask Register 1
(IMR1) and Interrupt Mask Register 2 (IMR2) respectively. The user can determine which framer has
active interrupts by polling the Interrupt Status Register (ISR).
21 of 61
DS21Q41B
ISR: INTERRUPT STATUS REGISTER (any unused address)
(MSB)
F3SR2
F3SR1
F2SR2
F2SR1
F1SR2
F1SR1
F0SR2
SYMBOL
POSITION
NAME AND DESCRIPTION
F3SR2
ISR.7
Status of Interrupt for SR2 in Framer 3.
1=interrupt active.
F3SR1
ISR.6
Status of Interrupt for SR1 in Framer 3.
1=interrupt active.
F2SR2
ISR.5
Status of Interrupt for SR2 in Framer 2.
1=interrupt active.
F2SR1
ISR.4
Status of Interrupt for SR1 in Framer 2.
1=interrupt active.
F1SR2
ISR.3
Status of Interrupt for SR2 in Framer 1.
1=interrupt active.
F1SR1
ISR.2
Status of Interrupt for SR1 in Framer 1.
1=interrupt active.
F0SR2
ISR.1
Status of Interrupt for SR2 in Framer 0.
1=interrupt active.
F0SR1
ISR.0
Status of Interrupt for SR1 in Framer 0.
1=interrupt active.
22 of 61
(LSB)
F0SR1
DS21Q41B
RIR1: RECEIVE INFORMATION REGISTER 1 (Address=22 Hex)
(MSB)
COFA
8ZD
16ZD
RESF
RESE
SEFE
B8ZS
(LSB)
FBE
SYMBOL
POSITION
NAME AND DESCRIPTION
COFA
RIR1.7
Change of Frame Alignment. Set when the last resync resulted
in a change of frame or multiframe alignment.
8ZD
RIR1.6
Eight 0 Detect. Set when a string of at least eight consecutive 0s
(regardless of the length of the string) have been received at
RPOS and RNEG.
16ZD
RIR1.5
Sixteen 0 Detect. Set when a string of at least 16 consecutive 0s
(regardless of the length of the string) have been received at
RPOS and RNEG.
RESF
RIR1.4
Receive Elastic Store Full. Set when the receive elastic store
buffer fills and a frame is deleted.
RESE
RIR1.3
Receive Elastic Store Empty. Set when the receive elastic store
buffer empties and a frame is repeated.
SEFE
RIR1.2
Severely Errored Framing Event. Set when 2 out of 6 framing
bits (Ft or FPS) are received in error.
B8ZS
RIR1.1
B8ZS Code Word Detect. Set when a B8ZS code word is
detected at RPOS and RNEG independent of whether the B8ZS
mode is selected or not via CCR2.6. Useful for automatically
setting the line coding.
FBE
RIR1.0
Frame Bit Error. Set when a Ft (D4) or FPS (ESF) framing bit
is received in error.
23 of 61
DS21Q41B
RIR2: RECEIVE INFORMATION REGISTER 2 (Address=31 Hex)
(MSB)
RLOSC
RCLC
TESF
TESE
TSLIP
RBLC
RPDV
(LSB)
TPDV
SYMBOL
POSITION
NAME AND DESCRIPTION
RLOSC
RIR2.7
Receive Loss of Sync Clear. Set when the framer achieves
synchronization; will remain set until read.
RCLC
RIR2.6
Receive Carrier Loss Clear. Set when the carrier signal is
restored; will remain set until read.
TESF
RIR2.5
Transmit Elastic Store Full. Set when the transmit elastic store
buffer fills and a frame is deleted.
TESE
RIR2.4
Transmit Elastic Store Empty. Set when the transmit elastic
store buffer empties and a frame is repeated.
TSLIP
RIR2.3
Transmit Elastic Store Slip Occurrence. Set when the transmit
elastic store has either repeated or deleted a frame.
TBLC
RIR2.2
Receive Blue Alarm Clear. Set when the Blue Alarm (AIS) is
no longer detected; will remain set until read.
RPDV
RIR2.1
Receive Pulse Density Violation. Set when the receive data
stream does not meet the ANSI T1.403 requirements for pulse
density.
TPDV
RIR2.0
Transmit Pulse Density Violation. Set when the transmit data
stream does not meet the ANSI T1.403 requirements for pulse
density.
24 of 61
DS21Q41B
SR1: STATUS REGISTER 1 (Address=20 Hex)
(MSB)
LUP
LDN
LOTC
RSLIP
RBL
RYEL
RCL
(LSB)
RLOS
SYMBOL
POSITION
NAME AND DESCRIPTION
LUP
SR1.7
Loop Up Code Detected. Set when the repeating ...00001...
loop up code is being received.
LDN
SR1.6
Loop Down Code Detected. Set when the repeating ...001...
loop down code is being received.
LOTC
SR1.5
Loss of Transmit Clock. Set when the TCLK pin has not
transitioned for one channel time (or 5.2 µs). Will force the
RLOS/LOTC pin high if enabled via CCR1.6. Also will force
transmit side formatter to switch to RCLK if so enabled via
TCR1.7. Based on RCLK.
RSLIP
SR1.4
Receive Elastic Store Slip Occurrence. Set when the receive
elastic store has either repeated or deleted a frame.
RBL
SR1.3
Receive Blue Alarm. Set when an unframed all ones code is
received at RPOS and RNEG.
RYEL
SR1.2
Receive Yellow Alarm. Set when a yellow alarm is received at
RPOS and RNEG.
RCL
SR1.1
Receive Carrier Loss. Set when 192 consecutive 0s have been
detected at RPOS and RNEG.
RLOS
SR1.0
Receive Loss of Sync. Set when the device is not synchronized
to the receive T1 stream.
25 of 61
DS21Q41B
DS21Q41B ALARM SET & CLEAR CRITERIA Table 4-2
ALARM
SET CRITERIA
CLEAR CRITERIA
Blue Alarm (AIS)
(see note 1 below)
when over a 3 ms window, five
or less 0s are received
when over a 3 ms window, six or
more 0s are received
Yellow Alarm (RAI)
1. D4 bit 2 mode (RCR2.2=0)
when bit 2 of 256 consecutive
channels is set to 0 for at least
254 occurrences
when bit 2 of 256 consecutive
channels is set to 0 for less than
254 occurrences
2. D4 12th F-bit mode
(RCR2.2=1; this mode is also
referred to as the "Japanese
Yellow Alarm")
when the 12th framing bit is set
to one for two consecutive
occurrences
when the 12th framing bit is set to
0 for two consecutive occurrences
3. ESF mode
when 16 consecutive patterns of
00FF appear in the FDL
when 14 or less patterns of 00FF
hex out of 16 possible appear in
the FDL
Red Alarm (RCL)
(this alarm is also referred to
as Loss of Signal)
when 192 consecutive 0s are
received
when 14 or more ones out of 112
possible bit positions are received
starting with the first one received
NOTES:
1. The definition of Blue Alarm (or Alarm Indication Signal) is an unframed all 1s signal. Blue alarm
detectors should be able to operate properly in the presence of a 10-3 error rate and they should not
falsely trigger on a framed all 1s signal. The blue alarm criteria in the DS21Q41B has been set to
achieve this performance. It is recommended that the RBL bit be qualified with the RLOS bit.
2. ANSI specifications use a different nomenclature than the DS21Q41B does; the following terms are
equivalent:
RBL=AIS
RCL=LOS
RLOS=LOF
RYEL=RAI
LOOP UP/DOWN CODE DETECTION
Bits SR1.7 and SR1.6 will indicate when either the standard “loop up” or “loop down” codes are being
received by the DS21Q41B. When a loop up code has been received for 5 seconds, the CPE is expected
to loop the recovered data (without correcting BPVs) back to the source. The loop down code indicates
that the loopback should be discontinued. See the AT&T publication TR 62411 for more details. The
DS21Q41B will detect the loop up/down codes in both framed and unframed circumstances with bit error
rates as high as 10**-2. The loop code detector has a nominal integration period of 48 ms. Hence, after
about 48 ms of receiving either code, the proper status bit will be set to a 1. After this initial indication, it
is recommend that the software poll the DS21Q41B every 100 ms to 500 ms until 5 seconds has elapsed
to insure that the code is continuously present.
26 of 61
DS21Q41B
SR2: STATUS REGISTER 2 (Address=21 Hex)
(MSB)
RMF
TMF
SEC
RFDL
TFDL
RMTCH
RAF
(LSB)
LORC
SYMBOL
POSITION
NAME AND DESCRIPTION
RMF
SR2.7
Receive Multiframe. Set on receive multiframe boundaries.
TMF
SR2.6
Transmit Multiframe. Set on transmit multiframe boundaries.
SEC
SR2.5
1-Second Timer. Set on increments of 1 second based on
RCLK; will be set in increments of 999 ms, 999 ms, and 1002
ms every 3 seconds.
RFDL
SR2.4
Receive FDL Buffer Full. Set when the receive FDL buffer
(RFDL) fills to capacity (8 bits).
TFDL
SR2.3
Transmit FDL Buffer Empty. Set when the transmit FDL
buffer (TFDL) empties.
RMTCH
SR2.2
Receive FDL Match Occurrence. Set when the RFDL matches
either RFDLM1 or RFDLM2.
RAF
SR2.1
Receive FDL Abort. Set when eight consecutive 1s are received
in the FDL.
LORC
SR2.0
Loss of Receive Clock. Set when the RCLK pin has not
transitioned for at least 2 µs (3 µs ± 1 µs).
27 of 61
DS21Q41B
IMR1: INTERRUPT MASK REGISTER (Address=7F Hex)
(MSB)
LUP
LDN
LOTC
SLIP
RBL
RYEL
SYMBOL
POSITION
NAME AND DESCRIPTION
LUP
IMR1.7
Loop Up Code Detected.
0=interrupt masked
1=interrupt enabled
LDN
IMR1.6
Loop Down Code Detected.
0=interrupt masked
1=interrupt enabled
LOTC
IMR1.5
Loss of Transmit Clock.
0=interrupt masked
1=interrupt enabled
SLIP
IMR1.4
Elastic Store Slip Occurrence.
0=interrupt masked
1=interrupt enabled
RBL
IMR1.3
Receive Blue Alarm.
0=interrupt masked
1=interrupt enabled
RYEL
IMR1.2
Receive Yellow Alarm.
0=interrupt masked
1=interrupt enabled
RCL
IMR1.1
Receive Carrier Loss.
0=interrupt masked
1=interrupt enabled
RLOS
IMR1.0
Receive Loss of Sync.
0=interrupt masked
1=interrupt enabled
28 of 61
RCL
(LSB)
RLOS
DS21Q41B
IMR2: INTERRUPT MASK REGISTER 2 (Address=6F Hex)
(MSB)
RMF
TMF
SEC
RFDL
TFDL
RMTCH
SYMBOL
POSITION
NAME AND DESCRIPTION
RMF
IMR2.7
Receive Multiframe.
0=interrupt masked
1=interrupt enabled
TMF
IMR2.6
Transmit Multiframe.
0=interrupt masked
1=interrupt enabled
SEC
IMR2.5
One Second Timer.
0=interrupt masked
1=interrupt enabled
RFDL
IMR2.4
Receive FDL Buffer Full.
0=interrupt masked
1=interrupt enabled
TFDL
IMR2.3
Transmit FDL Buffer Empty.
0=interrupt masked
1=interrupt enabled
RMTCH
IMR2.2
Receive FDL Match Occurrence.
0=interrupt masked
1=interrupt enabled
RAF
IMR2.1
Receive FDL Abort.
0=interrupt masked
1=interrupt enabled
LORC
IMR2.0
Loss of Receive Clock.
0=interrupt masked
1=interrupt enabled
29 of 61
RAF
(LSB)
LORC
DS21Q41B
5.0 ERROR COUNT REGISTERS
There are a set of three counters in the DS21Q41B that record bipolar violations, excessive 0s, errors in
the CRC6 code words, framing bit errors, and number of multiframes that the device is out of receive
synchronization. Each of these three counters are automatically updated on 1-second boundaries as
determined by the one second timer in Status Register 2 (SR2.5). Hence, these registers contain
performance data from the previous second. The user can use the interrupt from the 1-second timer to
determine when to read these registers. The user has a full second to read the counters before the data is
lost. All three counters will saturate at their respective maximum counts and they will not rollover (note:
only the Line Code Violation Count Register has the potential to overflow).
5.1 Line Code Violation Count Register (LCVCR)
Line Code Violation Count Register 1 High (LCVCR1) is the most significant word and LCVCR2 is the
least significant word of a 16-bit counter that records code violations (CVs). CVs are defined as Bipolar
Violations (BPVs) or excessive 0s. See Table 5-1 for details of exactly what the LCVCRs count. If the
B8ZS mode is set for the receive side via CCR2.2, then B8ZS code words are not counted. This counter is
always enabled; it is not disabled during receive loss of synchronization (RLOS=1) conditions.
LCVCR1: LINE CODE VIOLATION COUNT REGISTER 1 (Address=23 Hex)
LCVCR2: LINE CODE VIOLATION COUNT REGISTER 2 (Address=24 Hex)
(MSB)
LCV15
LCV14
LCV13
LCV12
LCV11
LCV10
LCV9
(LSB)
LCV8
LCVCR1
LCV7
LCV6
LCV5
LCV4
LCV3
LCV2
LCV1
LCV0
SYMBOL
POSITION
NAME AND DESCRIPTION
CV16
LCVCR1.7
MSB of the 16-bit code violation count
CV0
LCVCR2.0
LSB of the 16-bit code violation count
LCVCR2
LINE CODE VIOLATION COUNTING ARRANGEMENTS Table 5-1
COUNT EXCESSIVE
0S? (RCR1.7)
no
B8ZS ENABLED?
(CCR2.2)
no
WHAT IS COUNTED IN THE LCVCRs
yes
no
BPVs + 16 consecutive 0s
no
yes
BPVs (B8ZS code words not counted)
yes
yes
BPVs + 8 consecutive 0s
BPVs
5.2 Path Code Violation Count Register (PCVCR)
When the receive side of the DS21Q41B is set to operate in the ESF framing mode (CCR2.3=1), PCVCR
will automatically be set as a 12-bit counter that will record errors in the CRC6 code words. When set to
operate in the D4 framing mode (CCR2.3=0), PCVCR will automatically count errors in the Ft framing
bit position. Via the RCR2.1 bit, the DS21Q41B can be programmed to also report errors in the Fs
framing bit position. The PCVCR will be disabled during receive loss of synchronization (RLOS=1)
conditions. See Table 5-2 for a detailed description of exactly what errors the PCVCR counts.
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DS21Q41B
PCVCR1: PATH VIOLATION COUNT REGISTER 1 (Address=25 Hex)
PCVCR2: PATH VIOLATION COUNT REGISTER 2 (Address=26 Hex)
(MSB)
(LSB)
(note 1)
(note 1)
(note 1)
(note 1)
CRC/FB11
CRC/FB10
CRC/FB9
CRC/FB8
PCVCR1
CRC/FB7
CRC/FB6
CRC/FB5
CRC/FB4
CRC/FB3
CRC/FB2
CRC/FB1
CRC/FB0
PCVCR2
SYMBOL
POSITION
NAME AND DESCRIPTION
CRC/FB11
PCVCR1.3
MSB of the 12-bit CRC6 error or frame bit error count (note 2)
CRC/FB0
PCVCR2.0
LSB of the 12-bit CRC6 error or frame bit error count (note 2)
NOTES:
1. The upper nibble of the counter at address 25 is used by the Multiframes Out of Sync Count Register.
2. PCVCR counts either errors in CRC code words (in the ESF framing mode; CCR2.3=1) or errors in
the framing bit position (in the D4 framing mode; CCR2.3=0).
PATH CODE VIOLATION COUNTING ARRANGEMENTS Table 5-2
WHAT IS COUNTED IN THE PCVCRs
FRAMING MODE
(CCR2.3)
COUNT Fs ERRORS?
(RCR2.1)
D4
no
errors in the Ft pattern
D4
yes
errors in both the Ft and Fs patterns
ESF
don't care
errors in the CRC6 code words
5.3 Multiframes Out of Sync Count Register (MOSCR)
Normally the MOSCR is used to count the number of multiframes that the receive synchronizer is out of
sync (RCR2.0=1). This number is useful in ESF applications needing to measure the parameters Loss Of
Frame Count (LOFC) and ESF Error Events as described in AT&T publication TR54016. When the
MOSCR is operated in this mode, it is not disabled during receive loss of synchronization (RLOS=1)
conditions. The MOSCR has alternate operating mode whereby it will count either errors in the Ft
framing pattern (in the D4 mode) or errors in the FPS framing pattern (in the ESF mode). When the
MOSCR is operated in this mode, it is disabled during receive loss of synchronization (RLOS=1)
conditions. See Table 5-3 for a detailed description of what the MOSCR is capable of counting.
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DS21Q41B
MOSCR1:
MULTIFRAMES OUT OF SYNC COUNT REGISTER 1 (Address=25 Hex)
MOSCR2:
MULTIFRAMES OUT OF SYNC COUNT REGISTER 2 (Address=27 Hex)
(MSB)
(LSB)
MOS/FB11
MOS/FB10
MOS/FB9
MOS/FB8
(note 1)
(note 1)
(note 1)
(note 1)
MOSCR1
MOS/FB7
MOS/FB6
MOS/FB5
MOS/FB4
MOS/FB3
MOS/FB2
MOS/FB1
MOS/FB0
MOSCR2
SYMBOL
POSITION
NAME AND DESCRIPTION
MOS/FB11
MOSCR1.7
MSB of the 12-Bit multiframes out of sync or F-bit error count
(note 2)
MOS/FB0
MOSCR2.0
LSB of the 12-bit multiframes out of sync or F-bit error count
(note 2)
NOTES:
1. The lower nibble of the counter at address 25 is used by the Path Code Violation Count Register.
2. MOSCR counts either errors in framing bit position (RCR2.0=0) or the number of multiframes out of
sync (RCR2.0=1).
MULTIFRAMES OUT OF SYNC COUNTING ARRANGEMENTS Table 5-3
WHAT IS COUNTED IN THE MOSCRs
FRAMING MODE
(CCR2.3)
COUNT MOS OR F-BIT
ERRORS? (RCR2.0)
D4
MOS
number of multiframes out of sync
D4
F-BIT
errors in the Ft pattern
ESF
MOS
number of multiframes out of sync
ESF
F-BIT
errors in the FPS pattern
6.0 FDL/Fs EXTRACTION AND INSERTION
The DS21Q41B has the ability to extract/insert data from/into the Facility Data Link (FDL) in the ESF
framing mode and from/into Fs bit position in the D4 framing mode. Since SLC-96 utilizes the Fs bit
position, this capability can also be used in SLC-96 applications. The operation of the receive and
transmit sections will be discussed separately. Contact the factory for a copy of C language source code
for implementing the FDL on the DS21Q41B.
6.1 Receive Section
In the receive section, the recovered FDL bits or Fs bits are shifted bit-by-bit into the Receive FDL
register (RFDL). Since the RFDL is 8 bits in length, it will fill up every 2 ms (8 times 250 µs). The
DS21Q41B will signal an external microcontroller that the buffer has filled via the SR2.4 bit. If enabled
via IMR2.4, the INT pin will toggle low indicating that the buffer has filled and needs to be read. The
user has 2 ms to read this data before it is lost. If the byte in the RFDL matches either of the bytes
programmed into the RFDLM1 or RFDLM2 registers, then the SR2.2 bit will be set to a 1 and the INT
pin will toggled low if enabled via IMR2.2. This feature allows an external microcontroller to ignore the
FDL or Fs pattern until an important event occurs.
32 of 61
DS21Q41B
The DS21Q41B also contains a 0 destuffer which is controlled via the CCR2.0 bit. In both ANSI T1.403
and TR54016, communications on the FDL follows a subset of a LAPD protocol. The LAPD protocol
states that no more than five 1s should be transmitted in a row so that the data does not resemble an
opening or closing flag (01111110) or an abort signal (11111111). If enabled via CCR2.0, the DS21Q41B
will automatically look for five 1s in a row, followed by a 0. If it finds such a pattern, it will automatically
remove the 0. If the 0 destuffer sees six or more 1s in a row followed by a 0, the 0 is not removed. The
CCR2.0 bit should always be set to a 1 when the DS21Q41B is extracting the FDL. More on how to use
the DS21Q41B in FDL applications is covered in a separate Application Note.
RFDL: RECEIVE FDL REGISTER (Address=28 Hex)
(MSB)
RFDL7
RFDL6
RFDL5
RFDL4
RFDL3
RFDL2
SYMBOL
POSITION
NAME AND DESCRIPTION
RFDL7
RFDL.7
MSB of the received FDL code
RFDL0
RFDL.0
LSB of the received FDL code
RFDL1
(LSB)
RFDL0
The Receive FDL Register (RFDL) reports the incoming Facility Data Link (FDL) or the incoming Fs
bits. The LSB is received first.
RFDLM1: RECEIVE FDL MATCH REGISTER 1 (Address=29 Hex)
RFDLM2: RECEIVE FDL MATCH REGISTER 2 (Address=2A Hex)
(MSB)
RFDL7
RFDL6
RFDL5
RFDL4
RFDL3
RFDL2
SYMBOL
POSITION
RFDL7
RFDL.7
MSB of the FDL match code
RFDL0
RFDL.0
LSB of the FDL match code
RFDL1
(LSB)
RFDL0
NAME AND DESCRIPTION
When the byte in the Receive FDL Register matches either of the two Receive FDL Match Registers
(RFDLM1/RFDLM2), RSR2.2 will be set to a 1 and the INT will go active if enabled via IMR2.2.
6.2 Transmit Section
The transmit section will shift out into the T1 data stream, either the FDL (in the ESF framing mode) or
the Fs bits (in the D4 framing mode) contained in the Transmit FDL register (TFDL). When a new value
is written to the TFDL, it will be multiplexed serially (LSB first) into the proper position in the outgoing
T1 data stream. After the full 8 bits have been shifted out, the DS21Q41B will signal the host
microcontroller that the buffer is empty and that more data is needed by setting the SR2.3 bit to a 1. The
INT will also toggle low if enabled via IMR2.3. The user has 2 ms (1.5 ms in SLC-96 applications) to
update the TFDL with a new value. If the TFDL is not updated, the old value in the TFDL will be
transmitted once again.
The DS21Q41B also contains a 0 stuffer which is controlled via the CCR2.4 bit. In both ANSI T1.403
and TR54016, communications on the FDL follows a subset of a LAPD protocol. The LAPD protocol
33 of 61
DS21Q41B
states that no more than five 1s should be transmitted in a row so that the data does not resemble an
opening or closing flag (01111110) or an abort signal (11111111). If enabled via CCR2.4, the DS21Q41B
will automatically look for five 1s in a row.
If it finds such a pattern, it will automatically insert a 0 after the five ones. The CCR2.4 bit should always
be set to a 1 when the DS21Q41B is inserting the FDL. More on how to use the DS21Q41B in FDL
applications is covered in a separate Application Note.
TFDL: TRANSMIT FDL REGISTER (Address=7E Hex)
(MSB)
TFDL7
TFDL6
TFDL5
TFDL4
TFDL3
TFDL2
SYMBOL
POSITION
TFDL7
TFDL.7
MSB of the FDL code to be transmitted
TFDL0
TFDL.0
LSB of the FDL code to be transmitted
TFDL1
(LSB)
TFDL0
NAME AND DESCRIPTION
The Transmit FDL Register (TFDL) contains the Facility Data Link (FDL) information that is to be
inserted on a byte basis into the outgoing T1 data stream. The LSB is transmitted first.
7.0 SIGNALING OPERATION
The robbed bit signaling bits in embedded in the T1 stream can be extracted from the receive stream and
inserted into the transmit stream by the DS21Q41B. There is a set of 12 registers for the receive side
(RS1 to RS12) and 12 registers on the transmit side (TS1 to TS12). The signaling registers are detailed
below. The CCR1.5 bit is used to control the robbed signaling bits as they appear at RSER. If CCR1.5 is
set to 0, then the robbed signaling bits will appear at RSER in their proper position as they are received. If
CCR1.5 is set to a 1, then the robbed signaling bit positions will be forced to a 1 at RSER.
34 of 61
DS21Q41B
RS1 TO RS12: RECEIVE SIGNALING REGISTERS (Address=60 to 6B Hex)
(MSB)
A(8)
A(2)
(LSB)
A(1)
A(7)
A(6)
A(5)
A(4)
A(3)
RS1 (60)
A(16)
A(15)
A(14)
A(13)
A(12)
A(11)
A(10)
A(9)
RS2 (61)
A(24)
A(23)
A(22)
A(21)
A(20)
A(19)
A(18)
A(17)
RS3 (62)
B(8)
B(7)
B(6)
B(5)
B(4)
B(3)
B(2)
B(1)
RS4 (63)
B(16)
B(15)
B(14)
B(13)
B(12)
B(11)
B(10)
B(9)
RS5 (64)
B(24)
B(23)
B(22)
B(21)
B(20)
B(19)
B(18)
B(17)
RS6 (65)
A/C(8)
A/C(7)
A/C(6)
A/C(5)
A/C(4)
A/C(3)
A/C(2)
A/C(1)
RS7 (66)
A/C(16)
A/C(15)
A/C(14)
A/C(13)
A/C(12)
A/C(11)
A/C(10)
A/C(9)
RS8 (67)
A/C(24)
A/C(23)
A/C(22)
A/C(21)
A/C(20)
A/C(19)
A/C(18)
A/C(17)
RS9 (68)
B/D(8)
B/D(7)
B/D(6)
B/D(5)
B/D(4)
B/D(3)
B/D(2)
B/D(1)
RS10 (69)
B/D(16)
B/D(15)
B/D(14)
B/D(13)
B/D(12)
B/D(11)
B/D(10)
B/D(9)
RS11 (6A)
B/D(24)
B/D(23)
B/D(22)
B/D(21)
B/D(20)
B/D(19)
B/D(18)
B/D(17)
RS12 (6B)
SYMBOL
POSITION
NAME AND DESCRIPTION
D(24)
RS12.7
Signaling Bit D in Channel 24
A(1)
RS1.0
Signaling Bit A in Channel 1
Each Receive Signaling Register (RS1 to RS12) reports the incoming robbed bit signaling from eight
DS0 channels. In the ESF framing mode, there can be up to four signaling bits per channel (A, B, C, and
D). In the D4 framing mode, there are only two signaling bits per channel (A and B). In the D4 framing
mode, the DS21Q41B will replace the C and D signaling bit positions with the A and B signaling bits
from the previous multiframe. Hence, whether the DS21Q41B is operated in either framing mode, the
user needs only to retrieve the signaling bits every 3 ms. The bits in the Receive Signaling Registers are
updated on multiframe boundaries in both framing modes so the user can utilize the Receive Multiframe
Interrupt in the Receive Status Register 2 (SR2.7) to know when to retrieve the signaling bits. The
Receive Signaling Registers are frozen and not updated during a loss of sync condition (SR1.0=1). They
will contain the most recent signaling information before the “OOF” occurred.
35 of 61
DS21Q41B
TS1 TO TS12: TRANSMIT SIGNALING REGISTERS (Address=70 to 7B Hex)
(MSB)
A(8)
A(2)
(LSB)
A(1)
A(7)
A(6)
A(5)
A(4)
A(3)
TS1 (70)
A(16)
A(15)
A(14)
A(13)
A(12)
A(11)
A(10)
A(9)
TS2 (71)
A(24)
A(23)
A(22)
A(21)
A(20)
A(19)
A(18)
A(17)
TS3 (72)
B(8)
B(7)
B(6)
B(5)
B(4)
B(3)
B(2)
B(1)
TS4 (73)
B(16)
B(15)
B(14)
B(13)
B(12)
B(11)
B(10)
B(9)
TS5 (74)
B(24)
B(23)
B(22)
B(21)
B(20)
B(19)
B(18)
B(17)
TS6 (75)
A/C(8)
A/C(7)
A/C(6)
A/C(5)
A/C(4)
A/C(3)
A/C(2)
A/C(1)
TS7 (76)
A/C(16)
A/C(15)
A/C(14)
A/C(13)
A/C(12)
A/C(11)
A/C(10)
A/C(9)
TS8 (77)
A/C(24)
A/C(23)
A/C(22)
A/C(21)
A/C(20)
A/C(19)
A/C(18)
A/C(17)
TS9 (78)
B/D(8)
B/D(7)
B/D(6)
B/D(5)
B/D(4)
B/D(3)
B/D(2)
B/D(1)
TS10 (79)
B/D(16)
B/D(15)
B/D(14)
B/D(13)
B/D(12)
B/D(11)
B/D(10)
B/D(9)
TS11 (7A)
B/D(24)
B/D(23)
B/D(22)
B/D(21)
B/D(20)
B/D(19)
B/D(18)
B/D(17)
TS12 (7B)
SYMBOL
POSITION
NAME AND DESCRIPTION
D(24)
TS12.7
Signaling Bit D in Channel 24
A(1)
TS1.0
Signaling Bit A in Channel 1
Each Transmit Signaling Register (TS1 to TS12) contains the Robbed Bit signaling for eight DS0
channels that will be inserted into the outgoing stream if enabled to do so via TCR1.4. In the ESF framing
mode, there can be up to four signaling bits per channel (A, B, C, and D). On multiframe boundaries, the
DS21Q41B will load the values present in the Transmit Signaling Register into an outgoing signaling
shift register that is internal to the device. The user can utilize the Transmit Multiframe Interrupt in Status
Register 2 (SR2.6) to know when to update the signaling bits. In the ESF framing mode, the interrupt will
come every 3 ms and the user has a full 3 ms to update the TSRs. In the D4 framing mode, there are only
two framing bits per channel (A and B). However in the D4 framing mode, the DS21Q41B uses the C and
D-bit positions as the A and B bit positions for the next multiframe. The DS21Q41B will load the values
in the TSRs into the outgoing shift register every other D4 multiframe.
8.0 SPECIAL TRANSMIT SIDE REGISTERS
There is a set of seven registers in the DS21Q41B that can be used to custom tailor the data that is to be
transmitted onto the T1 line, on a channel by channel basis. Each of the 24 T1 channels can be either
forced to be transparent or to have a user defined idle code inserted into them. Each of these special
registers is defined below.
36 of 61
DS21Q41B
TTR1/TTR2/TTR3:
TRANSMIT TRANSPARENCY REGISTERS (Address=39 to 3B Hex)
(MSB)
CH8
CH7
CH6
CH5
CH4
CH3
CH2
(LSB)
CH1
TTR1 (29)
CH16
CH15
CH14
CH13
CH12
CH11
CH10
CH9
TTR2 (3A)
CH24
CH23
CH22
CH21
CH20
CH19
CH18
CH17
TTR3 (3B)
SYMBOL
POSITION
NAME AND DESCRIPTION
CH24
TTR3.7
Transmit Transparency Registers.
0=this DS0 channel is not transparent
CH1
TTR1.0
1=this DS0 channel is transparent
Each of the bit positions in the Transmit Transparency Registers (TTR1/TTR2/TTR3) represent a DS0
channel in the outgoing frame. When these bits are set to a 1, the corresponding channel is transparent (or
clear). If a DS0 is programmed to be clear, no robbed bit signaling will be inserted nor will the channel
have Bit 7 stuffing performed. However, in the D4 framing mode, bit 2 will be overwritten by a 0 when a
Yellow Alarm is transmitted. Also the user has the option to prevent the TTR registers from determining
which channels are to have Bit 7 stuffing performed. If the TCR2.0 and TCR1.3 bits are set to 1, then all
24 T1 channels will have Bit 7 stuffing performed on them regardless of how the TTR registers are
programmed. In this manner, the TTR registers are only affecting which channels are to have robbed bit
signaling inserted into them. Please see Figure 13-9 for more details.
TIR1/TIR2/TIR3: TRANSMIT IDLE REGISTERS (Address=3C to 3E Hex)
(MSB)
CH8
CH7
CH6
CH5
CH4
CH3
CH2
(LSB)
CH1
TIR1 (3C)
CH16
CH15
CH14
CH13
CH12
CH11
CH10
CH9
TIR2 (3D)
CH24
CH23
CH22
CH21
CH20
CH19
CH18
CH17
TIR3 (3E)
SYMBOL
POSITION
NAME AND DESCRIPTION
CH24
TIR3.7
Transmit Idle Registers.
0=do not insert the Idle Code into this DS0 channel
CH1
TIR1.0
1=insert the Idle Code into this channel
TIDR: TRANSMIT IDLE DEFINITION REGISTER (Address=3F Hex)
(MSB)
TIDR7
TIDR6
TIDR5
TIDR4
TIDR3
SYMBOL
POSITION
TIDR7
TIDR.7
MSB of the Idle Code
TIDR0
TIDR.0
LSB of the Idle Code
TIDR2
NAME AND DESCRIPTION
37 of 61
TIDR1
(LSB)
TIDR0
DS21Q41B
Each of the bit positions in the Transmit Idle Registers (TIR1/TIR2/TIR3) represent a DS0 channel in the
outgoing frame. When these bits are set to a 1, the corresponding channel will transmit the Idle Code
contained in the Transmit Idle Definition Register (TIDR). Robbed bit signaling and Bit 7 stuffing will
occur over the programmed Idle Code unless the DS0 channel is made transparent by the Transmit
Transparency Registers.
9.0 CLOCK BLOCKING REGISTERS
The Receive Channel Blocking Registers (RCBR1/RCBR2/RCBR3) and the Transmit Channel Blocking
Registers (TCBR1/TCBR2/TCBR3) control the RCHBLK and TCHBLK pins respectively. The
RCHBLK and TCHCLK pins are user-programmable outputs that can be forced either high or low during
individual channels. These outputs can be used to block clocks to a USART or LAPD controller in
Fractional T1 or ISDN-PRI applications. When the appropriate bits are set to a 1, the RCHBLK and
TCHCLK pins will be held high during the entire corresponding channel time. See the timing in Section
12 for an example.
RCBR1/RCBR2/RCBR3:
RECEIVE CHANNEL BLOCKING REGISTERS (Address=6C to 6E Hex)
(MSB)
CH8
CH7
CH6
CH5
CH4
CH3
CH2
(LSB)
CH1
RCBR1 (6C)
CH16
CH15
CH14
CH13
CH12
CH11
CH10
CH9
RCBR2 (6D)
CH24
CH23
CH22
CH21
CH20
CH19
CH18
CH17
RCBR3 (6E)
SYMBOL
POSITION
NAME AND DESCRIPTION
CH24
RCBR3.7
Receive Channel Blocking Registers.
0=force the RCHBLK pin to remain low during this channel time
CH1
RCBR1.0
1=force the RCHBLK pin high during this channel time
TCBR1/TCBR2/TCBR3:
TRANSMIT CHANNEL BLOCKING REGISTERS (Address=32 to 34 Hex)
(MSB)
CH8
CH7
CH6
CH5
CH4
CH3
CH2
(LSB)
CH1
TCBR1 (32)
CH16
CH15
CH14
CH13
CH12
CH11
CH10
CH9
TCBR2 (33)
CH24
CH23
CH22
CH21
CH20
CH19
CH18
CH17
TCBR3 (34)
SYMBOL
POSITION
NAME AND DESCRIPTION
CH24
TCBR3.7
Transmit Channel Blocking Registers.
0=force the TCHBLK pin to remain low during this channel time
CH1
TCBR1.0
1=force the TCHBLK pin high during this channel time
38 of 61
DS21Q41B
10.0 ELASTIC STORES OPERATION
Each framer within the DS21Q41B contains dual two-frame (386 bits) elastic stores, one for the receive
direction, and one for the transmit direction. These elastic stores have two main purposes. First, they can
be used to rate convert the T1 data stream to 2.048 Mbps (or a multiple of 2.048 Mbps) which is the E1
rate. Secondly, they can be used to absorb the differences in frequency and phase between the T1 data
stream and an asynchronous (i.e., not frequency locked) backplane clock (which can be 1.544 MHz or
2.048 MHz ). Both elastic stores contain full controlled slip capability which is necessary for this second
purpose. The receive side elastic store can be enabled via CCR1.2 and the transmit side elastic store is
enabled via CCR1.7. The elastic stores can be forced to a known depth via the Elastic Store Reset bit
(CCR3.6). Toggling the CCR3.6 bit forces the read and write pointers into opposite frames. Both elastic
stores within the DS21Q41B are fully independent and no restrictions apply to the sourcing of the various
clocks that are applied to them. The transmit side elastic store can be enabled whether the receive elastic
store is enabled or disabled and vice versa. Also, each elastic store can interface to either a 1.544 MHz or
2.048 MHz backplane without regard to the backplane rate the other elastic store is interfacing.
10.1 Receive Side
If the receive side elastic store is enabled (CCR1.2=1), then the user must provide either a 1.544 MHz
(CCR1.3=0) or 2.048 MHz (CCR1.3=1) clock at the RSYSCLK pin. The user has the option of either
providing a frame sync at the RSYNC pin (RCR2.3=1) or having the RSYNC pin provide a pulse on
frame boundaries (RCR2.3=0). If the user wishes to obtain pulses at the frame boundary, then RCR2.4
must be set to 0, and if the user wishes to have pulses occur at the multiframe boundary, then RCR2.4
must be set to 1. The DS21Q41B will always indicate frame boundaries via the RFSYNC output whether
the elastic store is enabled or not. If the elastic store is enabled, then multiframe boundaries will be
indicated via the RMSYNC output. If the user selects to apply a 2.048 MHz clock to the SYSCLK pin,
then the data output at RSER will be forced to all 1s every fourth channel and the F-bit will be deleted.
Hence channels 1, 5, 9, 13, 17, 21, 25, and 29 (timeslots 0, 4, 8, 12, 16, 20, 24, and 28) will be forced to a
1. Also, in 2.048 MHz applications, the RCHBLK output will be forced high during the same channels as
the RSER pin. See Section 12 for more details. This is useful in T1 to CEPT (E1) conversion
applications. If the 386-bit elastic buffer either fills or empties, a controlled slip will occur. If the buffer
empties, then a full frame of data (193 bits) will be repeated at RSER and the SR1.4 and RIR1.3 bits will
be set to a 1. If the buffer fills, then a full frame of data will be deleted and the SR1.4 and RIR1.4 bits will
be set to a 1.
10.2 Transmit Side
The operation of the transmit elastic store is very similar to the receive side. The transmit side elastic
store is enabled via CCR1.7. A 1.544 MHz (CCR1.4=0) or 2.048 MHz (CCR1.4=1) clock can be applied
to the TSYSCLK input. If the user selects to apply a 2.048 MHz clock to the TSYSCLK pin, then the data
output at TSER will be ignored every fourth channel. Hence channels 1, 5, 9, 13, 17, 21, 25, and 29
(timeslots 0, 4, 8, 12, 16, 20, 24, and 28) will be ignored. The user must supply a 8 kHz frame sync pulse
to the TFSYNC input. Also, in 2.048 MHz applications the TCHBLK output will be forced high during
the channels ignored by the DS21Q41B. See Section 12 for more details. Controlled slips in the transmit
elastic store are reported in the RIR2.3 bit and the direction of the slip is reported in the RIR2.5 and
RIR2.4 bits.
10.3 Minimum Delay Synchronous SYSCLK Mode
In applications where the DS21Q41B is connected to backplanes that are frequency locked to the
recovered T1 clock (i.e., the RCLK output), the full two-frame depth of the onboard elastic stores is really
not needed. In fact, in some delay sensitive applications, the normal two-frame depth may be excessive. If
the CCR3.7 bit is set to 1, then the receive elastic store (and also the transmit elastic store if it is enabled)
will be forced to a maximum depth of 32 bits instead of the normal 386 bits. In this mode, RSYSCLK
39 of 61
DS21Q41B
and TSYSCLK must be tied together and they must be frequency locked to RCLK. All of the slip
contention logic in the DS21Q41B is disabled (since slips cannot occur). Also, since the buffer depth is
no longer two frames deep, the DS21Q41B must be set up to source either a frame pulse at the RSYNC
pin and this output must be tied to the TFSYNC input. On power-up after the RSYSCLK and TSYSCLK
signals have locked to the RCLK signal, the elastic store reset bit (CCR3.6) should be toggled from a 0 to
a 1 to insure proper operation.
11.0 RECEIVE MARK REGISTERS
The DS21Q41B has the ability to replace the incoming data, on a channel-by-channel basis with either an
idle code (7F Hex) or the digital milliwatt code which is a 8-byte repeating pattern that represents a 1 kHz
sine wave (1E/0B/0B/1E/9E/8B/8B/9E). The RCR2.7 bit will determine which code is used. Each bit in
the RMRs, represents a particular channel. If a bit is set to a one, then the receive data in that channel will
be replaced with one of the two codes. If a bit is set to 0, no replacement occurs.
RMR1/RMR2/RMR3: RECEIVE MARK REGISTERS (Address=2D to 2F Hex)
(MSB)
CH8
CH7
CH6
CH5
CH4
CH3
CH2
(LSB)
CH1
RMR1 (2D)
CH16
CH15
CH14
CH13
CH12
CH11
CH10
CH9
RMR2 (2E)
CH24
CH23
CH22
CH21
CH20
CH19
CH18
CH17
RMR3 (2F)
SYMBOL
POSITION
NAME AND DESCRIPTION
CH24
RCBR3.7
Receive Channel Blocking Registers.
0=do not affect the receive data associated with this channel
CH1
RCBR1.0
1=replace the receive data associated with this channel with either
the idle code or the digital milliwatt code (depends on the
(RCR2.7 bit)
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DS21Q41B
12.0 TIMING DIAGRAMS
RECEIVE SIDE D4 TIMING Figure 12-1
NOTES:
1. RSYNC in the frame mode (RCR2.4=0) and double-wide frame sync is not enabled (RCR2.5=0).
2. RSYNC in the frame mode (RCR2.4=0) and double-wide frame sync is enabled (RCR2.5=1).
3. RSYNC in the multiframe mode (RCR2.4=1).
4. RLINK data (S-bit) is updated one bit prior to even frames and held for two frames.
5. RLINK and RLCLK are not synchronous with RSYNC when the receive side elastic store is enabled.
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DS21Q41B
RECEIVE SIDE ESF TIMING Figure 12-2
NOTES:
1. RSYNC in the frame mode (RCR2.4=0) and double-wide frame sync is not enabled (RCR2.5=0).
2. RSYNC in the frame mode (RCR2.4=0) and double-wide frame sync is enabled (RCR2.5=1).
3. RSYNC in the multiframe mode (RCR2.4=1).
4. ZBTSI mode disabled (RCR2.6=0).
5. RLINK data (FDL bits) is updated 1 bit-time before odd frames and held for two frames.
6. ZBTSI mode is enabled (RCR2.6=1).
7. RLINK data (Z-bits) is updated 1 bit-time before odd frame and held for four frames.
8. RLINK and RLCLK are not synchronous with RSYNC when the receive side elastic store is enabled.
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DS21Q41B
RECEIVE SIDE BOUNDARY TIMING
(WITH ELASTIC STORE DISABLED) Figure 12-3
NOTES:
1. There is a 13 RCLK delay from RPOS/RNEG to RSER.
2. RCHBLK is programmed to block channel 24.
3. Boundary timing shown is for the ESF framing mode.
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DS21Q41B
RECEIVE SIDE 1.544 MHz BOUNDARY TIMING
(WITH ELASTIC STORE ENABLED) Figure 12-4
NOTES:
1. RSYNC is in the output mode (RCR2.3=0).
2. RSYNC is in the input mode (RCR2.3=1).
3. RCHBLK is programmed to block channel 24.
44 of 61
DS21Q41B
RECEIVE SIDE 2.048 MHz BOUNDARY TIMING
(WITH ELASTIC STORE ENABLED) Figure 12-5
NOTES:
1. RSER data in channels 1, 5, 9, 13, 17, 21, 25, and 29 are forced to 1.
2. RSYNC is in the output mode (RCR2.3=0).
3. RSYNC is in the input mode (RCR2.3=1).
4. RCHBLK is forced to 1 in the same channels as RSER (see Note 1).
TRANSMIT SIDE D4 TIMING Figure 12-6
NOTES:
1. TSYNC in the frame mode (TCR2.3=0) and double-wide frame sync is not enabled (TCR2.4=0).
2. TSYNC in the frame mode (TCR2.3=0) and double-wide frame sync is enabled (TCR2.4=1).
3. TSYNC in the multiframe mode (TCR2.3=1).
4. TLINK data (S-bit) is sampled during the F-bit position of even frames for insertion into the outgoing
T1 stream when enabled via TCR1.2.
5. TLINK and TLCLK are not synchronous with TFSYNC.
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DS21Q41B
TRANSMIT SIDE ESF TIMING Figure 12-7
NOTES:
1. TSYNC in the frame mode (TCR2.3=0) and double-wide frame sync is not enabled (TCR2.4=0).
2. TSYNC in the frame mode (TCR2.3=0) and double-wide frame sync is enabled (TCR2.4=1).
3. TSYNC in the multiframe mode (TCR2.4=1).
4. ZBTSI mode disabled (TCR2.5=0).
5. TLINK data (FDL bits) is sampled during the F-bit time of odd frame and inserted into the outgoing
T1 stream if enabled via TCR1.2.
6. ZBTSI mode is enabled (TCR2.5=1).
7. TLINK data (Z-bits) is sampled during the F-bit time of frame 1, 5, 9, 13, 17, and 21 and inserted into
the outgoing stream if enabled via TCR1.2.
8. TLINK and TLCLK are not synchronous with TFSYNC.
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DS21Q41B
TRANSMIT SIDE BOUNDARY TIMING
(WITH ELASTIC STORE DISABLED) Figure 12-8
NOTES:
1. There is a 10 TCLK delay from TSER to TPOS/TNEG.
2. TSYNC is in the output mode (TCR2.0=1).
3. TSYNC is in the input mode (TCR2.0=0).
4. TCHBLK is programmed to block channel 2.
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DS21Q41B
TRANSMIT SIDE 1.544 MHz BOUNDARY TIMING
(WITH ELASTIC STORE ENABLED) Figure 12-9
NOTE:
1. TCHBLK is programmed to block channel 24.
TRANSMIT SIDE 2.048 MHz BOUNDARY TIMING
(WITH ELASTIC STORE ENABLED) Figure 12-10
NOTES:
1. TSER data in channels 1, 5, 9, 13, 17, 21, 25, and 29 is ignored.
2. TCHBLK is forced to 1 in the same channels as TSER (see Note 1).
48 of 61
DS21Q41B
DS21Q41B TRANSMIT DATA FLOW Figure 12-11
49 of 61
DS21Q41B
13.0 AC AND DC CHARACTERISTICS
ABSOLUTE MAXIMUM RATINGS*
Voltage on Any Pin Relative to Ground
Operating Temperature
Operating Temperature
Storage Temperature
Soldering Temperature
*
-1.0V to +7.0V
0°C to 70°C for DS21Q41BT
-40°C to +85°C for DS21Q41BTN
-55°C to +125°C
260°C for 10 seconds
This is a stress rating only and functional operation of the device at these or any other conditions
above those indicated in the operation sections of this specification is not implied. Exposure to
absolute maximum rating conditions for extended periods of time may affect reliability.
RECOMMENDED DC
OPERATION CONDITIONS
PARAMETER
(0°C to 70°C for DS21Q41BT;
-40°C to +85°C for DS21Q41BTN)
SYMBOL
MIN
Logic 1
VIH
Logic 0
Supply
TYP
MAX
UNITS
2.0
VDD+0.3
V
VIL
-0.3
+0.8
V
VDD
4.50
5.50
V
CAPACITANCE
PARAMETER
Input Capacitance
Output Capacitance
DC
CHARACTERISTICS
PARAMETER
NOTES
1
(tA=25°C)
SYMBOL
CIN
MIN
COUT
TYP
5
MAX
7
UNITS
pF
NOTES
pF
(0°C to 70°C; VDD=5V ± 10% for DS21Q41BT;
-40°C to +85°C; VDD=5V ± 10% for DS21Q41BTN)
SYMBOL
MIN
TYP
MAX
UNITS
NOTES
mA
1
+1.0
µA
2
1.0
µA
3
Supply Current @ 5V
IDD
30
Input Leakage
IIL
Output Leakage
ILO
Output Current (2.4V)
IOH
-1.0
mA
Output Current (0.4V)
IOL
+4.0
mA
-1.0
NOTES:
1. TCLK = RCLK = TSYSCLK = RSYSCLK = 1.544 MHz ; outputs open circuited.
2. 0.0V < VIN < VDD.
3. Applies to INT when 3-stated.
50 of 61
DS21Q41B
AC CHARACTERISTICS MULTIPLEXED PARALLEL
PORT (MUX=1)
PARAMETER
(0°C to 70°C; VDD=5V ± 10% for DS21Q41BT;
-40°C to +85°C; VDD=5V ± 10% for DS21Q41BTN)
SYMBOL
MIN
tCYC
200
ns
Pulse Width, DS Low or RD High
PWEL
100
ns
Pulse Width, DS High or RD Low
PWEH
100
ns
Input Rise/Fall Times
t R , tF
R/ W Hold Time
tRWH
10
ns
R/ W Setup Time Before DS High
tRWS
50
ns
CS , FS0, FS1 Setup Time before DS,
WR or RD Active
tCS
20
ns
CS ,
tCH
0
ns
Read Data Hold Time
tDHR
10
Write Data Hold Time
tDHW
0
ns
Muxed Address Valid to AS or ALE
Fall
tASL
15
ns
Muxed Address Hold Time
tAHL
10
ns
Delay Time DS, WR or RD to AS or
ALE Rise
tASD
20
ns
PWASH
30
ns
tASED
10
ns
tDDR
20
tDSW
50
Cycle Time
FS0, FS1 Hold Time
Pulse Width AS or ALE High
Delay Time, AS or ALE to DS, WR or
TYP
MAX
20
50
UNITS
ns
ns
RD
Output Data Delay Time from DS or
80
ns
RD
Data Setup Time
See Figures 13-1 to 13-3 for details.
51 of 61
ns
NOTES
DS21Q41B
INTEL BUS READ AC TIMING (BTS=0/MUX=1) Figure 13-1
INTEL BUS WRITE AC TIMING (BTS=0/MUX=1) Figure 13-2
MOTOROLA BUS AC TIMING (BTS=1/MUX=1) Figure 13-3
52 of 61
DS21Q41B
AC CHARACTERISTICS RECEIVE SIDE
(0°C to 70°C; VDD=5V ± 10% for DS21Q41BT;
-40°C to +85°C; VDD=5V ± 10% for DS21Q41BTN)
PARAMETER
SYMBOL
MIN
TYP
MAX
648
UNITS
RCLK Period
tCP
RCLK Pulse Width
tCH
tCL
RSYSCLK Period
tSP
tSP
RSYSCLK Pulse Width
tSH
tSL
50
50
ns
RSYNC Set Up to RSYSCLK Falling or
RPOS/RNEG Set Up to RCLK Falling
tSU
20
ns
RSYNC Pulse Width
tPW
50
ns
RPOS/RNEG Hold from RCLK Falling
tHD
20
ns
ns
75
75
ns
ns
648
488
ns
ns
RCLK and RSYSCLK Rise and Fall
Times
t R , tF
25
ns
Delay RCLK or RSYSCLK to RSER
Valid
tDD
75
ns
Delay RCLK or RSYSCLK to
RCHCLK
tD1
75
ns
Delay RCLK or RSYSCLK to
RCHBLK
tD2
75
ns
Delay RCLK to RFSYNC or RSYNC or
Delay RSYSCLK to RMSYNC or
RSYNC
tD3
75
ns
Delay RCLK to RLCLK
tD4
75
ns
Delay RCLK to RLINK Valid
tD5
75
ns
See Figures 13-4 to 13-6 for details.
NOTES:
1. RSYSCLK=1.544 MHz.
2. RSYSCLK=2.048 MHz.
3. RSYNC in input mode.
53 of 61
NOTES
1
2
3
DS21Q41B
RECEIVE SIDE AC TIMING Figure 13-4
NOTE:
1. RSYNC is in the output mode (RCR2.3=0).
54 of 61
DS21Q41B
RECEIVE SYSTEM SIDE AC TIMING Figure 13-5
NOTES:
1. RSYNC is in the output mode (RCR 2.3 = 0).
2. RSYNC is in the input mode (RCR 2.3 = 1).
RECEIVE LINE INTERFACE AC TIMING Figure 13-6
55 of 61
DS21Q41B
TRANSMIT LINE INTERFACE SIDE AC TIMING Figure 13-7
AC CHARACTERISTICS TRANSMIT SIDE
(0°C to 70°C; VDD=5V ± 10% for DS21Q41BT;
-40°C to +85°C; VDD=5V ± 10% for DS21Q41BTN)
PARAMETER
SYMBOL
MIN
TYP
MAX
TCLK Period
tCP
TCLK Pulse Width
tCH
tCL
TSYSCLK Period
tSP
tSP
TSYSCLK Pulse Width
tSH
tSL
50
50
ns
ns
TSER, TSYNC and TLINK Set Up to
TCLK Falling or TSER, TFSYNC Set
Up to TSYSCLK Falling
tSU
20
ns
TSYNC, TFSYNC Pulse Width
tPW
50
ns
TSER, TSYNC and TLINK Hold from
TCLK Falling or TSER
tHD
20
ns
TCLK or TSYSCLK Rise and Fall Times
648
UNITS
ns
75
75
ns
ns
648
488
ns
ns
t R , tF
25
ns
Delay TCLK to TPOS/TNEG Valid
tDD
75
ns
Delay TCLK to TCHCLK or TSYSCLK
to TCHCLK
tD1
75
ns
Delay TCLK to TCHBLK or TSYSCLK
to TCHBLK
tD2
75
ns
Delay TCLK to TSYNC
tD3
75
ns
Delay TCLK to TLCLK
tD4
75
ns
See Figures 13-7 to 13-9 for details.
NOTES:
1. TSYSCLK = 1.544 MHz.
2. TSYSCLK = 2.048 MHz.
3. TSYNC in input mode.
56 of 61
NOTES
1
2
3
DS21Q41B
TRANSMIT SIDE AC TIMING Figure 13-8
NOTES:
1. TSYNC is in the output mode (TCR2.2=1).
2. TSYNC is in the input mode (TCR2.2=0).
3. TSER is sampled on the falling edge of TCLK when the transmit side elastic store is disabled.
4. TCHCLK and TCHBLK are synchronous with TCLK when the transmit side elastic store is disabled.
57 of 61
DS21Q41B
TRANSMIT SYSTEM SIDE AC TIMING Figure 13-9
NOTES:
1. TSER is only sampled on the falling edge of TSYSCLK when the transmit side elastic store is
enabled.
2. TCHCLK and TCHBLK are synchronous with TSYSCLK when the transmit side elastic store is
enabled.
3. MSB of channel 1 when TSYSCLK is in 2.048 mode.
58 of 61
DS21Q41B
AC CHARACTERISTICS NON-MULTIPLEXED PARALLEL (0°C to 70°C; VDD=5V ± 10% for DS21Q41BT;
PORT (MUX=0)
-40°C to +85°C; VDD=5V ± 10% for DS21Q41BTN)
PARAMETER
SYMBOL
MIN
TYP
MAX
Set Up Time for A0 to A6, FS0, FS1
Valid to CS Active
t1
0
ns
Set Up Time for CS Active to either
RD, WR, or DS Active
t2
0
ns
Delay Time from either RD or DS
Active to Data Valid
t3
Hold Time from either RD, WR, or DS
Inactive to CS Inactive
t4
0
Hold Time from CS Inactive to Data
Bus 3-State
t5
5
Wait Time from either WR or DS
Active to Latch Data
t6
75
ns
Data Set Up Time to either WR or DS
Inactive
t7
10
ns
Data Hold Time from either WR or DS
Inactive
t8
10
ns
Address Hold Time
t9
40
ns
75
ns
ns
20
See Figures 13-10 to 13-13 for details.
INTEL BUS READ AC TIMING (BTS=0/MUX=0) Figure 13-10
59 of 61
UNITS
ns
NOTES
DS21Q41B
INTEL BUS WRITE AC TIMING (BTS=0/MUX=0) Figure 13-11
MOTOROLA BUS READ AC TIMING (BTS=1/MUX=0) Figure 13-12
MOTOROLA BUS WRITE AC TIMING (BTS=1/MUX=0) Figure 13-13
60 of 61
DS21Q41B
DS21Q41B 128-PIN TQFP
PKG
DIM
128-PIN
MIN
MAX
A
-
1.60
A1
0.05
-
A2
1.35
1.45
B
0.17
0.27
C
0.09
0.20
D
21.80
22.20
D1
E
E1
e
L
20.00 BSC
15.80
16.20
14.00 BSC
0.50 BSC
0.45
0.75
56-G4011-000
61 of 61