INFINEON PEB2084H

ICs for Communications
Quadruple Transceiver for S/T Interface
QUAT-S
PEB 2084 Version 1.2
Data Sheet 07.95
T2084-V12-D1-7600
Ausgabe 07.95
Herausgegeben von Siemens AG,
Bereich Halbleiter, MarketingKommunikation, Balanstraße 73,
81541 München
© Siemens AG 1995.
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PEB 2084
Revision History:
Current Version: Data Sheet 07.95
Previous Releases:
Preliminary Technical Manual 2.94
Page
(in previous
Version)
Page
(in current
Version)
Subjects (major changes since last revision)
11
10
Figure 1, IDO = Output and Input
9
12
Pin 40, IDO, resistor definition
20
22
Boundary scan, sequence of test pins (new)
29
33
Push-pull sensing
43
44
State diagram (DI → F3)
55
60
Maximum voltage on any pin
56
63
Power supply current
PEB 2084
Table of Contents
Page
1
1.1
1.2
1.3
1.4
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
Logic Symbol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9
Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10
Pin Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11
2
2.1
2.2
2.2.1
2.2.2
2.2.3
2.3
2.3.1
2.3.2
2.3.3
2.3.4
2.3.5
2.3.5.1
2.3.5.2
Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
Device Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
S/T Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
IOM®-2 System Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
JTAG Boundary Scan Test Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
Individual Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
Transceiver, Analog Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
Timing Recovery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .26
Receive Signal Oversampling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
Activation / Deactivation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .29
S/T Interface Frame Structures Synchronization . . . . . . . . . . . . . . . . . . . . . .29
Multi-Frame Generation with a short FSC . . . . . . . . . . . . . . . . . . . . . . . . . . .30
Super-Frame (M-bit) Generation using SSYNC (for DECT) . . . . . . . . . . . . .31
3
3.1
3.2
3.3
3.3.1
3.3.2
3.3.3
3.3.4
3.4
3.4.1
3.4.2
3.4.3
3.5
3.6
3.7
Operational Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
Push – Pull Sensing on Pin IDO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
IOM®-2 Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
ISDN Channels Allocation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
Monitor Channel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .33
D-Channel Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36
Command/Indicate Channel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40
Activation and Deactivation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40
LT-S Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41
LT-T Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .45
Example of Activation/Deactivation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .50
Diagnostic Functions, Test Loop-backs . . . . . . . . . . . . . . . . . . . . . . . . . . . . .51
S and Q Channel Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .52
Default-Use of Pin CEB/SSYNC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .53
4
4.1
4.2
4.3
4.4
4.5
Registers Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .54
Identification Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .54
Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .55
Loopback Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .56
Auxiliary Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .57
Other Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .58
Semiconductor Group
4
PEB 2084
Table of Contents
Page
5
5.1
5.2
5.3
5.4
5.5
5.6
5.7
5.8
5.9
Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .59
Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .59
DC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .61
Capacitances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .62
Recommended Oscillator Circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .63
AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .63
Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .64
IOM®-2 Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .65
Timing of Boundary Scan Test Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . .68
Transceiver Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .69
6
Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .71
7
Appendix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .72
IOM®, IOM®-1, IOM®-2, SICOFI®, SICOFI®-2, SICOFI®-4, SICOFI®-4µC, SLICOFI®, ARCOFI® , ARCOFI®-BA,
ARCOFI®-SP, EPIC®-1, EPIC®-S, ELIC®, IPAT®-2, ITAC®, ISAC®-S, ISAC®-S TE, ISAC®-P, ISAC®-P TE, IDEC®,
SICAT®, OCTAT®-P, QUAT®-S are registered trademarks of Siemens AG.
MUSAC™-A, FALC™54, IWE™, SARE™, UTPT™, ASM™, ASP™ are trademarks of Siemens AG.
Purchase of Siemens I2C components conveys a license under the Philips’ I2C patent to use the components in
the I2C-system provided the system conforms to the I2C specifications defined by Philips. Copyright Philips 1983.
Semiconductor Group
5
General Information
1
Overview
The PEB 2084, Quadruple Transceiver for S/T Interfaces (QUAT-S), implements fourwire S/T interfaces used to link voice/data digital terminals to PBX subscriber lines and
PBX trunk lines to the public ISDN. The QUAT-S is an optimized device for PBX
applications but can also be used in Hubs and Multiplexers. It can handle up to four
S/T interfaces simultaneously. While each channel is independently useable as S or
T interface.
The PEB 2084, QUAT-S, provides electrical and functional link between the analog
S/T interface and the ISDN-Oriented Modular (IOM-2) interface. It handles the
S/T interfaces fully according to CCITT I.430, ETSI 300.012, and ANSI T1.605
standards.
The PEB 2084, QUAT-S, is a CMOS device offered in a P-MQFP-44 package. It
operates from a single 5 V power supply.
Other Siemens’ integrated circuits for PBX applications are:
PEB 20550 Extended Line Card Interface Controller (ELIC)
PEB 2465
Signal-processing Codec Filter with 4 Channels (SICOFI-4)
PEB 2096
Octal Transceiver for UPN Interfaces (OCTAT-P)
PEB 2075
ISDN D-Channel Controller (IDEC)
Semiconductor Group
6
General Information
R
IOM -2
2048 kbit/s
TE 0
8xS
S0
TE 7
QUAT-S
PEB 2084
PCM
0
PCM
R
ELIC
PEB 20550
TE 0
8 x U PN
CFI
0
R
U PN
TE 7
OCTAT -P
PEB 2096
1
D Arbiter
TE 1
16 x t/r
r/t
TE 16
2
SLIC
SLIC
R
SICOFI -4
PEB 2465
SACCO-A
3
Signaling
SACCO-B
TSS
8xT
0
CO
7
R
Memory
IOM -2
QUAT-S
PEB 2084
µP Interface
R
µP
IOM -2
4 x D Cannel
R
IDEC
PEB 2075
ITB05392
Example for an Integrated Analog / Digital PBX Application
Semiconductor Group
7
Quadruple Transceiver for S/T Interface
(QUAT-S)
PEB 2084
CMOS
1.1
Features
• Four full duplex (B1 + B2 + D) S/T interface
transceivers, each equipped with the following
functions:
– Analog S/T interfaces fully according to the
CCITT I.430, ETSI 300.012 and ANSI T1.605
standards.
– 192 kbit/s transmission rate
– Receive timing recovery
•
•
•
•
•
•
P-MQFP-44-2
– Conversion between pseudo-ternary
and binary codes
– Conversion between S/T and IOM-2 frame structures
– Activation / deactivation procedures, triggered by primitives received over the
IOM-2 interface or by info received from the line (e.g. detection of INFO1)
– Access to S and Q bits of S/T interface
– Execution of test loops
– Loop length up to 1.5 km (point-to-point)
– Frame alignment in trunk applications with maximum wander of ± 50 µs
– Logical S/T interface functions identical to PEB 2081, SBCX, for line card
applications.
– Analog S/T line transceivers identical to PEB 2081, SBCX.
IOM-2 interface
D-channel access control
Support for JTAG boundary scan test
1µ CMOS technology with low power consumption
+ 5 V power supply
P-MQFP-44 package
Type
Ordering Code
Package
PEB 2084 H
Q6701-H6481
P-MQFP-44-2 (SMD)
Semiconductor Group
8
07.95
PEB 2084
1.2
Logic Symbol
Figure 1
QUAT-S Logic Symbol
Semiconductor Group
9
PEB 2084
1.3
Pin Configuration
(top view)
P-MQFP-44-2
Semiconductor Group
10
PEB 2084
1.4
Pin Description
Pin No. Symbol
Input (I)
Function
Output (O)
29, 30
32, 33
27, 26
24, 23
5, 4
2, 1
7, 8
10, 11
I
O
I
O
I
O
I
O
SR0a,b
SX0a,b
SR1a,b
SX1a,b
SR2a,b
SX2a,b
SR3a,b
SX3a,b
43
42
41
FSC
DCL
IDI
I
I
I
40
IDO
O/I
39
ICS
I
S/T Interface a: positive, b: negative
No. 0: differential input
No. 0: differential output
No. 1: differential input
No. 1: differential output
No. 2: differential input
No. 2: differential output
No. 3: differential input
No. 3: differential output
IOM®-2 Interface
Frame Synchronization Clock (8 kHz)
Data Clock
IOM Interface Data Input: Data Downstream in LT-S
Data Upstream in LT-T
IOM Interface Data Output: Data Upstream in LT-S
Data Downstream in LT-T
Output
open-drain: resistor to VDD
push-pull: resistor to VSS
resistor = 100 kΩ to 1 MΩ
refer to push-pull sensing, chapter 3.2
IOM Interface Channel Select (pin-strapping)
0: channels 0 though 3 selected
1: channels 4 through 7 selected
16
15
14
13
TMS
TCK
TDI
TDO
I
I
I
O
JTAG Boundary Scan Test Interface
Test Mode Select
Test Clock 6.25 MHz
Test Data Input
Test Data Output
20
21
XTAL1
XTAL2
I
O
Oscillator or 7.68 MHz clock input
Oscillator output
Semiconductor Group
11
PEB 2084
1.4
Pin Description (cont’d)
Pin No. Symbol
Input (I)
Function
Output (O)
36
O/I
CLK1/
IDS
CLK1:
IDS:
Clock output 1.536 MHz synchronized to
the trunk line (after reset in high impedance
state, only activated by programming
configuration register)
IOM-Interface Data Rate Select during HW
reset (pin-strapping)
0: double DCL (normal IOM-2 interface)
1: single DCL
The value of the input is sampled by the
falling edge of RST. Afterwards the pin may
be used for CLK1 functions.
35
CLK2
O
7.68 MHz clock output
38
RST
I
Reset, active high
17
CEB /
SSYNC
I/O /
I
CEB:
18
DRDY
O
D-channel Ready signal to control HDLC hardware in
LT-T mode
(open-drain or push-pull operation identical to pin
IDO)
I
+ 5 V power supply
I
Reference ground
VDD
6, 12,
22, 28,
34, 44
3, 9, 19, VSS
25, 31,
37
Semiconductor Group
Common echo bit for collision resolution in
logical subscriber LT-S bus configurations
(open drain output, external pull-up resistor
required.)
SSYNC: Superframe synchronization input
12
PEB 2084
2
Functional Description
The PEB 2084, QUAT-S, performs the layer-1 functions of the ISDN basic access for
four S/T interfaces.
2.1
Device Architecture
The QUAT-S contains the following functional blocks: Refer to figure 2
•
•
•
•
•
Four line transceivers with analog S/T interfaces
One digital IOM-2 interface
Frame structure converter between the IOM-2 interface and the S/T interfaces
JTAG boundary scan test interface
Clocking, reset and initialization block
Figure 2
QUAT-S Device Architecture
Semiconductor Group
13
PEB 2084
2.2
Interfaces
PEB 2084, QUAT-S, provides four independent S/T interfaces, one IOM-2 interface and
one JTAG boundary scan test interface.
2.2.1
S/T Interface
Frame Structure
One frame consists of 48 bits, at a nominal bit rate of 192 kbit/s. Thus each frame carries
two octets of B1, two octets of B2 and 4 bits of D-channel, according to the B1+B2+D
structure defined for the ISDN basic access (the total user data rate is 144 kbit/s). The
beginning of the frame is marked with a F-bit using a code violation (no Mark inversion).
The frame structures for data downstream (from network to subscriber) and for data
upstream (from subscriber to network) are shown in figure 3.
48 Bits in 250 µs
DL. F L.
NT
B1
E D A FA N
B2
E DM
B1
EDS
B2
E D L. F L.
0
TE 1
0
2 Bits Offset
D L. F L.
TE
NT
0
1
0
B1
L. D L. FA L.
B2
L. D L.
B1
L. D L.
B2
L. D L. F L.
t
F = Framing Bit
L = DC Balancing Bit
D = D-Channel Bit
E = D-Echo-Channel Bit
FA = Auxiliary Framing Bit or Q-Bit
N = Bit set to a Binary Value N = FA
B1 = Bit within B Channel 1
B2 = Bit within B Channel 2
A = Bit used for Activation
S = Subchannel SC1 through SC5 bit position
M = Multiframing Bit
ITD02330
Figure 3
Frame Structure at Reference Points S and T (CCITT I.430)
The E-bit (= Echo bit to the D-channel bit) can be controlled via C/I channel and may be
used to carry the “available” / “blocked” information sent by ELIC, PEB 20550. Refer to
chapter 3.3.3.
Semiconductor Group
14
PEB 2084
Coding
The QUAT-S uses a pseudo-ternary coding technique on the S/T interface (with a 100%
pulse width) according to CCITT I.430 recommendation. A binary ‘1’ corresponds to a
neutral level (space = no current) on the S/T line, binary ‘0’s are coded as alternating
positive and negative pulses (= marks), figure 4.
Code violation (CV) is caused by two successive pulses with the same polarity (= no
mark inversion).
Figure 4
S/T Interface Line Code
For details refer to Technical Manual PEB 2081, SBCX.
Semiconductor Group
15
PEB 2084
Interface Configurations
The QUAT-S provides four S/T interfaces for different applications, see figure 5:
• Subscriber’s connection to PBX (LT-S Mode) for different line configurations:
– Point-to-point
– Short passive bus
– Extended passive bus
• PBX connection to CO trunk (LT-T Mode)
Figure 5
S/T Interface Configurations
The T interface is physically identical to the S interface.
Semiconductor Group
16
PEB 2084
2.2.2
IOM®-2 System Interface
The PEB 2084, QUAT-S, is equipped with a digital ISDN Oriented Modular (IOM-2)
interface, for interconnection with other telecommunication ICs, such as IDEC
(PEB 2075), EPIC (PEB 2055) and ELIC (PEB 20550). EPIC and ELIC represent the
first switching stage towards the exchange system.
Figure 6
System Integration, IOM®-2 Interface
Interface Signals
The IOM-2 interface is a four-wire serial interface which comprises two data lines and
two clock lines for synchronization. Refer to figure 6.
Data is carried over Data Upstream (DU) and Data Downstream (DD) lines. The
downstream and upstream directions are always seen with respect to the exchange.
Downstream refers to the information flow from the central exchange via PBX to the
subscriber and upstream vice versa.
Semiconductor Group
17
PEB 2084
Thus, depending on the programmable QUAT-S mode, the data lines IDI and
different meanings: IDI (IOM interface Data Input)
= Data Downstream
= Data Upstream
IDO (IOM-2 interface Data Output) = Data Upstream
= Data Downstream
IDO get
in LT-S
in LT-T
in LT-S
in LT-T
The data is clocked by Data Clock (DCL) that operates at single or double data rate. The
selection is done by pinstrapping (CLK1/IDS). The IOM frames are delimited by an 8 kHz
Frame Synchronization Clock (FSC). The FSC rising edge indicates the start of an
IOM-2 frame.
The IOM-2 interface specification describes open drain data lines with external pull-up
resistors. However, if operation is logically point-to-point, tristate operation is possible as
well.
Frame Structure
One IOM-2 frame typically contains 8 IOM channels (sub-frames). The ISDN user data
rate is 144 kbit/s (B1 + B2 + D). The data is transmitted transparently synchronously and
in phase in both directions over the IOM-2 interface using time division multiplexing
within the 125 µs IOM-2 interface frame.
Refer to figure 7.
QUAT-S requires IOM-2 frame consisting of n complete ISDN channels (with 32 bits per
channel); n = 4, 5, 6, … 16.
Nominal bit rate of data (IDI and IDO)
Nominal frequency of DCL
Selectable frequency of DCL
Nominal frequency of FSC
1024 kbit/s
2048 kHz
1024 kHz
8 kHz
Semiconductor Group
18
… 4096 kbit/s
… 8192 kHz
… 4096 kHz
PEB 2084
125 µ s
FSC
DCL
DU
IOM CH0
R
CH1
CH2
CH3
CH4
CH5
CH6
CH7
CH0
DD
IOM CH0
R
CH1
CH2
CH3
CH4
CH5
CH6
CH7
CH0
B1
B2
MONITOR
D
C/I
MM
R X
ITD04319
Figure 7
Multiplexed Frame Structure of the IOM-2 Interface in LT Mode with 2048 kbit/s
Data Rate
Each IOM ISDN channel consists of a total of 32 bits, or four octets:
B1 (8 bits) + B2 (8 bits) + D (2 bits) plus 14 bits for intercommunication.
• Two 8-bit B1 and B2 channels for voice and data communication with a data rate of
64 kbit/s each,
• One 8-bit monitor channel for transferring maintenance information,
• One 2-bit D-channel for data transfer (e.g. signalling) with a data rate of 16 kbit/s
• Four command/indication (C/I) bits for controlling layer-1 functions.
• Two bits for handling the monitor channel: MR an MX (hand shake control).
8 bits
8 bits
8 bits
2
B1 channel
B2 channel
Monitor channel
D ch.
4 bits
1
Command/ MR
Indication
1
MX
The user data rate is 144 kbit/s (B1 + B2 + D).
Monitor Channels
The monitor channel is used to convey message oriented local functions such as
software programming or access to internal registers via a layer-2 controller (ICC,
ELIC,…). There is a defined handshake procedure between the monitor channel
transmitter and the receiver in order to ensure a safe data transfer over the IOM-2
interface.
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PEB 2084
The monitor channel operates on an asynchronous basis. While data transfer on the bus
takes place synchronized to the frame, the data flow is controlled by a handshake
procedure using the monitor channel receive bit (MR) and the monitor channel transmit
bit (MX). For example: data is placed onto the monitor channel and the MX bit is
activated (active low). This data will be transmitted repeatedly once per 8 kHz frame until
the transfer is acknowledged via the MR bit.
The monitor channel is in an idle condition when the MX bit is inactive in two or more
consecutive frames (indication of End Of Message EOM).
The monitor channel is also used to convey S and Q maintenance bits information (S/Q
channel).
The PEB 2084, QUAT-S, handles four monitor channels allocated to its four S/T
interfaces. The implemented monitor protocol is according to the IOM Interface
Specification, Rev. 2. For more details and an example refer to chapter 3.3.2.
D-Channels
The D-channels are switched transparently between the S/T interfaces and the IOM-2
interface. Depending on the data load on a line card, different PBX architectures can be
implemented for D-channel handling in LT-S applications:
For decentral signalling, up to 32 subscribers can be served with only one special HDLC
controller which is integrated in the PEB 20550, ELIC (SACCO-A).
For intensive data packet handling in LT-S mode (e.g. in PC networks) or in LT-T
applications, additional HDLC controllers such as HSCX, IDEC, ESCC 2 or 8 or
MUNICH 32 may be connected to the IOM-2 interface. If a D-channel collision resolution
according to CCITT I.430 is required, the QUAT-S offers a strobe signal to control the
connected HDLC (LAPD) controller.
For operational description refer to chapter 3.3.3.
C/I-Channels
A C/I-channel is used for communication between the PEB 2084, QUAT-S, and a
processor via a layer-2 device, to control and monitor layer-1 functions
(activation/deactivation and additional control functions). The layer-2 device monitors
the layer-1 indication continuously and indicates a change if a new code is found to be
valid in two consecutive IOM frames (double last look criterion).
The codes originated by layer-2 devices are called “Commands”, those originated by the
PEB 2084, QUAT-S, are called “Indications”.
The PEB 2084, QUAT-S, handles four C/I-channels; one for each S/T transceiver.
For a list of the C/I codes and their use refer to chapter 3.6.
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PEB 2084
2.2.3
JTAG Boundary Scan Test Interface
The QUAT-S provides a boundary scan support for a cost effective board testing. It
consists of:
– Complete boundary scan for 11 signals (pins) according to IEEE Std. 1149.1
specification
– Test access port controller (TAP)
– Four dedicated pins (TCK, TMS, TDI, TDO)
– One 32-bit IDCODE register
– Specific functions for SXna,b
Boundary Scan
The following QUAT-S pins are included in the boundary scan:
FSC, DCL, IDI, IDO, RST, ICS, CEB, DRDY, CLK1, CLK2 and XTAL1.
Depending on the pin functionality one or two boundary scan cells are provided.
Pin Type
Number of Boundary Scan Cells
Usage
Input
1
Input
Output
2
Output, enable
When the TAP controller is in the appropriate mode data is shifted into/ out of the
boundary scan via the pins TDI/TDO using the 6.25 MHz clock on pin TCK.
The QUAT-S pins are included in the boundary scan in the following sequence:
Boundary Scan Number
TDI ––>
Pin Number
Pin Name
Type
Number of
Scan Cells
1
43
FSC
I
1
2
42
DCL
I
1
3
41
IDI
I
1
4
40
IDO
O
2+1
5
39
ICS
I
1
6
38
RST
I
1
7
36
CLK1/IDS
O/I
2+1
8
35
CLK2
O
2
9
20
XTAL1
I
1
10
18
DRDY
O
2
11
17
CEB/SSYNC
I/O
1+2
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PEB 2084
TAP Controller
The Test Access Port (TAP) controller implements the state machine defined in the
JTAG standard IEEE Std. 1149.1. Transitions on the pin TMS cause the TAP controller
to perform a state change.
Following the standard definition five instructions are executable.
TAP controller instructions:
Code
Instruction
Function
0000
EXTEST
External testing
0001
INTEST
Internal testing
0010
SAMPLE/PRELOAD
Snap-shot testing
0011
IDCODE
Reading ID code
0100
Test Mode TM1
Single pulses (2 kHz) on SXna,b
0101
Test Mode TM2
Continuous pulses (96 kHz) on SXna,b
11XX
BYPASS
Bypass operation
Note: The instructions TM1 and TM2 require 7.68 MHz at XTAL1.
EXTEST is used to examine the board interconnections.
When the TAP controller is in the state “update DR”, all output pins are updated with the
falling edge of TCK. When it has entered state “capture DR” the levels of all input pins
are latched with the rising edge of TCK. The in/out shifting of the scan vectors is typically
done using the instruction SAMPLE/PRELOAD.
INTEST supports internal chip testing.
When the TAP controller is in the state “update DR”, all inputs are updated internally with
the falling edge of TCK. When it has entered state “capture DR” the levels of all outputs
are latched with the rising edge of TCK. The in/out shifting of the scan vectors is typically
done using the instruction SAMPLE/PRELOAD.
0001 (INTEST) is the default value of the instruction register.
SAMPLE / PRELOAD provides a snap-shot of the pin level during normal operation or
is used to preload (TDI) / shift out (TDO) the boundary scan with a test vector. Both
activities are transparent to the system functionality.
Note: The input pin XTAL1 should not be evaluated.
The input frequency (7.68 MHz) is not synchronous to TCK (6.25 MHz) which may
cause not predictable snap-shots on the pin XTAL1.
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PEB 2084
IDCODE Register
The 32-bit identification register is serially read out via TDO. It contains the version
number (4 bits), the device code (16 bits) and the manufacture code (11 bits). The LSB
is fixed to “1”.
Version
Device Code
Manufacture Code
0001
0000 0000 0010 0000
0000 1000 001
Output
1
→ TDO
Note: In the state “test logic reset” the code “0011” is loaded into the instruction code
register.
Test Modes TM1 and TM2
Two different pulse types at the line interface SXna,b are selectable: 2 kHz single pulses
or 96 kHz continuous pulses, figure 8.
Figure 8
Test Pulse Wave Forms
BYPASS, a bit entering TDI is shifted to TDO after one TCK clock cycle, e.g. to skip
testing of selected ICs on a printed circuit board.
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PEB 2084
2.3
Individual Functions
2.3.1
Transceiver, Analog Connections
The receiver input stages consist of a differential amplifier, followed by a peak detector
and a set of comparators. Additional noise immunity is achieved by digital oversampling
after the comparators, meaning that the sampling of the received bit is controlled digitally
and dependent on the mode (CONFIGURATION Register).
The peak detector requires at most 2 µs to reach the peak value while storing the peak
level for at least 250 µs. The data detection thresholds are chosen to 35 % of the peak
voltage to increase the performance in extended passive bus configurations. However
they are never lower than 85 mV. The level detector monitors the line input signals to
detect whether an information is present. In LT-S analog loop-back mode the level
detector monitors its own loop signal and an incoming signal is not recognized.
Figure 9
Receiver Functional Blocks
The transmitter stage consists of two identical current limited voltage sources, one for
each polarity of output pulses, in order to achieve a ternary pulse shaping. A voltage of
2.1 V is delivered between SXna and SXnb, which yields a current of 7.5 mA over 280 Ω.
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PEB 2084
.
Figure 10
Transmitter Functional Block
External transformers of the ratio 2:1 are needed in receive and transmit directions to
provide for isolation and transform voltage levels according to CCITT recommendations
I.430. The QUAT-S also needs external circuitry for impedance matching, overvoltage
protection and electromagnetic compatibility (EMC) for its connection to the 4-wire S/T
interface.
Figure 11
QUAT-S External Circuitry
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PEB 2084
Note: The actual values of the external resistors depend on the selected transformer.
The resistor values are optimal for an ideal transformer (RCu = 0).
Line termination (RT) is applied to the last TE on the S bus only.
The transmitter of the QUAT-S is identical to that of SBCX, hence the line interface
circuitry should be the same. The external resistors (20 … 40 Ω) are required in order to
adjust the output voltage to the pulse mask (nominal 750 mV according to CCITT I.430)
on the one hand and in order to meet the output impedance of a minimum of 20 Ω
(transmission of a binary one according to CCITT I.430) on the other hand.
The QUAT-S has a symmetrical receiver.
Useful hints on how to design the external interface circuitry are contained in the
application note “S/T interface circuitry using the PEB 2080, SBC, or PEB 2085,
ISAC-S” from 12.89.
2.3.2
Timing Recovery
LT-S Mode (Configuration Register: Mode = 0)
In the LT-S mode the QUAT-S is the clock master to all connected TEs.
The transmit PLL (XPLL) synchronizes the 192 kHz transmit bit clock to the IOM-2 clock
FSC (8 kHz) derived from the oscillator clock. When the oscillator clock is synchronous
to FSC (fixed divider ratio of 960 from 7.68 MHz clock) the XPLL will not perform any
tracking after having locked the phase, i.e. the input jitter on clocks XTAL and FSC will
not be increased, see figure 12.
Figure 12
Block Diagram of XPLL
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PEB 2084
In the receive direction two cases have to be distinguished depending on the bus
configuration:
– Short passive bus configuration (Configuration Register: C/W = 1)
The 192 kHz receive bit clock is identical to the transmit bit clock. The sampling instant
for the receive bits is shifted by 4.6 µs with respect to the transmit bit clock. According to
CCITT I.430 the receive frame shall be shifted (delayed) by two bits with respect to the
transmit frame.
– Point-to-point or extended passive bus configurations
(Configuration Register: C/W = 0)
The 192 kHz receive bit clock is recovered (via PLL) from the receive data stream on the
S interface. According to CCITT I.430 the receive frame can be shifted by 2 to 8 bits with
respect to the transmit frame. However other shifts are allowed by the QUAT-S as well;
including 0.
LT-T Mode (Configuration Register: Mode = 1)
In LT-T applications the QUAT-S is a clock slave to the central office clock, which is
always the master. Thus a PBX clock system must be locked up with the CO clock
system.
The 192 kHz receive bit clock is recovered (via PLL) from the receive data stream on the
T interface.
2.3.3
Receive Signal Oversampling
The receive signal is sampled several times (oversampling) inside the receive clock
period, and a majority logic is used to reduce the bit error rate in severe conditions.
As illustrated in figure 13, each received bit is sampled 29 times at 7.68 MHz clock
intervals inside the estimated bit window. The samples obtained are compared against
a threshold of 50 % with respect to the signal stored by the peak detector. If at least 16
samples have an amplitude exceeding the set threshold, a logical “0” is considered to be
detected; otherwise a logical “1” (no signal) is considered to be detected.
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PEB 2084
VSR2 - VSR1
VTR1 or VTR2
0V
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
Derived 192-kHz Receive Bit Period
ITD02361
Figure 13
Receive Signal Oversampling on S and T Interfaces
The PLL also provides a synchronous 1.536 MHz clock (adaptive timing recovery),
which can be used to synchronize the PCM clocks of the PEB 20550, ELIC, by means of
a XTAL controlled PLL circuit. Refer to figure 14.
Figure 14
Clock System in LT-S and LT-T Modes
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PEB 2084
Since the ELIC generates the IOM-2 clocks (FSC, DCL) for all connected layer-1 and
layer-2 devices, the loop is closed. If several layer-1 devices are operated in LT-T mode,
only one device (one channel in a QUAT-S) may be selected (Configuration Register, bit
RCLK) to deliver the reference clock.
The receive PLL performs tracking every 250 µs after detecting a phase difference
between the F/L transition of the receive signal and the recovered clock. A phase
adjustment is done by adding or subtracting 65 ns to or from the 1.536 MHz clock cycle.
Elastic Buffer
The two interfaces (IOM-2 and S/T) of the QUAT-S require a buffer to compensate for
the differences in bit rate between the two interfaces as well as the different round trip
delays of various wiring configurations. The QUAT-S enables intermediate storage of
3 × B1, 3 × B2 and 6 D-bits for phase difference and wander absorption.
Moreover, the buffer is designed as a wander-tolerant system, required in LT-T modes
where the QUAT-S is a slave to both interfaces and the data clocks of the two interfaces
have a time dependent phase relationship. The elastic buffer of the QUAT-S
compensates for a maximum phase wander of 50 µs peak-to-peak and a slip detector
indicates when this limit is exceeded. Setting the C/W-bit in the Configuration Register
gives a warning when a slip of 25 µs is exceeded. An indication (Slip detected) is
released in the C/I channel. However the data may be lost.
The phase relationship between the IOM-2 interface and the S/T interface is arbitrary in
this case.
The transmit frame is shifted (delayed) by two bits with respect to the receive frame.
2.3.4
Activation / Deactivation
An incorporated finite state machine controls the activation and deactivation procedures
and communicates with the layer-2 unit via the IOM-2 C/I channel. Each of the four C/I
channels is allocated to its corresponding S/T line interface. Refer to chapter 3.6.
2.3.5
S/T Interface Frame Structures Synchronization
The QUAT-S supports two different kinds of frame structures:
a) A Multi-Frame consisting of 20 consecutive S/T frames.
b) A Super-Frame consisting of 2 × n (n = 1, 2, …) consecutive S/T frames.
Both frames provide an extra layer-1 capacity for information transmission in both
application modes: LT-T and LT-S (refer to chapter 3.6, access to S and Q channels).
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PEB 2084
2.3.5.1 Multi-Frame Generation with a short FSC
The QUAT-S synchronizes to a multi-frame structure according to CCITT
recommendation I.430.
In LT-S application mode the S interface multi-frame (20 × 250 µs = 5 ms period) can be
generated by a master device (e.g. ELIC) by inserting a short FSC pulse.
An external strobe on the pin CEB/SSYNC can be used for simple terminal
synchronization.
A short FSC pulse has a width of one DCL clock whereas a normal FSC pulse has a
width of at least two DCL clocks. The QUAT-S samples the FSC input with the second
falling edge of DCL clock in the very first bit positions of the frame. If the sampled bit is
zero the S/T interface transmit frame, including multi-frame, is reset.
The frame relationship between IOM-2 interface (FSC) and S/T interface is shown in the
following figures.
Figure 15
Multi-Frame Generation with a Short FSC
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PEB 2084
2.3.5.2 Super-Frame (M-bit) Generation using SSYNC (for DECT)
A zero pulse on the SSYNC input pin forces the QUAT-S to send M = 1 synchronously
on all four S/T interfaces. (Useful with MFD = 1 only.)
Figure 16
M-bit Generation Using SSYNC
In LT-T mode the QUAT-S synchronizes to the received FA-bit inversions and M-bits.
When the synchronization is not achieved or lost, it mirrors the received FA-bits.
Multi-frame synchronization is achieved after two complete multi-frames have been
detected with reference to FA/N-bit and M-bit positions. Multi-frame synchronization is
lost after two or more bit errors in F A/N-bit and M-bit positions have been detected in
consequence, i.e. without a complete valid multi-frame in between.
The multi-frame synchronization can be disabled by programming the Configuration
Register:
MFD = 1.
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PEB 2084
3
Operational Description
All procedures required for data transmission over the S/T interface are implemented.
These comprise the S/T interface frame and multiframe synchronization,
activation/deactivation procedure, and timing requirements such as bit rate and jitter. For
a correct functionality of the QUAT-S the following operational precautions must be
taken:
3.1
Reset
At power up, a reset pulse (RST) should be applied to bring the line interfaces of the
PEB 2084, QUAT-S, to the state “reset”. No clocks are required during that procedure.
After that the PEB 2084, QUAT-S, may be operated according to the state diagram,
each line interface controlled via the corresponding C/I channel.
3.2
Push – Pull Sensing on Pin IDO
The QUAT-S senses whether an external pull-up resistor (100 kΩ to 1 MΩ) is connected
to the pin IDO. The sensing is done after reset within the following two IOM frames in the
monitor channel.
The pin is pulled low for one bit and then switched to tristate. If the voltage level at IDP0
rises in the next bit to “High”, QUAT-S interprets this behaviour as an external pull up
being connected to the pin and remains as open collector. If the level stays at “Low”
QUAT-S switches to push-pull. However, actions of other device on this line or crosstalk
from other lines during the sensing procedure may falsify the result. (A pull down resistor
of 100 kΩ to 1 MΩ may improve the correctness of the sensing). This feature is useful if
multiple transmitters are connected to the same IOM-2 interface, e.g. QUAT-S with an
IDEC.
3.3
IOM®-2 Interface
3.3.1
ISDN Channels Allocation
The allocation between S/T line interfaces and the IOM-2 ISDN channels is according to
their numbers with an offset of four or zero. The offset can be selected via pin ICS by pin
strapping, i.e.
for ICS = 0 the SRX0a,b is allocated to IOM channel 0, and so on,
for ICS = 1 the SRX0a,b is allocated to IOM channel 4, and so on.
For detailed electrical definition refer to the chapter 5 and the IOM Interface
Specification, Rev. 2.
As described in chapter 2.2.2, each basic ISDN channel consists of five different
communication channels: two voice channels, one monitor channel (incl. MR and MX
bits), one D-channel and one command/indication (C/I) channel.
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PEB 2084
3.3.2
Monitor Channel
Before starting a data transmission to the QUAT-S, a microprocessor must verify that the
transmitter of the QUAT-S is inactive, i.e. that a previous transmission has been
terminated.
The QUAT-S has a monitor transmitter time out function of minimum 4 ms implemented.
This prevents the monitor message to be transmitted continuously if the monitor data
won’t be acknowledged by the receiver.
First the Identification Register of the QUAT-S may be read. Two bytes are transmitted
to the QUAT-S and as a result of the read operation two bytes are returned to the
controller. In case of a write operation the data is only acknowledged and no data is
returned from the QUAT-S to the controller.
The first byte of the data transmitted to the QUAT-S always indicates the type of the
desired monitor operation (i.e. read or write to the internal registers).
The example shows the typical register access of the ELIC and gives a feeling about the
important bits.
The ELIC uses a 16-Byte FIFO for transmission and reception of the monitor data.
Therefore the user doesn’t need to provide routines for the handshake protocol.
An example for a communication between a µP, an ELIC and the QUAT-S is shown in
figures 17 and 18.
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PEB 2084
Figure 17
Monitor Channel Handling: µP ↔ ELIC ↔ QUAT-S
A detailed description of the hand-shake procedure using MX and MR bits is shown in
figure 18.
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PEB 2084
Figure 18
Monitor Channel Handling: Hand-shake by the Use of MX and MR Bits (LT-S
Mode)
QUAT-S in LT-S Mode
Data Downstream:
Data Upstream:
MX-bit at ELIC → MR-bit at QUAT-S
MX-bit at QUAT-S → MR-bit at ELIC
QUAT-S in LT-T Mode
Data Downstream:
Data Upstream:
MX-bit at QUAT-S → MR-bit at ELIC
MX-bit at ELIC → MR-bit at QUAT-S
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PEB 2084
3.3.3
D-Channel Handling
Decentral D-channel handling in a PBX depends on QUAT-S application mode: LT-S or
LT-T.
LT-S Mode. Configuration Register, MODE = 0.
It is used in PBX applications with only one signalling controller (HDLC) used for up to 32
ISDN subscribers in order to minimize system costs. A terminal is allowed to send data
only if the signalling controller is ready to receive data. The D-channel access can be
controlled via a central D-channel arbiter unit integrated in the PEB 20550, ELIC, or
according to CCITT I.430 via an arbitration logic in the QUAT-S.
D-Channel Arbitration via ELIC. Auxiliary Register, DCM(1:0) = 11.
ELIC, PEB 20550, informs the QUAT-S whether the signalling controller (SACCO-A) is
ready to receive data. It sends commands (C/I) to individual QUAT-S channels:
C/I = 1100H (e.g. 1000H) indicates that the D-channel is “available” and can be used.
C/I = 1100H indicates that the D-channel currently can not be used (is “blocked”) as
the signalling controller is allocated to an other terminal.
The QUAT-S controls the connected terminal transmitters (e.g. ISAC-S, SBCX,
ISAC-S TE) via its S interfaces accordingly. It translates the information “available” or
“blocked” by setting the E-bit on the S interface.
E = D indicates to the terminal that its HDLC controller can send data.
E = D indicates that the HDLC controller may not send data or has to abort sending data.
Figure 19
QUAT-S in LT-S Mode with a D-Channel Access via ELIC D-Channel Arbiter
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PEB 2084
The codes (C/I = 1100H and 1100H) can only be used when the QUAT-S is in the state
G3 activated (during INFO 4 transmission). Refer to chapter 3.6.
For a detailed description of the D-Channel Arbiter refer to “ELIC, PEB 20550, Technical
Manual 9.93”, page 54, chapter 2.2.8.
D-Channel Access According to CCITT I.430 (Star Configuration)
The D-channel access is arbitrated among the terminals themselves,
if the QUAT-S Auxiliary Register is programmed to DCM(1:0) = 10.
Figure 20
QUAT-S in LT-S Mode Supporting Arbitration According to CCITT I.430
The D-channel access control is established as a logical passive bus structure. All
received D-channels are ANDed and the resulting value (internally connected to the pin
CEB) is sent back as Echo bit on all involved S/T interfaces.
If more QUAT-S work in parallel the CEB pins (open drain output) are wired via an
external pull-up resistor to VDD.
The “short passive bus”, a system of multiple TE’s accessing a single D-channel, is
extended to multiple physical S lines still representing a single logical “short passive
bus”. It is a system with multiple B-channels using a single D-channel.
Only the winning D-channel reaches the ELIC. The other D-channels remain blocked
until a TE encounters 8 (10) E-bits equal to the D-bit in a row.
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PEB 2084
The ELIC D-channel arbiter doesn’t work in this application as an arbiter (all channels
are permanently sent the C/I command “available” = 1000H), it only detects the winning
D-channel on the IOM interface and controls the connected LABD controller
(SACCO-A).
LT-T Mode Configuration Register, bit 0: MODE = 1
D-channel collision resolution is always controlled according to CCITT I.430.
Four-Channel LT-T Applications
The pin DRDY conveys control information synchronous to the D-channel timeslots to
control PEB 2075, IDEC, if the Auxiliary Register, bits DCM(1:0) = 10.
Stop when DRDY = “0”, Go when DRDY = “1”.
Figure 21
QUAT-S in LT-T Mode with IDEC for Four-Channel Applications
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PEB 2084
Single-Channel LT-T Applications
QUAT-S can also be used in a mixed mode, e.g. by programming three channels in LT-S
mode and one channel in LT-T mode. The Auxiliary Register of only one channel can be
programmed to DCM(1:0) = 11 and the Configuration Register pin RCLK to 1.
Whereas the subscriber D-channels are handled by the D-channel arbiter and SACCO-A
in ELIC (as described in chapter LT-S Mode), the trunk D-channel is handled by the
QUAT-S arbitration logic and SACCO-B in ELIC.
If the Echo bit differs from the D-bit then QUAT-S stops SACCO-B: DRDY = “1”, else
SACCO-B may send data: DRDY = “0”. Pin DRDY conveys control information
asynchronous to the D-channel timeslot.
This mode is applicable to single channel LT-T applications only.
Figure 22
QUAT-S with SACCO-B for Single-Channel LT-T Applications
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PEB 2084
Clock generation for the above application is shown in figure 14.
3.3.4
Command/Indicate Channel
The exchange of control information in the C/I channel is state oriented. This means that
a code in the C/I channel is repeated in every IOM frame until a next change is
necessary. A new code must be found in two consecutive IOM frames to be considered
as valid (double last look criterion).
C/I commands trigger QUAT-S layer-1 state machine in accordance with CCITT I.430.
For a list of the C/I codes and their use refer to chapter 3.6.
3.4
Activation and Deactivation
An internal finite state machine of the PEB 2084, QUAT-S, controls the
activation/deactivation procedures, switching of loops and transmission of special pulse
patterns. Such actions can be initiated by primitives (INFOS) on the S/T interface or by
control codes (C/I) sent over the IOM-2 interface.
The IOM-2 interface should be kept active in both application modes, LT-S and LT-T, for
the QUAT-S is always ready to transmit and receive messages.
Depending on the application mode and the transfer direction the QUAT-S state
machines support about 20 different codes in conditional and unconditional states:
LT-S mode
C/I codes
States:
LT-T mode
C/I codes
data downstream = Commands: reset, test mode,
activate req.,..
data upstream
= Indications: not sync., code violation,
timer out,..
deactivated, activated, pending, lost framing, test mode.
The state diagram is shown in figure 23.
for data upstream = Commands:
reset, test,
activate request,..
data downstream = Indications:
command x
acknowledged,..
Conditional states: power up, pending deactivation, synchronized,
slip detected,..
The state diagram is shown in figure 24.
Unconditional states can be entered from any conditional state and should
be left with the command TIM:
loop closed, test mode,
reset state,..
The state diagram is shown in figure 25.
The activation and deactivation procedures implemented in the PEB 2084, QUAT-S,
correspond with those implemented in the PEB 2081, SBCX.
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PEB 2084
3.4.1
LT-S Mode
Command / Indication Codes
Commands (downstream) Abbreviation Code Remark
LT-S mode
Deactivate request
DR
0000
(x)
Reset
RES
0001
(x)
Test mode 1
TM1
0010
Transmission of pseudo-ternary
pulses at 2 kHz frequency (x)
Test mode 2
TM2
0011
Transmission of pseudo-ternary
pulses at 96 kHz frequency (x)
Activate request
AR
1000
Activate indication
AI
1100
Transmission of transparent
INFO acc. to state diagram with
inverted D-channel mirrored back
in E-channel
Activate request loop
ARL
1010
Activation request for loop 2
Deactivate confirmation
DC
1111
Deactivation acknowledgment,
quiescent state
(x) unconditional commands
Indications (upstream)
LT-S mode
Abbreviation Code Remark
Timing
TIM
0000
Resynchronizing
RSY
0100
Receiver is not synchronous
Activate request
AR
1000
INFO 1 received
Code violation received
CVR
1011
After each multi-frame the receipt
of at least one illegal code
violation is indicated four times.
This function must be enabled by
setting the RCVE-bit in the
configuration register.
Activate indication
AI
1100
Synchronous receiver
Deactivate indication
DI
1111
Timer (32 ms) expired or INFO 0
received after deactivation
request
Semiconductor Group
41
PEB 2084
Figure 23
QUAT-S State Diagram of LT-S Mode
Note: 1) ARD stands for AR or ARL
2)
only if DCM (1:0) = 11
Semiconductor Group
42
PEB 2084
Figure 24
QUAT-S State Diagram in the LT-T Mode, Conditional States
Note: 1) × = TM1 and TM2 and RES and ARL
2)
Alp stand for AI8 or Al10
3)
ARp TMI stands for AR8 or AR10
4) TMI stands for TM1 or TM2
Semiconductor Group
43
PEB 2084
LT-S Mode States
• G1 deactivated
The line interface is not transmitting. There is no signal detected on the S interface,
and no activation command is received in the C/I channel.
• G2 pending activation
As a result of an INFO 1 detected on the S line or an ARD command, the line interface
begins transmitting INFO 2 and waits for reception of INFO 3. The timer to supervise
reception of INFO 3 is to be implemented in software. In case of an ARL command,
loop 2 is closed.
• G3 activated
Normal state where INFO 4 is transmitted to the S interface. The line interface
remains in this state as long as neither a deactivation nor a test mode is requested,
nor the receiver looses synchronism. When receiver synchronism is lost, INFO 2 is
sent automatically. After reception of INFO 3, the transmitter keeps on sending
INFO 4.
• G2 lost framing
This state is reached when the line interface has lost synchronism in the state G3
activated.
• G4 pending deactivation
This state is triggered by a deactivation request DR. It is an unstable state: indication
DI (state “G4 wait for DR.”) is issued by the QUAT-S when: either INFO 0 is received,
or an internal timer of 32 ms expires.
• G4 wait for DR
Final state after a deactivation request. The line interface remains in this state until a
response to DI (in other words DC) is issued.
• Test mode 1
Single alternating pulses are sent on the S interface (2 kHz repetition rate).
• Test mode 2
Continuous alternating pulses are sent on the S interface (96 kHz).
Semiconductor Group
44
PEB 2084
3.4.2
LT-T Mode
Command / Indication Codes, Conditional States
Commands (upstream)
LT-T Mode
Abbreviation Code
Remark
Timing
TIM
0000
Line interface is powered up
Reset
RS
0001
(x)
Test mode 1
TM1
0010
Transmission of pseudo-ternary
pulses at 2 kHz frequency (x)
Test mode 2
TM2
0011
Transmission of pseudo-ternary
pulses at 96 kHz frequency (x)
Activate request, priority 8
AR8
1000
Activation command,
D channel priority is 8
Activate request, priority 10 AR10
1001
Activation command,
D channel priority is 10
Active request loop
ARL
1010
Activation of loop 3 (x)
Deactivate indication
DI
1111
Line interface is powered down
(x) unconditional commands
Semiconductor Group
45
PEB 2084
Indications (downstream) Abbreviation Code Remark
LT-T Mode
Deactivate request
DR
0000
Deactivation request via S/T
interface
Reset
RES
0001
Reset acknowledge
Test mode 1
TM1
0010
TM1 acknowledge
Test mode 2
TM2
0011
TM2 acknowledge
Slip detected
SLIP
0011
Wander is larger than 50 µs peakto-peak (or 25 µs peak-to-peak if
programmed, refer to the C/W-bit
of the Configuration Register)
Resynchronization during
level detect
RSY
0100
Signal received, receiver not
synchronous
Power up
PU
0111
Line interface is powered up
Activate request
AR
1000
INFO 2 received
Activate request loop
ARL
1010
Loop 3 closed
Code violation received
CVR
1011
After each multiframe the receipt
of at least one illegal code
violation is indicated four times.
This function must be enabled by
setting the RCVE-bit in the
configuration register.
Activate indication loop
AIL
1110
Loop 3 activated
Activate indication with
priority class 8
AI8
1100
INFO 4 received,
D-channel priority is 8 or 9
Activate indication with
priority class 10
AI10
1101
INFO 4 received,
D-channel priority is 10 or 11
Deactivate confirmation
DC
1111
Line interface is powered down
Semiconductor Group
46
PEB 2084
Figure 25
QUAT-S State Diagram in the LT-T Mode, Unconditional States (Transitions)
Note:
1)
In state loop 3 activated, i3 is the internal signal, the external signal is i0.
Semiconductor Group
47
PEB 2084
LT-T Mode, Conditional States
• F3 power down
This is the deactivated state of the physical protocol. The receive line awake unit is
active.
• F3 power up
This state is similar to “F3 power down”. The state is invoked by a C/I command
TIM = “0000” (or DI static low). After the subsequent activation of the clocks the
“Power Up” message is output.
• F3 pending deactivation
The line interface reaches this state after receiving INFO 0 (from states F5 to F8).
From this state an activation is only possible from the line (transition “F3 pend. deact.”
to “F5 unsynchronized”). The power down state may be reached only after receiving
DI.
• F4 pending activation
Activation has been requested from the terminal, INFO 1 is transmitted, INFO 0 is still
received, “Power Up” is transmitted in the C/I channel. This state is stable: timer T3
(I.430) is to be implemented in software.
• F5/8 unsynchronized
At the reception of any signal from the NT, the QUAT-S ceases to transmit INFO 1,
adapts its receiver circuit, and awaits identification of INFO 2 or INFO 4. This state is
also reached after the line interface has lost synchronism in the states F6 or F7
respectively.
• F6 synchronized
When the QUAT-S receives an activation signal (INFO 2), it responds with INFO 3 and
waits for normal frames (INFO 4).
• F7 activated
This is the normal active state with the layer-1 protocol activated in both directions.
From state “F6 synchronized”, state F7 is reached almost 0.5 ms after reception of
INFO 4.
• F7 slip detected
When a slip is detected between the T interface clocking system and the IOM-2
interface clocks (phase wander greater than 50 µs, data may be disturbed, or 25 µs if
programmed in the configuration register) the line interface enters this state,
synchronizing again the internal buffer. After 0.5 ms this state is left again.
Semiconductor Group
48
PEB 2084
LT-T Mode, Unconditional States
The unconditional states should be left with the command TIM.
• Loop 3 closed
On Activate Request Loop command, INFO 3 is sent by the line transmitter internally
to the line receiver (INFO 0 is transmitted to the line). The receiver is not yet
synchronized.
• Loop 3 activated
The receiver is synchronized on INFO 3 which is looped back internally from the
transmitter. Data may be sent. The indication “AIL” is output to indicate the activated
state. When the S/T line awake detector, which is switched to the line, detects an
incoming signal, this is indicated by “RSY”.
• Test mode 1
Single alternating pulses are sent on the T interface (2 kHz repetition rate).
• Test mode 2
Continuous alternating pulses are sent on the T interface (96 kHz).
• Reset state
A hardware or software reset (RES) forces the line interface to an idle state where the
analog components are disabled (transmission of INFO 0) and the T line awake
detector is inactive. Thus activation from the NT is not possible.
Semiconductor Group
49
PEB 2084
3.4.3
Example of Activation/Deactivation
An activation and deactivation procedure between a QUAT-S and an ISAC-S or SBCX
in TE mode over the S/T interface line is shown in figure 26. It illustrates how the state
machines of the respective modes interwork to facilitate activation and deactivation. In
this case activation was initiated by an AR request at the terminal side and deactivation
by a DR command at the LT side. Activation could also be initialized at the LT side using
an AR request.
Figure 26
Example of S/T Interface Activation and Deactivation
Note: T1:
T2:
T3:
T4:
T5:
4 ms
≤ 1 ms
500 ms
16 ms
32 ms
Semiconductor Group
time for INFO 1 detection
time for synchronization
time for INFO 4 detection (2 subsequent frames)
time for INFO 0 detection
timer
50
PEB 2084
3.5
Diagnostic Functions, Test Loop-backs
Different test loops for B1, B2 and D-channels can be closed in the QUAT-S:
– Transparent analog loops (the data are also sent forward).
– Non transparent analog loops (the forward data path is blocked).
– External transparent analog loop for board test.
The loops may be closed in both operational modes, in LT-S and in LT-T, via the C/I
command ARL which may be applied (continuously) in the states “G4 pending
deactivation”, “G4 wait for DR” and “G1 deactivated”.
Loop transparency can be achieved by setting the LP-bit in the Configuration Register.
An example is shown in figure 27.
Figure 27
An Example for QUAT-S in LT-S Mode with a Transparent Loop (Loop 2)
and in LT-T Mode with a Non Transparent Loop (Loop 3)
Loop 2 and 3 are activated over the IOM-2 interface with Activate Request Loop (ARL).
Semiconductor Group
51
PEB 2084
3.6
S and Q Channel Access
According to CCITT recommendation I.430 a multi-frame (= 20 consecutive S/T frames)
provides an additional communication channel between TE and LT or LT and CO via S
and Q bits. Refer to figure 28.
Two S channels (S1 and S2) can be used by the QUAT-S for communication in data
downstream direction.
The Q channel bits are defined to be the bits in the FA bit position and are used for
communication in data upstream direction.
Figure 28
Direction of S and Q Channels in Different Application Modes
The following table shows the S and Q bit positions within the multi-frame (20 S/T
frames).
Frame Number
LT to TE or
CO to LT
TE to LT or
LT to CO
1
2
S11
S21
Q1
ZERO
6
7
S12
S22
Q2
ZERO
11
12
S13
S23
Q3
ZERO
16
17
S14
S24
Q4
ZERO
1
…
S11
…
Q1
…
Semiconductor Group
52
PEB 2084
All other S and Q bit positions within the remaining 12 frames of the multi-frame carry the
value ZERO.
The S and Q bits are accessed by the ELIC or EPIC via IOM-2 interface monitor channel.
The bits are handled in byte format packed in the lower nibble. The upper nibble is used
as identifier for the message type. The bit structure used by the QUAT-S is outlined in the
following table.
Identifier
Downstream Data
0
0
0
1
S11 S12 S13 S14
0
0
1
0
S21 S22 S23 S24
0
0
0
1
Upstream Data
Q1
Q2
Q3
Q4
QUAT-S has implemented a 3 × 4 bit RAM as buffer for the S and Q bits. The 4-bit RAM
cells can be addressed separately.
The data are handled by the QUAT-S in either non auto mode or in transparent mode.
In the transparent mode the S data are transferred in downstream direction as a real time
data stream of 1.600 bit/s (8 bits in 5 ms = 20 × 250 µs), the Q data are transferred in
upstream direction as a real time data stream of 800 bit/s (4 bits in 5 ms).
In non auto mode the received S and Q channels are checked for code changes and, if
a change is detected, the new four bits are transferred. In transmit direction each of the
4-bit message is repeated until a new word is written into the buffer (e.g. into the MFFIFO
in ELIC).
3.7
Default-Use of Pin CEB/SSYNC
The PEB 2084, QUAT-S, uses the input signal at pin CEB/SSYNC as an external
multiframe synchronization input in any case except if DCM(1:0) is set to “10” in any of
the four channels. The external multiframe synchronization input signal is expected to be
low for 125 µs and high for 2n + 1 times 125 µs thus defining an S/T interface multiframe
of n + 1 frames. The edges of the external multiframe synchronization input signal have
to be in coincidence with the rising edges of FSC. Each low at this input will generate one
frame with M-bit as binary ONEs at the S/T interface output. When setting bit MFD
(configuration register) to “1”, this function enables the generation of arbitrary
multiframes, which may be useful to synchronize digital cellular wireless
communications equipment.
While using SSYNC for M-bit generation the short FSC signal is not allowed as it would
reset the Super-Frame generated by SSYNC. If not used, the SSYNC input must be
connected via a pull-up resistor to VDD.
Semiconductor Group
53
PEB 2084
4
Registers Description
As the QUAT-S contains four PEB 2081, SBCX, cores, it contains four complete register
sets. All registers programming is done via the four IOM monitor channels.
Access to the registers of the QUAT-S are treated as local functions and therefore are
marked with the code “1000” in the first four bits of the message:
Monitor message:
Code = 1 0 0 0
Internal address
D7 D6 D5 D4
D3 D2 D1 D0
Register Read
An internal register is read by setting the internal address to zero (0H) and indicating the
address of the specific register in the bits D(3:0). The bits D(7:4) are set to zero.
E.g. “80H 01H” is the read command for the register 1H, the Configuration Register.
Code = 1 0 0 0
0000
0000
register addr. = 01H
The response message from QUAT-S comprises two bytes, the first showing the
address after the local function code, the second showing the register data.
E.g. “81H (D7:0)” is the response to a read command on address 1H, where D(7:0) is the
content of the Configuration Register.
Code = 1 0 0 0
register addr.= 01H
D7 D6 D5 D4
D3 D2 D1 D0
Register Write
An internal register is written by setting the internal address to the address of the specific
register. The register will then be loaded with the value of D(7:0),
e.g. “81H 5DH” programs the Configuration Register (addr. 1H) with the value 5DH.
Code = 1 0 0 0
4.1
register addr.
D7 D6 D5 D4
D3 D2 D1 D0
Identification Register
Read, Address: 0H
bit 7
Format:
0
bit 0
1
0
0
0
1
0
0
After the read command “80H 00H” according to the procedure described above the
QUAT-S transmits the response “80H 44H”.
The returned value 44H of the Identification Register is specific for the PEB 2084,
QUAT-S.
Semiconductor Group
54
PEB 2084
4.2
Configuration Register
Read/Write, Address: 1H
bit 7
Format:
MFD
bit 0
RCLK
0
LP
SQM
RCVE
C/W
MODE
Initial value: 00H
Bit-name Description
MFD
Multi-Frame Disable (write):
0: All multi-frame functions active.
1: Multi-frame generation (LT-S) or synchronization (LT-T) prohibited.
No SQ monitor messages released.
Multi-Frame Detected (read):
0: No multi-frame synchronization achieved.
1: Multi-frame synchronization (LT-T) achieved.
RCLK
Receive Clock
0: No output signal at pin CLK1/IDS
(if all QUAT-S channels are programmed to 0 at this bit location, the
output pin CLK1 is tristated)
1: The 1.536 MHz clock synchronized to the receiver (LT-T) is output
at the pin CLK1(Due to an internal short-circuit safety logic, a 1 is
only processed if the other three channels are set to 0 at this bit
location.)
Note: The pin CLK1/IDS is used to pin-strap the DCL data clock ratio
during HW reset phase
10: Double clock
11: Single clock
LP
Loop
LT-S mode
0: Transparent analog loop
1: Non transparent analog loop
LT-T mode
0: Non transparent analog loop
1: External transparent loop
SQM
SQ channel handling Mode selection
0: Non auto mode
only S1 and Q channels
1: Transparent mode
S1, S2 and Q channels
Semiconductor Group
55
PEB 2084
Bit-name Description
RCVE
Receive Code Violation Indication (C/I) Enable
0: Normal operation
1: A code violation detector is implemented to support the
Far-end-code-violation (FECV) function according to ANSI T1.605.
After each multi-frame the receipt of at least one illegal code
violation is indicated by the occurrence of four times the CI code
1011 (CVR).
C/W
Configuration / Wander detection
LT-S mode: Configuration
0: Point-to-point or extended passive bus configuration
(adaptive timing recovery).
1: short passive bus configuration (fixed timing recovery)
LT-T mode: Wander detection (warning on slip detection in C/I, data may
be lost!)
0: “SLIP” after 50 µs wander
1: “SLIP” after 25 µs wander
MODE
Mode select
0: LT-S mode selected
1: LT-T mode selected
4.3
Loopback Register
Read/Write, Address: 2H
bit 7
Format:
0
bit 0
SB2
SB1
0
0
0
1
0
Initial value: 02H
Bit-name Description
SB2
Loopback B2 channel at the S/T interface
SB1
Loopback B1 channel at the S/T interface
Note: Register bits not described may exist in hardware due to the use of the PEB 2081,
SBCX, core. Writing those bits other than the default value will cause unexpected
behavior of the device.
Semiconductor Group
56
PEB 2084
4.4
Auxiliary Register
Read/Write, Address: 4H
bit 7
Format:
CI3
bit 0
CI2
CI1
CI0
TOD
0
DCM1
DCM0
Initial value: CI(3:0), 0H
Bit-name Description
CI(3:0)
C/I codes as in C/I channel
The indication can be read via monitor channel CI (3:0).
TOD
Time-Out Disable
0: Monitor timeout (minimum 5 ms)
1: The time-out function of the monitor transmitter can be disabled
to ease manual software debugging.
DCM(1:0) D-channel mode:
Specific D channel associated functions including the pins DRDY and
CEB/SSYNC:
00: Transparent D-channel, pins DRDY and CEB/SSYNC tristated.
10: LT-T mode: D-channel collision resolution according to CCITT
I.430. Pin DRDY conveys control information
synchronous to D-channel timeslots to control
PEB 2075, IDEC (0: stop; 1: go).
LT-S mode: D-channel access control by establishing a logical
passive bus structure, where the received D-channel is
ANDed with the other channels selected over pin
CEB and the resulting value is sent back as Echo bit.
11: LT-T mode: D-channel collision resolution according to CCITT
I.430. Pin DRDY conveys asynchronous control
information to control SACCO-B in the ELIC,
PEB 20550. This mode is only applicable for a single
channel LT-T application (0: go; 1: stop).
LT-S mode: D-channel access control via the central D-channel
arbiter unit of the PEB 20550, ELIC. Dependent on
the command, each channel mirrors the received
D-channel into the Echo channel inverted
command 1100H) or unchanged (1000H).
01: Not applicable
Note: Register bits not described may exist in hardware due to the use of PEB 2081,
SBCX, core. Writing those bits other than the default value will cause unexpected
behavior of the device.
Semiconductor Group
57
PEB 2084
4.5
Other Registers
Other registers are implemented at address locations 3H, 5H, and 8H. Access to those
monitor addresses may cause unexpected behavior of the device.
Semiconductor Group
58
PEB 2084
5
Electrical Characteristics
All characteristics given are valid under the following conditions unless otherwise
indicated:
TA = 0 to 70 °C; VDD = 5 V ± 5 %; VSS = 0 V
5.1
Absolute Maximum Ratings
Parameter
Symbol
TA
Tstg
Storage temperature
Voltage on any pin with respect to ground VS
Vmax
Maximum voltage on any pin
Ambient temperature under bias
Limit Values
Unit
0 to 70
°C
– 65 to 125
°C
– 0.4 to VDD + 0.4
V
6
V
Note: Stresses above the listed values may cause permanent damage to the device.
Exposure to absolute maximum rating conditions for extended periods may affect
device reliability.
Maximum ratings are absolute ratings; exceeding only one of these values may
cause irreversible damage to the integrated circuit.
Semiconductor Group
59
PEB 2084
Line Overload Protection
The maximum input current (under overvoltage conditions) is given as a function of the
width of a rectangular input current pulse. For the destruction current limits refer to
figure 29.
Ι
5000
mA
500
50
5
t
10
-9
10
-7
10
-5
10
-3
sec
ITD05400
Figure 29
Maximum Line Input Current for the Receiver
Semiconductor Group
60
PEB 2084
5.2
Pin
DC Characteristics
Parameter
Symbol Limit Values Unit Test Condition
min.
max.
– 0.4
+ 0.8
V
2.0
VDD
V
All pins
Input voltage
except
Input high voltage
SXna,b;
SRna,b
XTAL1, 2 Output low voltage
VIL
VIH
VOL
0.45
V
IOL = 2 mA
DRDY,
IDO
VOL1
0.45
V
IOL = 7 mA
2.4
V
VDD
V
IOH = – 400 µA
IOH = – 100 µA
+1
µA
0 V ≤ VIN ≤ VDD
+1
µA
0 V ≤ VOUT ≤ VDD
2.03
2.10
2.31
2.39
V
V
RL = 50 Ω1)
RL = 400 Ω1)
13.4
mA
RL = 5.6 Ω1)
inactive or
during binary
one
(VDD = 0 … 5 V)
during binary
zero
RL = 50 Ω
Output low voltage
All pins
Output high voltage
except
SXna,b;
SRna,b;
XTAL1, 2 Input leakage current
Output leakage current
+ 0.4
VOH
– 0.5
ILI
ILO
VX
SXna,b
Absolute value of
output pulse amplitude
(VSXna – VSXnb)
SXna,b
Transmitter output current IX
7.5
SXna,b
Transmitter output
impedance
ZX
10
kΩ
0
Ω
kΩ
Ω
SRna,b
Receiver input
impedance
ZR
30
100
XTAL1
Input high voltage
VIH
3.5
VDD
VDD = 5 V
VDD = 0 V
V
+ 0.4
XTAL1
Input low voltage
XTAL2
Output high voltage
VIL
VOH
XTAL2
Output low voltage
VOL
– 0.4
1.5
4.5
V
V
0.4
V
IOH = 5 µA,
C ≤ 50 pF
IOH = 5 µA,
C ≤ 50 pF
Note: 1) Due to the transformers, the load resistance as seen by the circuit is four times RL.
Semiconductor Group
61
PEB 2084
DC Characteristics (cont’d)
Pin
Parameter
Symbol Limit Values Unit Test Condition
min.
Power
supply
current
5.3
operational ICC
max.
55
mA
VDD = 5 V
inputs at
VSS/VDD
power
down
5
mA
No outputs
loads, no
XTAL1
power
down
10
mA
No output
loads, with
XTAL1
Capacitances
TA = 25 °C; VDD = 5 V ± 5 %; VSS = 0 V; fC = 1 MHz
Pin
Parameter
Symbol
Limit Values Unit
min.
All pins except SXn a, b
Pin capacitance
SXn a, b
Output capacitance
against VSS
XTAL1, 2
External load capacitance
Semiconductor Group
62
max.
CIO
COUT
7
pF
10
pF
CL
50
pF
PEB 2084
5.4
Recommended Oscillator Circuits
Crystal nominal frequency: 7.68 MHz ± 100 ppm
Figure 30
Recommended Oscillator Circuits
5.5
AC Characteristics
TA = 0 to 70 °C; VDD = 5 V ± 5 %
AC testing: Set-up, Hold, Delays
Inputs are driven at VDD – 0.5 V for a logic “1” and 0.45 V for a logic “0”.
Timing measurements are made at 2.0 V for a logic “1” and at 0.8 V for a
logic “0”.
Figure 31
Input/Output Wave Form for AC Tests
Jitter
The clock input FSC is used as reference clock to provide the 192 kHz clock for the S/T
interface. In the case of a desynchronous 7.68 MHz clock generated by an oscillator, the
clock FSC should have a jitter of less than 50 ns peak-to-peak.
Semiconductor Group
63
PEB 2084
5.6
Clocks
CLK1
Parameter
Symbol
Limit Values Unit Test Condition
min.
max.
High phase of clock
tWH
250
ns
50 pF load
capacitance at CLK1
Low phase of clock
tWL
250
ns
50 pF load
capacitance at CLK1
Clock period
Tp
650.8
651.2
ns
CLK2
Parameter
Symbol
Limit Values
min.
Unit Test Condition
max.
High phase of clock
tWH
40
ns
50 pF load capacitance
at CLK2
Low phase of clock
tWL
40
ns
50 pF load capacitance
at CLK2
Clock period
TP
130.16
130.24
ns
CLK2 is directly derived from the oscillator clock and can drive up to 6 oscillator inputs
of other communication ICs, e.g. ISAC-S, PEB 2085.
3.5 V
0.8 V
t WH
t WL
TP
Figure 32
Definition of Clock Period and Width
Semiconductor Group
64
ITT00766
PEB 2084
5.7
IOM®-2 Interface Timing
Figure 33
Timing of the IOM®-2 Interface with Double Data Rate DCL
Timing Characteristics of the IOM®-2
Parameter
Symbol
Limit Values
min.
typ.
Unit
max.
30
ns
70
ns
130
ns
Data delay to frame1)
tFH
tFS
tFWH
tFWL
tDDC
tDDF
Data setup
tDS
20
ns
Data hold
tDH
50
ns
Frame sync hold
Frame sync setup
Frame sync high
Frame sync low
Data delay to clock
tDCL
Note: 1) tDDF = 0.5 tDCL + tDDC – tFH
Semiconductor Group
65
100
ns
150
ns
Conditions
PEB 2084
Figure 34
IOM®-2 Interface Timing with Single Data Rate DCL
Timing Characteristics of the IOM®-2
Parameter
Symbol
Limit Values
min.
Frame sync. hold
Frame sync. setup
Frame sync. high
Frame sync. low
Data delay to clock
Data delay to frame1)
Data setup
Data hold
tFH
tFS
tFWH
tFWL
tDDC
tDDF
tDS
tDH
max.
30
ns
70
ns
130
ns
tDCL
100
ns
150
ns
20
ns
50
ns
Note: 1) tDDF = 0.5 tDCL + tDDC – tFH
Semiconductor Group
typ.
Unit
66
Conditions
PEB 2084
Figure 35
SSYNC Timing
Parameter
Symbol
Limit Values
min.
tSSYS
tSSYH
Superframe sync. setup
Superframe sync. hold
Semiconductor Group
67
Unit
max.
200
ns
200
ns
PEB 2084
5.8
Timing of Boundary Scan Test Interface
Figure 36
Boundary Scan Test Interface Timing
Parameter
Symbol
Limit Values
min.
Test clock period
Test clock period low
Test clock period high
TMS setup time to TCK
TMS hold time from TCK
TDI setup time to TCK
TDI hold time from TCK
TDO valid delay from TCK
Semiconductor Group
tTCP
tTCPL
tTCPH
tMSS
tMSH
tDIS
tDIH
tDOD
max.
160
ns
80
ns
80
ns
30
ns
30
ns
30
ns
30
ns
60
68
Unit
ns
PEB 2084
5.9
Transceiver Characteristics
The transceiver comprises the transmitter output stages, the differential-to-single ended
receiver input stage, the loop switch, the peak detector, and the threshold comparators.
Figure 37
Transceiver Architecture of one S/T-Channel
When transmitting a binary ZERO, the transmitter output is ± 2.1 V (difference between
SXna and SXnb), when transmitting a binary ONE, it is tristate. The receiver input range
is ± 2.5 V to ± 85 mV, the latter being a hardwired minimum peak level.
Semiconductor Group
69
PEB 2084
Transmitter Performance
Cable 0.6 mm, 120 nF/km
Configuration
Condition
Distance TE-TE
Distance TE-NT/LT
Point-to-point
no noise
–
980 m
200 / 2000 kHz
100 mVpp
–
940 m
no noise
120 m
720 m
120 m
540 m
Ext. passive bus
(Roundtrip < 2 µs) 200 / 2000 kHz
100 mVpp
Cable 0.6 mm, 30 nF/km
Configuration
Condition
Distance TE-TE Distance TE-NT/LT
Point-to-point
no noise
–
> 1500 m
200 / 2000 kHz
100 mVpp
–
> 1050 m
no noise
> 250 m
> 1250 m
> 250 m
> 800 m
Ext. passive bus
(Roundtrip < 2 µs) 200 / 2000 kHz
100 mVpp
Semiconductor Group
70
PEB 2084
6
Package Outlines
GPM05622
Stand off
Plastic Package, P-MQFP-44-2
(Plastic Metric Quad Flat Package)
Sorts of Packing
Package outlines for tubes, trays etc. are contained in our
Data Book “Package Information”.
SMD = Surface Mounted Device
Semiconductor Group
71
Dimensions in mm
PEB 2084
7
Appendix
List of Transformer Manufacturers and S0 Transformers
The following list contains transformers recommended by different manufacturers for
use with Siemens S0 transceivers.
Transformers marked with * have been tested in Siemens S evaluation boards and have
shown positive test results concerning pulse shape and impedance requirements of
ETS 300 012.
Manufacturers
Transformers
APC
APC 2040 S
APC 1020 S
APC 3060 S
APC 9018 D
APC 3366 D
Pulse Engineering
PE-68975*
PE-64995
PE-65495
PE-65795
PE-68995
S + M Components
B78384-A1060-A2*
B78384-P1111-A2
Vacuumschmelze VAC
T60403-L4025-X021*
T60403-L4097-X011*
T60403-L5051-X006*
T60403-L4021-X066
T60403-L4025-X095
T60403-L4097-X029
T60403-L5032-X002
VALOR
PT 5001
PT 5069
ST 5069
VOGT
543 21 002 00*
543 21 004 00*
Semiconductor Group
72