INFINEON PEB2080-N

General Information
Contents
Page
1
1.1
1.2
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Pin Definitions and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
System Integration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
2
2.1
2.2
2.3
2.4
2.5
Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
General Functions and Device Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Individual Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Additional Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
15
15
16
20
27
36
3
3.1
3.2
3.3
Operating Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Clocking, Reset and Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Control of Layer 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
38
38
38
41
4
Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
5
Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
6
Information on Literature. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77
7
Semiconductor Group - Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
IOM®, IOM®-1, IOM®-2, ISAC®-P, ISAC®-S, EPIC® are registered trademarks of Siemens AG
Semiconductor Group
3
S/T Bus Interface Circuit
(SBC)
PEB 2080
PEF 2080
Preliminary Data
1
CMOS IC
Features
● Full duplex 2B + D S/T-interface transceiver according to
●
●
●
●
●
●
●
●
●
●
●
●
CCITT I.430
Conversion of the frame structure between the S/T and
IOM® interfaces
D-channel access control
Activation and deactivation procedures according to
CCITT I.430
Built-in wake-up unit for activation from power-down state
Adaptively switched receive thresholds
Control via IOM interface
Several operating modes
Receive timing recovery according to selected operating
mode
Frame alignment with absorption of phase wander in trunk
line applications
Switching of test loops
Advanced CMOS technology
Low power consumption:
PEB 2080:
standby less than 5 mW
active max. 65 mW
PEF 2080:
standby less than 6.5 mW
active max. 70 mW
Type
Ordering Code
Package
PEB 2080-N
Q67100-H8395
P-LCC-28-R (SMD)
PEB 2080-P
Q67100-H2954
P-DIP-22
PEF 2080-N
Q67100-H6097
P-LCC-28-R (SMD)
Semiconductor Group
5
P-LCC-28-R
P-DIP-22
06.92
Features
The S-Bus Interface Circuit (SBC) PEx 2080 implements the four-wire S/T-interface used to link
voice/data terminals to an ISDN. Through selection of operating mode, the device may be employed
in all types of applications involving an S interface. Two or more SBC´s can be used to build a pointto-point, passive bus, extended passive bus or star configuration.
Specific ISDN applications of the SBC include: ISDN terminals, ISDN network termination (Central
Office and PABX applications), and PABX trunk lines to Central Office.
The device provides all electrical and logical functions according to CCITT recommendation I.430.
These include: mode-dependent receive timing recovery, D-channel access and priority control,
and automatic handling of activation/deactivation procedures. The SBC does not require direct
microprocessor control.
The SBC is an IOM compatible, 22-pin CMOS device. It operates from a single + 5 V supply and
features a power-down state with very low power consumption.
Semiconductor Group
6
Features
Pin Configuration
(top view)
P-DIP-22
Semiconductor Group
P-LCC-28-R
7
Features
1.1
Pin Definitions and Functions
Pin No.
P-LCC
Pin No.
P-DIP
Symbol
Input (I)
Function
Output (O)
3
2
SX1
O
Positive output S-bus transmitter
4
3
SX2
O
Negative output S-bus transmitter
7
5
SDO
O
Serial Data Out, IOM interface
10
8
SDI
I
Serial Data In, IOM interface
8
6
DCL
I/O
Serial Data Clock, IOM interface
9
7
FSC
I/O
Frame sync, IOM interface
16
5
20
12
4
15
M2
M1
M0
I
I
I
Setting of operation mode
14
11
19
17
11
9
14
13
X3
X2
X1
X0
I
I/O
I/O
I/O
Functions depending on the selected operating
mode see chapter 2.2
21
16
CP
I/O
Clock Pulse/special purpose
24
19
XTAL1
I
Connection for external crystal, or input for
external clock generator
23
18
XTAL2
O
Connection for external crystal, n.c. when
external clock generator is used
26
20
SR2
I
S-bus receiver, signal input
27
21
SR1
O
S-bus receiver, 2.5 V reference output
2
1
VDD
I
Power supply, + 5 V ± 5 %
22
17
VSS
I
Power supply, ground
13
10
RST
I
Reset, active low
6
-
X4
I
External filter connection, active low
28
-
UFI
O
Opamp output for external filter
25
-
AUX
I
Auxiliary input: VDD or VSS to be applied
15
18
1
-
N.C.
-
not connected
Semiconductor Group
8
Features
Logic Symbol
Semiconductor Group
9
Features
Block Diagram
Semiconductor Group
10
Features
1.2
System Integration
The SBC implements the four-wire S and T interfaces used in the ISDN basic access. It may be
used at both ends of these interfaces.
The applications include:
ISDN terminals (TE)
ISDN network termination (NT)
ISDN subscriber line termination (LT-S)
ISDN trunk line termination (LT-T) (PABX connection to Central Office).
These applications are shown in figure 1, where the usual nomenclature as defined by the CCITT
for the basic access functional blocks and reference points, has been used.
Figure 1
Applications of SBC
Semiconductor Group
11
Features
Some of the S interface wiring configurations possible with the SBC are shown in figure 2 with
approximate typical distances.
*) (N.B.: “TR” stands for terminating resistor of value 100 Ω).
Figure 2
Some S-Interface Wiring Configurations
*) The maximum line attenuation tolerated by the SBC is 10 dB at 96 kHz
Semiconductor Group
12
Figure 3
ISDN Oriented Modular (IOM®) Architecture
Semiconductor Group
13
Figure 3 gives an example of an application of the SBC in an IOM (ISDN Oriented Modular)
architecture.
By separate implementation of OSI layer-1 and layer-2 functions, and through unified control
procedures, the architecture provides flexibility with respect to various transmission techniques.
The IOM devices are all low-power, high integration, single + 5 V supply CMOS devices. Through
mode switching, each device may be used in several applications: thus with one and the same
limited set of devices all ISDN basic access configurations are covered. Note that one of the
compatible layer-1 devices (SBC, IBC, IEC) requires direct microprocessor control. This is, of
course, due to the fact that the IOM interface provides all the necessary functions for layer-1/layer2 communication.
Semiconductor Group
14
Semiconductor Group
15
Functional Description
2
Functional Description
The S-bus interface circuit PEx 2080 performs the layer-1 functions for the S/T interface of the ISDN
basic access.
2.1
General Functions and Device Architecture
The common functions for all operating modes are:
● Iine transceiver functions for the S interface according to the electrical specifications of
CCITT I.430;
● dynamically adaptive threshold control for the receiver;
● conversion of the frame structure between IOM and S interfaces;
● conversion from/to binary to/from pseudo-ternary code.
Mode specific functions are:
receive timing recovery;
S-timing generation using IOM timing synchronous to system, or vice versa;
D-channel access control and priority handling;
D-channel echo bit generation;
activation/deactivation procedures, triggered by primitives received over the IOM interface or by
INFO’s received from the line;
● frame alignment according to CCITT Q.503;
● execution of test loops.
●
●
●
●
●
Analog Functions
The full-bauded pseudo-ternary pulse shaping is achieved with the integrated transmitter which is
realized as a current limited voltage source. A voltage of 2.1 V is delivered between SX1-SX2,
which yields a current of 7.5 mA over 280 Ω.
The receiver is designed as a threshold detector with adaptively switched threshold levels. Pin SR1
delivers 2.5 V as an output, which is the virtual ground of the input signal on pin SR2.
An external transformer of ratio 2:1 is needed in both receive and transmit direction to provide for
isolation and transform voltage levels according to CCITT recommendations.
Semiconductor Group
15
Functional Description
Digital Functions
A DPLL circuitry working with a frequency of 7.68 MHz ± 100 ppm serves to generate the 192-kHz
line clock from the reference clock delivered by the network and to extract the 192-kHz line clock
from the receive data stream.
The 7.68-MHz clock may be generated with the use of an external crystal between pins XTAL1 and
XTAL2. It may also be provided by an external oscillator, in which case XTAL2 is left unconnected.
The “Control” block includes the logic to detect layer-1 commands and to communicate with
external layer-1 or layer-2 devices via the IOM interface.
An incorporated finite state machine controls ISDN layer-1 activation/deactivation.
The D-channel access procedure according to CCITT I.430 including priority management is fully
implemented in the SBC. When used as an S-bus master in a multipoint configuration, the device
generates the echo bits necessary for D-channel collision detection. In the NT-mode, moreover, the
echo channel may be made externally available through an auxiliary pin and thus “intelligent NT’s”
(star configuration) may be implemented.
In terminal applications (TE) the Q channel as specified by I.430 is supported (stepping A6 and up.
The SBC sends a binary one in F A -bit position to allow another terminal to use the extra
transmission capacity.)
The buffer memory serves to adapt the different bit rates of the S and the IOM interface. In addition,
in trunk line applications it absorbs the possible deviation between two system clocks, according to
CCITT Q.503 (slip detection).
2.2
Operating Modes
The operating modes are determined by pin strapping on pins M0 to M2. The four basic operating
modes are: TE, NT, LT-S, LT-T.
In three of these operating modes, the IOM may be programmed to function in the IOM-1 mode, in
the IOM -2 mode or in the inverted mode. To see which IOM timing mode is applicable in the four
basic operating modes, refer to table 1.
In table 1, the functions of the operating mode specific pins are given: these pins are DCL (IOM
interface data clock, input/output), FSC (IOM interface frame sync, input/output), CP (auxiliary
clock/test pin), and X0 to X3.
Depending on the selected mode, pins CP, X2 and X1 provide auxiliary clocks, either asynchronous
or synchronous to the S-interface:
3840 kHz
2560 kHz
1280 kHz
1536 kHz
512 kHz
clocks derived from the 7680-kHz crystal
clocks synchronized to S interface
These auxiliary clocks may be used to drive, e.g. a codec filter, or a microprocessor system (TE
applications).
Semiconductor Group
16
Functional Description
Table 1
Operating Modes and Functions of Mode Specific Pins of SBC
Application
TE
TE
TE
LT-T
LT-T
NT
LT-S
LT-S
LT-S
Operation Inverted
of IOM
Mode
Interface
Inverted
Mode
IOM-1
Mode
IOM-2
Mode
or
Invert.
Mode
IOM-1
Mode
IOM-1
Mode
IOM-2
Mode
or
Invert.
Mode
IOM-1
Mode
IOM-1
Mode
M2
M1
M0
0
0
0
0
0
1
0
1
0
0
1
1
0
1
1
1
1
1
1
0
0
1
1
0
1
1
0
DCL
o:
o:
512 kHz* 512
kHz*
o:
512
kHz*
i:
4096
kHz
i:
512
kHz
i:
512
kHz
i:
4096
kHz
i:
512
kHz
i:
512
kHz
FSC
o:
8 kHz*
o:
8 kHz*
o:
8 kHz*
i:
8 kHz
i:
8 kHz
i:
8 kHz
i:
8 kHz
i:
8 kHz
i:
8 kHz
CP
o:
1536
kHz*
o:
1536
kHz*
o:
512
kHz*
o:
512
kHz*
o:
512
kHz*
i:SCZ
i:fixed
at 0
i:fixed
at 0
i:fixed
at 0
X3
i:ENCK
i:ENCK
i:ENCK i:fixed
at 1
i:fixed
at 0
i:BUS
i:BUS
i:BUS
i:BUS
X2
o:
2560
kHz
o:
1280
kHz
o:
ECHO
i:TS2
i:fixed
at 0
i:SSZ
i:TS2
i:fixed
at 0
o:
192
kHz*
X1
o:
3840
kHz
o:
3840
kHz
o:
3840
kHz
i:TS1
i:fixed
at 0
i:DEX
i:TS1
o:
7680
kHz
o:
7680
kHz
X0
o:RDY
o:RDY
i:CON
i:TS0
i:CON
i/o:DE
i:TS0
i:fixed
at 0
i:fixed
at 1
*) synchronized to S/T interface
i:input
o:output
Semiconductor Group
17
Functional Description
The other uses of the auxiliary pins are:
ENCK
input
Enable Clock. At “0”, forces the SBC to deliver IOM timing at all
times, regardless of SDI input level; in TE mode, pin X3.
BUS
input
At “1”, specifies a bus configuration (as opposed to point to point
or extended passive bus); in NT and LT-S modes, pin X3.
ECHO
output
push-pull
Reproduces the E bits received from the S interface
synchronously to IOM frame “D” bits (bit positions 24 and 25 of
IOM frame). All other bit positions are binary “1”; in TE mode, pin
X2.
SSZ
input
Send Single Zeros. At “0”, forces the SBC to transmit alternating
pulses at 250 s intervals (period 2 kHz) on S-interface for test
purposes; X2 in NT mode.
RDY
output
Ready. Provides a signal logically equal push to bit 3 of
MONITOR channel. Signals the pull D-channel status (“0” =
occupied, “1” = free) to layer-2 component; X0 in TE mode.
CON
input
Connected. At “0”, prevents the SBC from activating and
transmitting on the S interface. Indicates whether the device is
connected to the S interface or not; X0 in TE and LT-T modes.
DEX
input
External D-channel Echo enable. At “1”, makes the E-bit
dependent on the DE (X0) input. Used in NT mode to build a star
configuration; X1 in NT mode.
DE
input/output
D-channel Echo. The DE outputs should be tied together (open
open drain with drain) in an NT-star configuration, to obtain the global echo bit;
integrated pull- X0 in NT mode.
up resistor
TS0 to TS2
inputs
Semiconductor Group
Time Slot 0 to 7. IOM interface time slot to be used =
4 x TS2 + 2 x TS1 + TS0; LT-T and LT-S in IOM-2 mode and
inverted mode.
18
Functional Description
Figure 4
Clocking of SBC in Different Operating Modes
Semiconductor Group
19
Functional Description
2.3
Interfaces
S Interface
According to CCITT recommendation I.430, pseudo-ternary encoding with 100 % pulse width is
used on the S interface. A logical 1 corresponds to a neutral level (no current), whereas logical 0´s
are encoded as alternating positive and negative pulses. An example is shown in figure 5.
Figure 5
S-Interface Line Code
One S 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 four D bits, according to the B1 + B2 + D structure defined for
the ISDN basic access (total useful data rate: 144 kbit/s). Frame begin is marked using a code
violation (no mark inversion). The frame structures (from network to subscriber, and subscriber to
network) are shown in figure 6.
Figure 6
Frame Structure at Reference Ponts S and T (CCITT I.430)
Semiconductor Group
20
Functional Description
Digital Interface
IOM Frame Structure
The SBC is provided with a digital interface, the IOM interface, for communication with other ISDN
devices, in other words with units realizing OSI layer-1 functions (such as the ISDN Echo
Cancellation Circuit IEC PEB 2090) or layer-2 functions (such as the ISDN Communication
Controller ICC PEB 2070).
The IOM interface is a four-wire serial interface with: a bit clock, a frame clock and one data line per
direction (figure 7).
The ISDN data rate of 144 kbit/s (B1 + B2 + D) is transmitted transparently in both directions over
the interface. In addition, it is necessary to interchange control information for activation and
deactivation of OSI layer 1 and for switching of test loops. This information is transferred using time
division multiplexing with a 125-µs total frame length.
Figure 7
IOM® Interface Signals
Semiconductor Group
21
Functional Description
The basic frame consists of a total of 32 bits, or four octets: B1 + B2 + D (18 bits) plus 14 bits of
MONITOR and control information. The data in both directions are synchronous and in phase
(figure 8).
Figure 8
IOM® Interface Frame Structure
1st octet B1:
2nd octet B2
3rd octet:
4th octet B*:
B channel (64 kbit/s), most significant bit first
-”-”MONITOR channel (64 kbit/s) -”2-bit D channel (16 kbit/s)
4-bit C/I channel
T channel: not used with SBC
E bit: not used with SBC.
The C/l channel is used for communication between the SBC and a processor via a layer-2 device,
to control and MONITOR layer-1 functions. The codes originating from layer-2 devices are called
“commands”, those sent by the SBC are called “indications”. For a list of the C/l codes and their use,
refer to chapter 4.
Three modes of the lOM are distinguished. These modes differ only with respect to the physical data
rate (256 or 8 x 256 kbit/s) and to polarity of the clocks.
Semiconductor Group
22
Functional Description
IOM-1 Mode
This timing mode is applicable in all operating modes of the SBC.
Nominal bit rate of data (SDI and SDO):
Nominal frequency of DCL:
Nominal frequency of FSC:
256 kbit/s
512 kHz
8 kHz
Transitions of the data occur after even-numbered rising edges of DCL. Even-numbered rising
edges of the clock are defined as the second rising edge following the rising edge of FSC and every
second rising edge thereafter.
The frame is earmarked by the rising edge of FSC.
Figure 9
Timing of Data and Clocks of IOM® in the Normal Mode
Inverted Mode
Timing mode applicable in TE mode: 512 kHz
The characteristics are the same as above, except that FSC is not a signal with 50 %, duty cyc!e
but an active low pulse, one DCL clock period long, which occurs in the middle of bit 27 (fourth bit
of B*).
Timing mode applicable in LT-T and LT-S operating modes: 4096 kHz
Nominal bit rate of data bursts (SDI and SDO)
Nominal frequency of DCL
Nominal frequency of FSC
2048 kbit/s
4096 kHz
8 kHz.
The frame clock FSC is an active low strobe clock. The strobe earmarks the second half of bit
no. 251 in the frame. The low state of the strobe is detected with the rising edge of DCL. Refer to
figure 10.
The data at the input SDI is valid on the even-numbered rising edges of DCL. Transitions of the data
on SDO occur after even-numbered falling edges of DCL. The rising edge earmarked by the frame
strobe is an even-numbered rising edge of DCL. The following falling edge is an even-numbered
falling edge.
Semiconductor Group
23
Functional Description
The bursts are allocated to consecutive time slots in a frame by the static inputs X0 (TS0), X1 (TS1),
X2 (TS2). Table 2 indicates the allocations. Figure 11 gives the positions of the respective frames.
Figure 10
Timing of Data and Clocks of IOM® in the Inverted Mux Mode
IOM®-2 Mode
Timing mode applicable in LT-T and LT-S modes: 4096 kHz.
As opposed to inverted mode, data change with rising edges and frame synchronization is defined
as in IOM-1 mode. (cf. IOM® Interface Specification, Rev. 2.2).
Table 2
Allocation of Time Slots
Time Slot No.
TS2
TS1
TS0
Bit No.
0
1
2
3
4
5
6
7
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0 … 31
32 … 63
64 … 95
96 … 127
128 … 159
160 … 191
192 … 223
224 … 255
Semiconductor Group
24
Functional Description
Figure 11
Position of IOM® Frames as a Function of Time Slot Allocation in IOM®-2 and Inverted Mode
Semiconductor Group
25
Functional Description
The IOM-2 mode may be used to link up to eight SBC´s over a single 2048 kbit/s interface to an
exchange or PABX (figure 12).
Figure 12
IOM® Interface 2048 kbit/s MUX Mode
Semiconductor Group
26
Functional Description
2.4
Individual Functions
The SBC transmits data between the IOM interface and the line interface. The relative frame
positions have been selected to minimize the round trip delays of the B channels, which are:
125 µs for TE, NT and LT-S in normal IOM mode, max. 250 µs for LT-T in normal IOM mode and
LT-S in inverted mux mode and, finally, max. 375 µs for LT-T in inverted mux mode.
In the active state the data of the B channels are switched through transparently. The same applies
to the D channel, except in TE mode where D-channel switching is subject to the S bus D-channel
access procedure and collision detection.
S/T Interface Pre-Filter
In some applications it may be desirable to improve the signal-to-noise ratio of the received S/T
interface signal by filtering out undesirable frequency (usually high frequency) components. This
may be realized by an external pre-filter.
To simplify the implementation of this filter, an operational amplifier is integrated in the ISAC-S, as
shown in figure 13. By connecting an RC network between input SR2 and the extra pin UFI an
active RC filter of desired order can be realized (one example is shown in figure 13b).
Figure 13a
Prefilter Connections
Semiconductor Group
27
Functional Description
Figure 13b
Example of 2nd Order RC Network
Note:
Following component values are recommended to give a 500 kHz cutoff, and 600 nS (± 170 nS)
propagation delay time:
R1 = R 2 = 10 kΩ
C1 =
13 pF
C2 =
22.5 pF
an extra delay may be introduced into the received signal by a filter.
Semiconductor Group
28
Functional Description
NT and LT-S Applications
The 192-kHz transmit bit clock is synchronized to the IOM clock DCL. In the receive direction two
cases have to be distinguished depending whether a bus or a point-to-point operation is
programmed (pin X3:BUS).
Bus Operation
The 192-kHz receive bit clock is identical to the transmit bit clock, shifted by 4.6 µs with respect to
the transmit edge. According to CCITT I.430, the receive frame shall be shifted by two bits with
respect to the transmit frame.
Point-to-Point Operation
The 192-kHz receive bit clock is recovered from the receive data stream on the S interface (the
sampling instant for the receive bits is shifted by 3.9 µs with respect to the leading edge of the
derived receive clock). According to CCITT I.430, the receive frame can be shifted by 2-8 bits with
respect to the transmit frame at the NT (LT-S) (Other shifts are allowed by SBC (including 0)).
This operation mode should also be used in extended passive bus applications.
E channel handling
For D-channel access collision resolution, the received D bit is in all cases transmitted as the E bit
in the S-frames.
In addition, in the NT mode the echo bit may be made externally available, thus allowing for the
implementation of a star configuration.
TE Application
The transmit and receive bit clocks are derived, with the help of the DPLL, from the S-interface
receive data strem.
The transmit frame is shifted by two bits with respect to the received frame. The output clocks CP,
DCL and FSC are synchronous to the S-interface timing.
Semiconductor Group
29
Functional Description
Figure 14
Clock System of the SBC
Semiconductor Group
30
Functional Description
D-channel access control
The D-channel access control ensures that only one terminal shall have access to the D channel at
any time. This is achieved through collision detection by each terminal (CCITT I.430). The SBC
MONITORS the received D-echo channel, and, when transmission in the D channel is started,
compares the echo bits to the transmitted D bits.
A mismatch between D bit and D-echo bit means that another terminal is also transmitting and a
collision has taken place. This can only happen if D = 1 and D-echo = 0, since on the S bus a logical
0 overrides a logical 1 (thus the comparison of D echo with D bit is performed only when
D echo = logical 0). The SBC immediately ceases transmission, returns to the D-channel
monitoring state and sends 1’s in the D channel. D-channel access is possible only after x
consecutive 1’s have been received in the echo channel. Depending on the priority class, x can be
either eight or ten. If a terminal has successfully transmitted a complete HDLC frame, x is
automatically increased by 1. X is reset to its initial value of eight (ten) when nine (eleven)
consecutive 1’s are received in the echo channel.
To enable initiating and interrupting HDLC frame transmission in the D channel, the SBC has to
inform the layer-2 controller (ISDN Communication Controller) of the D-channel status — “ready” or
“busy”. For this, bit 20 of the IOM frame, in other words the fourth bit from the right in the MONITOR
channel, is used: see figure 15.
B1
B2
MONITOR
D D
SDO
Figure 15
Position of BUSY Bit in IOM® Frame
Semiconductor Group
B*
31
C/I
T E
Busy = 1
S-Bus D-Channel
not Available
Busy = 0
S-Bus D-Channel
Available
Functional Description
By sending the BUSY bit at 0 to the ISDN Communication Controller in anticipation of the S-bus Dchannel “ready” state, the first valid D bits will emerge from the SBC at exactly the moment an
access is allowed.
D-channel switching (blocked: D = 1, or transparent: D = HDLC) is described by the state diagram
in figure 15a with BUSY bit states “ready” and “busy” as input variables. Figure 15b shows the
status diagram for “ready” and “busy”, with the following variables:
P:
C:
V:
DP:
priority (8 or 10), set by a C/l channel command
number of consecutive ones appearing in the echo channel
V = 1 if: transmitted D bit = received D-echo bit
V = 0 otherwise
priority decrement for priority class P
(P = 8 or 10).
Thus state 1 is the state where a D-channel access may be attempted. The transition “1” - “2” occurs
at the first zero of an opening flag (C = 0: zero observed in D-echo channel, and V = 1: a zero has
actually been transmitted). Transition “i - 0” (i = 1,2,3) occurs at the first monitored zero in the echo
channel when the station is idle (“1” - “0”), or if a collision either within an opening flag (“2” - “0”) or
between the opening and closing flags (“3” - “0”) of an HDLC frame is observed. The successful
transmission of a closing flag (“3” - “0” conditioned by C = 6) must be followed by a decrement in
the priority class (DP = 1 ). DP is reset when 9 or 11 consecutive 1’s are observed (state “1”): cf
CCITT I.430.
Semiconductor Group
32
Functional Description
Figure 16
D-Channel Access Control of the SBC
Semiconductor Group
33
Functional Description
Q Channel
The SBC provides Q-channel support by transmitting a binary “1” in each frame in which a “1” is
received in the FA-bit position of the NT-to-TE frame. Thus interference of FA bits from one TE with
the Q bits in passive bus configurations is avoided.
LT-T Application
As in TE applications, the receive 192-kHz clock is adaptively derived from the S-interface data. The
transmit frame is shifted by two bits with respect to the receive frame.
The SBC provides a 512-kHz clock, CP, derived from the 192-kHz receive line clock with the DPLL.
If necessary, this reference clock may be used to synchronize the central system (“NT2”) clock
generator. The system timing is input over IOM interface bit and frame clocks, DCL and FSC. The
relative position of the S and IOM frame is arbitrary. Moreover, the SBC prevents a slip from
occurring if the wander between the DCL and CP clocks does not exceed a limit (The SBC enables
intermediate storage of: 3xB1, 3xB2 and four D bits, for phase difference and wander absorption). ln
case a wander greater than 24 µs is exceeded (cf CCITT Q.503), a warning is sent twice by the
SBC in the C/l channel (“slip”).
If the analog test loop (TL3) is closed, the 192-kHz line clock is internally derived from DCL:
therefore no slips can occur in this case.
Since only point to point configurations can be realized with the LT-T application, bus availability
indication is not required. However, the D-echo bit is still monitored and interference-free
transmission is indicated by the BUSY bit.
Semiconductor Group
34
Functional Description
2.5
Additional Functions
Test Functions
Test loops
Two kinds of test loops may be closed in the SBC, which depend on the selected mode of operation.
In both test loops, all three channels (B1, B2 and D) are looped back. In a “transparent loop” the
data are also sent forward (in addition to being looped back), whereas in a “non-transparent loop”
the forward data path is blocked (CCITT I.430). These test loops are shown in figure 17.
Figure 17
Test Loops of SBC
Test loop 3 is activated with the C/l channel command Activate Request Loop (ARL). An S interface
is not required since INFO3 is looped back to the receiver. When the receiver has synchronized
itself to this signal, the message “Test Indication’’ (or “Awake Test Indication”) is delivered in the C/l
channel. No signal is transmitted over the S interface.
Test loop 2 is likewise activated over the IOM interface with Activate Request Loop (ARL). No S line
is required. INFO4 is looped back to the receiver and also sent to the S interface. When the receiver
is synchronized, the message “AIU” is sent in the C/l channel. In the test loop mode the S-interface
awake detector is disabled, and echo bits are set to logical “0”.
Semiconductor Group
35
Functional Description
Test Signals
Two kinds of test signals may be sent by the SBC: single pulses and continuous pulses.
The single pulses are of alternating polarity, one S-interface bit period wide, 0.25 ms apart, with a
repetition frequency 2 kHz. Single pulses can be sent in all applications. The corresponding C/l
command in TE, LT-S and LT-T applications is SSZ (Send single zeros). Alternatively, this test
mode can be effected by pulling pin SSZ (pin X2, NT mode only) to logical “0”.
Continuous pulses are likewise of alternating polarity, one S-interface bit period wide, but they are
sent continuously. The repetition frequency is 96 kHz. Continuous pulses may be transmitted in all
applications. This test mode is entered in LT- S, LT-T and TE applications with the C/l command
SCZ. Alternatively, pin SCZ (pin CP, NT mode only) can be pulled to logical “0”.
Special Applications
The mode specific pins X0-3 allow for special applications to be implemented, some of which are
mentioned in the following.
Star Configuration
In NT mode, the SBC transmits the D-bit state over pin X0 (DE). A star configuration may be
implemented by connecting pins X0 of several SBC’s together (open drain with integrated pull up).
With X1 (DEX, D-E-External mirrowing) tied to logical “1”, the SBC transmits the resulting DE (wired
AND for all SBC’s) as the S-interface echo bit. See figure 18.
Figure 18
Star Configuration in NT
Semiconductor Group
36
Functional Description
Use of ECHO
Local communication of terminals connected to an S bus may be implemented by using the auxiliary
ECHO output (pin X2, in TE mode only). The timing of ECHO is identical to that of output SDO:
however, the signal is “1” everywhere except in bit positions 24 and 25 of the IOM frame, where it
is equal to the echo bits received from the S interface. Thus a layer-2 device (e.g. the ISDN
Communication Controller PEB 2070) connected to ECHO is able to receive or “hear” all other
terminals. As a special application, an S-bus local area network may be built using several TE
SBC’s and one NT (or an NT star configuration). Communication in the D and E channel is half
duplex.
Figure 19
Star Configuration in NT
Semiconductor Group
37
Operational Description
3
Operational Description
3.1
General
The internal finite state machine of the SBC controls the activation/deactivation procedures,
switching of test loops and transmission of special pulse patterns. Such actions can be initiated by
signals on the S transmission line (INFO’s) or by control (C/l) codes sent over the IOM interface.
The exchange of control information in the C/l channel is state oriented. This means that a code in
the C/l channel is repeated in every IOM frame until a change is necessary. A new code must be
found in two consecutive IOM frames to be considered valid (double last look criterion).
3.2
Clocking, Reset and Initialization
In LT-T and LT-S applications the IOM interface should be kept active, i.e. the clocks DCL and FSC
are always present. In this case commands in the C/l channel may also be handed over to the SBC
in the “power down” state (state F3 for LT-T/state G1 for LT-S: see figures 24 and 25).
In TE and NT applications the IOM interface can be switched off in the inactive state, reducing
power consumption to a minimum (on the order of 5 mW and 6.5 mW for PEB and PEF,
respectively). In this deactivated state the clock lines are low and the data lines are high.
For the TE case the procedure is shown in figure 20. After detecting the code DIU (Deactivate
Indication Upstream, i.e. from TE to NT/LT-S) from the downstream unit, the SBC responds by
transmitting DID (Deactivate Indication Downstream) during subsequent frames and stops the
timing signals synchronously with the end of the last C/l channel bit of the fourth frame.
Figure 20
Deactivation of the IOM® Interface
Semiconductor Group
38
Operational Description
In NT mode the IOM interface is activated by the upstream unit turning on the clocking signals.
Simultaneously the upstream unit must send the desired command in the C/l channel. In the case
where activation is requested from a terminal, the NT SBC first requests timing on the IOM interface
by pulling SDO to a static low level. The SBC enters the power-up state immediately after timing
has been applied. The clock signals may be switched off after the code Deactivation Indication
Downstream has been sent twice by the upstream unit.
Figure 21
Activation of the IOM® Interface
Semiconductor Group
39
Operational Description
As an alternative to clock activation via SDI, the asynchronous wake-up pin ENCK (X3 in TE mode)
can be grounded. In this case the timing given in figure 22 applies. When ENCK is tied to ground
the IOM-clock pulses are delivered by SBC at all times.
Figure 22
Activation of the IOM® Interface via ENCK (pin X3) in TE Mode (NB: DCL out of scale)
The clock pulses will be enabled again when the SBC recognizes a low level on SDI (command
Timing TIM = “0000”) or when a non-zero level on the S line interface is detected. The clocks are
turned on after approximately 0.5 to 4 ms (dependent on the capacitances on XTAL 1/2).
After the clocks have been enabled this is indicated by the PU code in the C/l channel. The
downstream unit may then insert a valid code in the C/l channel. The continuous supply of timing
signals by the SBC is ensured as long as there is no DIU command in the C/l channel. If timing
signals are no longer required and activation is not yet requested, the downstream unit may indicate
this by sending DIU.
At power up, a reset pulse (RST) should be applied to bring the SBC to a well defined state. This
state is G1 for NT or LT-S mode, and F3 for TE or LT-T mode. The oscillator and energy intensive
analog components are disabled and the S-line awake detector is active after the pulse. All outputs
are in high impedance state during the hardware reset pulse. In TE mode when ENCK is grounded,
however, the SBC will still supply IOM timing during a reset pulse, and the message “Error
Indication” EI is present in the C/l channel. Similarly, in NT mode, activation of pin CP brings the
outputs to low impedance during a reset pulse and the message EI is sent in the C/l channel.
Semiconductor Group
40
Operational Description
3.3
Control of Layer 1
The state diagrams are shown in figures 24 to 26. The activation/deactivation implemented by the
SBC in its different operating modes agrees with the requirements set forth in CCITT recommendations. State identifiers F1-F8 (TE/LT-T) and G1-G4 (NT/LT-S) are in keeping with
CCITT I.430. In the NT mode the four states have been expanded to implement a full handshake
between the ends of the subscriber loop.
In the state diagrams a notation is employed which explicitly specifies the inputs and outputs on the
S interface and in the C/l channel: see figure 23.
Figure 23
Semiconductor Group
41
Operational Description
Commands / Indications and State Diagrams in TE / LT-T
Table 5
Command (upstream)
Abbr.
Code
Remark
Timing
TIM
0000
Activation of all output clocks is requested
Reset
RS
0001
(x)
Send continuous zeros
SCZ
0100
Transmission of pseudo-ternary pulses at
96-kHz frequency (x)
Send single zeros
SSZ
0010
Transmission of pseudo-ternary pulses at
2-kHz frequency (x)
Activate request, set
priority 8
AR8
1000
Activation command, set D-channel priority to 8
Activate request, set
priority 10
AR10
1001
Activation command, set D-channel priority to
10
Activate request loop
ARL
1010
Activation of test loop 3 (x)
Deactivate indication
DIU
1111
IOM interface can be disabled
Indication (downstream)
Abbr.
Code
Remark
Power up
PU
0111
IOM clocking is provided
Deactivate request
DR
0000
Deactivation request by S
Slip detected
SD
0010
Wander is larger than 24 µs peak-to-peak
Disconnected
DIS
0011
Pin CON connected to GND
Error indication
EI
0110
(RST = 0 & ENCK = 0) in TE, or RS
Level detected
RSY
0100
Signal received, receiver not synchronous
Activate request
ARD
1000
Info 2 received
Test indication
TI
1010
Test loop 3 activated or continuous zeros
transmitted
Awake test indication
ATI
1011
Level detected during test loop
Activate indication with
priority class 8
AI 8
1100
Info 4 received, D-channel priority is 8 or 9
Activate indication with
priority class 10
AI 10
1101
Info 4 received, D-channel priority is 10 or 11
Deactivate indication
DID
1111
Clocks will be disabled, (in TE), quiescent state
(x) unconditional commands
Semiconductor Group
42
Operational Description
TE / LT-T Mode
F3 power down
This is the deactivated state of the physical protocol.The receive line awake unit is active except
during a RST pulse. Clocks are disabled if ENCK = 1 (TE mode). The power consumption in this
state is approximately 22 mW when the clock is running, and 4 mW otherwise.
F3 power up
This state is identical to “F3 power down”, except for the C/l output message. The state is invoked
by a C/l command TIM = “0000” (or SDI static low). After the subsequent activation of the clocks the
PU message is outputted. This occurs 0,5 ms to 4 ms after application of TIM, depending on crystal
capacitances. If, however, the SBC is disconnected from the S interface (CON = 0), the C/l
message DIS is outputted.
F3 pend. deact.
The SBC reaches this state after receiving INFO0 (from states F5 to F8) for 16 ms (64 frames). This
time constant is a “flywheel” to prevent accidental deactivation. From this state an activation is only
possible from the line (transition “F3 pend. deact.” to “F5 unsynchronized”). A power down state
may be reached only after receiving DIU.
F4 pend. act.
Activation has been requested from the terminal, INFO1 is transmitted, INFO0 is still received,
“Power Up” is transmitted in the C/l channel. This state is stable: timer T3 (I.430) is to be
implemented in software.
F5 unsynchronized
At the reception of any signal from the NT, the SBC ceases to transmit INFO1 and awaits
identification of INFO2 or INFO4. This state is reached at most 50 s after a signal different from
INFO0 is present at the receiver of the SBC.
F6 synchronized
When the SBC receives an activation signal (INFO2), it responds with INFO3 and waits for normal
frames (INFO4). This state is reached at most 6 ms after an INFO2 arrives at the SBC (when the
oscillator was disabled in “F3 power down”).
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 at most 0,5 ms after reception of INFO4. From state “F3 power
down” with the oscillator disabled, state F7 is reached at most 6 ms after the SBC is directly
activated by INFO4.
F8 lost framing
This is the condition where SBC has lost frame synchronization and is awaiting re-synchronization
by INFO2 or INFO4 or deactivation by INFO0.
Semiconductor Group
43
Operational Description
Unconditional States
Loop3 closed
On Activate Request Loop command, INFO3 is sent by the line transmitter internally to the line
receiver (INFO0 is transmitted to the line). The receiver is not yet synchronized.
Loop3 activated
The receiver is synchronized on INFO3 which is looped back internally from the transmitter. Data
may be sent. The indication “Tl” or”ATI” is output depending whether or not a signal different from
INFO0 is detected on the S interface.
Test mode continuous pulses
Continuous alternating pulses are sent.
Test mode single pulses
Single alternating pulses are sent (2-kHz repetition rate).
Reset state
A software reset (RS) forces the SBC to an idle state where the analog components are disabled
(transmission of INFO0) and the S line awake detector is inactive. Thus activation from the NT is
not possible. Clocks are still supplied (TE mode) and the outputs are in a low impedance state.
Semiconductor Group
44
Operational Description
Figure 24a
State Diagram of TE/LT-T Mode
Semiconductor Group
45
Operational Description
Figure 24b
State Diagram of TE/LT-T Mode: Unconditional Transitions
Semiconductor Group
46
Operational Description
Commands / Indications and State Diagrams in LT-S Mode
Table 3
Command (downstream)
Abbr.
Code
Remark
Deactivate request
DR
0000
(x)
Send continuous zeros
SCZ
0010
Transmission of pseudo-ternary pulses at
96-kHz frequency (x)
Send single zeros
SSZ
0010
Transmission of pseudo-ternary pulses at
2-kHz frequency (x)
Activate request
ARD
1000
Activate request loop
ARL
1010
Activation request for loop 2
Deactivate indication
DID
1111
Deactivation acknowledgement, quiescent
state
Indication (upstream)
Abbr.
Code
Remark
Lost signal level
LSL
0001
No receive signal
Lost framing
RSYU
0100
Receiver is not synchronous
Activate request
ARU
1000
Info 1 received
Activate indication
AIU
1100
Synchronous receiver
Deactivate indication
DIU
1111
Timer (32 ms) expired or info 0 received
(during 16 ms) after deactivation request
(x) unconditional commands
Semiconductor Group
47
Operational Description
LT-S Mode
G1 deactivated
The SBC is not transmitting. No signal detected on the S interface, and no activation command is
received in C/l channel.
G2 synchronized
As a result of an INFO1 detected on the S line or an ARD command, the SBC begins transmitting
INFO2 and waits for reception of INFO3. INFO2 is sent after the awake detector has detected
pulses during 4 ms. The timer to supervise reception of INFO3 is to be implemented in software.
G3 activated
Normal state where INFO4 is transmitted to the S interface. This state is reached less than 2 ms
after an INFO3 first arrives at the SBC receiver. The SBC remains in this state as long as neither a
deactivation or a test mode is requested, nor a reset pulse is issued.
When receiver synchronism is lost, lNFO2 is sent automatically. After reception of INFO3, the
transmitter keeps on sending INFO4. (Version A7 and following)
G4 pend. deact.
This state is triggered by a deactivation request DR. It is an unstable state: indication DIU (state “G4
unackn.”) is issued by the SBC when:
– either INFO0 is received during 16 ms,
– or an internal timer of 32 ms expires.
G4 unacknowleded
Final state after a deactivation request. The SBC remains in this state until a response to DIU (in
other words DID) is issued, without which a new activation is impossible.
Test mode continuous pulses
Continuous alternating pulses are sent.
Test mode single pulses
Single alternating pulses are sent (2-kHz repetition rate).
Semiconductor Group
48
Operational Description
Figure 25
State Diagram of LT-S Mode
Semiconductor Group
49
Operational Description
Commands / Indications and State Diagrams in NT
Table 4
Command (downstream)
Abbr.
Code
Remark
Deactivate request
DR
0000
(x)
Resynchronization of
U-interface
RSYD
0100
Transmission of pseudo-ternary pulses at
96-kHz frequency after loss of synchronism of
the U interface
Activate request
ARD
1000
Transmission of info 2
Activate request loop
ARL
1010
Transmission of info 2, switching of test loop 2
Deactivate indication
DID
1111
Deactivation acknowledgement, quiscent state
Activate indication
AID
1100
Transmission of info 4
Activate indication loop
AIL
1110
Transmission of info 4, switching of test loop 2
Send single zeros
SSZ
0010
Transmission of pseudo-ternary pulses at
2-kHz frequency (x)
Indication (upstream)
Abbr.
Code
Remark
Timing
TIM
0000
SBC requires clock pulses
Lost signal level
LSL
0001
No receive level
Lost framing
RSYU
0100
Receiver is not synchronous
Error indication
EI
0110
RST and SCZ both active
Activate request
ARU
1000
Info 1 received
Activate indication
AIU
1100
Synchronous receiver
Deactivate indication
DIU
1111
Timer (32 ms) expired or info 0 received (during
16 ms) after deactivation request
(x) unconditional commands
Semiconductor Group
50
Operational Description
NT Mode
G1 deactivated
The SBC is not transmitting. No signal is detected on the S/T interface, and no activation command
is received in C/l channel. EI is output as a response to RST, DIU is output in the normal deactivated
state, and TIM is output as a first step when an activation is requested from the S/T interface.
G1 i1 detected
An INFO1 is detected on the S/T interface, translated to an “Activation Request Upstream”
indication in the C/l channel. The SBC is waiting for an ARD command, which normally indicates
that the transmission line upstream (usually a two-wire interface) is synchronized.
G2 pend. act.
As a result of the ARD command, an INFO2 is sent on the S/T interface. INFO3 is not yet received.
G2 synchronized
INFO3 was received, INFO2 continues to be transmitted while the SBC waits for a “switch-through”
command AID from the device upstream.
G3 activated
INFO4 is sent on the S/T interface as a result of the “switch through” command AID: the B and D
channels are transparent. In case of loss of synchronism of the NT receiver, lNFO2 is sent (Version
A7 and following).
Lost framing U
On receiving a RSYD command which usually indicates that synchronization has been lost on the
two-wire interface, the SBC transmits continuous alternating pulses.
G4 pend. deact.
This state is triggered by a deactivation request DR, and is an unstable state. Indication DIU (state
“G4 unackn.”) is issued by the SBC when:
– either INFO0 is received during 16 ms
– or an internal timer of 32 ms expires.
G4 unacknowledged
Final state after a deactivation request. The SBC remains in this state until an “acknowledgment” to
DIU (DID) is issued, without which a new activation is impossible.
Test mode continuous pulses
Continuous alternating pulses are sent.
Test mode single pulses
Single alternating pulses are sent (2-kHz repetition rate).
Semiconductor Group
51
Operational Description
Figure 26
State Diagram of NT Mode
Semiconductor Group
52
Operational Description
Example of Activation / Deactivation
An example of an activation/deactivation of the S interface, with the aforementioned time
relationships, is shown in figure 27, in the case of an SBC in TE and LT-S modes.
Figure 27
Example of Activation / Deactivation
Semiconductor Group
53
Electrical Characteristics
4
Electrical Characteristics
Absolute Maximum Ratings
Parameter
Symbol
Limit Values
Unit
Ambient temperature under bias
PEB 2080
PEF 2080
TA
TA
0 to 70
– 40 to 85
˚C
˚C
Storage temperature
Tstg
– 65 to 125
˚C
Voltage on any pin with respect to ground
VS
– 0.4 to VDD + 0.4 V
V
Power dissipation
PD
1
W
Stresses above those listed here may cause permanent damage to the device. Exposure to
absolute maximum rating conditions for extended periods may effect device reliability.
Line Overload Protection
The maximum input current (under overvoltage conditions) is given as a function of the width of a
rectangular input current pulse (figure 28).
Figure 28
Test Condition for Maximum Input Current
Semiconductor Group
54
Electrical Characteristics
Transmitter Input Current
The destruction limits for negative input signals with Ri ≥ 2 Ω and for positive input signals with
Ri ≥ 200 Ω are given in figure 29.
Figure 29
Receiver Input Current
The destruction limits are given in figure 30.
Ri ≥ 300 Ω.
Figure 30
Semiconductor Group
55
Electrical Characteristics
DC Characteristics
TA = 0 to 70 ˚C;VDD = 5 V 5 %, VSS = 0 V
Parameter
Symbol
Limit Values
min.
max.
Unit
L-input voltage
VIL
– 0.4
0.8
V
H-input voltage
VIH
2.0
VDD
V
Test Condition
+ 0.4
L-output voltage
L-output voltage (SDO)
VOL
VOL1
H-output voltage
H-output voltage
VOH
VOH
V
V
IOL = 2 mA
IOL = 7 mA
V
V
IOH = – 400 µA
IOH = – 100 µA
13
mA
1
mA
PEB 2080; VDD = 5 V
inputs at VSS/VDD
no output loads
15
mA
1.3
mA
0.45
0.45
2.4
VDD
– 0.5
Power supply current operational
power down ICC
Power supply current operational
power down ICC
PEF 2080; VDD = 5 V
inputs at VSS/VDD
no output loads
Input leakage current
ILI
Output leakage current
ILO
Absolute value of output pulse
amplitude (VSX2 - VSX1)
VX
2.03
2.10
2.31
2.39
V
V
RL = 50 Ω 1) 2)
RL = 400 Ω 1) 2)
Transmitter output current
IX
7.5
13.4
mA
RL = 5.6 Ω 1)
Transmitter output
RX
10
kΩ
inactive or during
binary one
80
Ω
during binary zero 3)
RL = 50 Ω
10
impedance
µA
0 V < VIN < VDD to 0 V
0 V < VIN < VDD to 0 V
Receiver output voltage
VSR1
2.35
2.6
V
IO < 5 µA
Receiver threshold voltage
VSR1 - VSR2
VTR
225
375
mV
dependent on peak
level
Notes:
1) Due to the transformer, the load resistance as seen by the circuit is four times RL.
2) The required 20 Ω output impedance is realised by external components.
3) The 80 Ω output impedance is required as external resistor.
Semiconductor Group
56
Electrical Characteristics
Capacitances
TA = – 40 to 85 ˚C,VDD = 5 V ± 5 %, VSS = 0 V, fC = 1 MHz
Parameter
Symbol
Limit Values
min.
Unit
Test Condition
max.
Input capacitance
I/O capacitance
CIN
CIO
7
7
pF
pF
All pins except SR1,2
XTAL1,2
Output capacitance against Vssa
COUT
10
pF
SX1,2
Load capacitance
CLD
50
pF
XTAL1,2
Recommended Oscillator Circuit
Figure 31
The integrated oscillator uses a parallel resonance crystal.
Unmeasured pins returned to ground.
Semiconductor Group
57
Electrical Characteristics
Table 6
Output Stages
Application
TE
TE
TE
LT-T
LT-T
NT
LT-S
LT-S
LT-S
Operation Inverted
of IOM
Mode
Interface
Inverted
Mode
IOM-1
Mode
IOM-2
Mode
or
Invert.
Mode
IOM-1
Mode
IOM-1
Mode
IOM-2
Mode
or
Invert.
Mode
IOM-1
Mode
IOM-1
Mode
M2
M1
M0
0
0
0
0
0
1
0
1
0
0
1
1
0
1
1
1
1
1
1
0
0
1
1
0
1
1
0
DCL
Push/
Pull
Push/
Pull
Push/
Pull
FSC
Push/
Pull
Push/
Pull
Push/
Pull
CP
Push/
Pull
Push/
Pull
Push/
Pull
Push/
Pull
Push/
Pull
X2
Push/
Pull
Push/
Pull
Push/
Pull
X1
Push/
Pull
Push/
Pull
Push/
Pull
X0
Push/
Pull
Push/
Pull
SDO
Push/
Pull
Push/
Pull
Push/
Pull
Push/
Pull
open
drain*
Push/
Pull
open
drain
Push/
Pull
*) with internal pull-up
Semiconductor Group
58
open
drain*
open
drain
Push/
Pull
Push/
Pull
Electrical Characteristics
Table 7
SBC Clock Signals
*Application
TE
TE
LT-T
LT-T
NT
LT-S
LT-S
LT-S
Operation Inverted Inverted IOM-1
of IOM
Mode
Mode
Mode
Interface
IOM-2
Mode
or
Invert.
Mode
IOM-1
Mode
IOM-1
Mode
IOM-2
Mode
or
Invert.
Mode
IOM-1
Mode
IOM-1
Mode
M2
M1
M0
0
0
0
0
1
1
0
1
1
1
1
1
1
0
0
1
1
0
1
1
0
DCL
o:
o:
o:
i:
512 kHz* 512 kHz* 512 kH 4096
1:2
1:2
z*
kHz
2:1
i:
512
kHz
i:
512
kHz
i:
4096
kHz
i:
512
kHz
i:
512
kHz
FSC
o:8 kHz*
o:8 kHz*
o:8
kHz*
i:8 kHz
o:8
kHz*
1:1
i:8 kHz
i:8 kHz i:8 kHz
CP
o:
1536
kHz
3:2
o:
1536
kHz
3:1
o:
1536
kHz
3:2*
o:
512
kHz*
2:1
o:
512
kHz*
2:1
X2
o:
2560
kHz
1:2
o:
1280
kHz
1:2
X1
o:
3840
kHz
1:1
o:
3840
kHz
1:1
0
0
1
TE
0
1
0
o:
192
kHz*
1:1
o:
3840
kHz
1:1
X0
o:
7680
kHz
1:1
o:
7680
kHz
1:1
i:fixed
at 0
i:fixed
at 0
Input and Output Pin Configurations
In TE, LT-T and LT-S IOM-1 modes an integrated pull-up resistor is connected to SDI. For output
pin configurations, see table 6.
*) synchronized to S line
Semiconductor Group
59
Electrical Characteristics
AC Characteristics
TA = 0 to 70 ˚C, VDD = 5 V ± 5 % for PEB 2080
TA = – 40 to 85 ˚C, VDD = 5 V ± 5 % for PEF 2080
The AC testing input/output waveform is shown below.
Figure 32
Input / Output Waveform for AC Test
Jitter
In TE mode, the timing extraction jitter of the SBC conforms to CCITT Recommendation I.430
(– 7 % to + 7 % of the S-interface bit period). In the NT and LT-S applications, the clock input DCL
is used as reference clock to provide the 192-kHz clock for the S line interface. In the case of a
plesiochronous 7.68-MHz clock generated by an oscillator, the clock DCL should have a jitter of less
than 100 ns peak-to-peak. (In the case of a zero input jitter on DCL, SBC generates at most 130 ns
“self-jitter” on S interface.) In the case of a synchronous (fixed divider ratio of 15 between XTAL1
and DCL) 7.68-MHZ clock (input XTAL1), the SBC transfers the input jitter of XTAL1, DCL and FSC
to the S interface. The maximum jitter of the NT/LT-S output is limited to 260 ns peak-to-peak
(CCITT I.430).
Clock Timing
The clocks in the different operating modes are summarized in table 7, with duty ratios. Clock CP
is phase-locked to the receive S signal, and is derived using the internal DPLL and the
7.68 MHz ± 100 ppm crystal (TE and LT-T). A phase tracking of CP with respect to “S” is performed
once in 250 µs. As a consequence of this DPLL tracking, the high state of CP may be either reduced
or extended by one 7.68 MHz period (CP duty ratio 2:2 or 4:2 instead of 3:2) once every 250 µs.
Since DCL and FSC are derived from CP (TE mode), the high state (FSC) or the high or low state
(DCL) may likewise be reduced or extended by the same amount once every 250 µs. (The phase
adjustment may take place either in the sixth, seventh or eighth CP cycle counting from the
beginning of an IOM frame in TE).
The phase relationships of the auxiliary clocks are shown in figure 29.
Semiconductor Group
60
Electrical Characteristics
Figure 33
Phase Relationships of Auxiliary Clocks
Tables 8 to 12 give the timing characteristics of the clock.
Figure 34
Definition of Clock Period and Width
Semiconductor Group
61
Electrical Characteristics
Table 8
XTAL1,2
Parameter
Symbol
Limit Values
min.
Unit
max.
High phase of crystal/clock
tW H
20
ns
Low phase of crystal/clock
tW L
20
ns
Table 9
DCL
Parameter
Symbol
Limit Values
min.
typ.
max.
Unit
Test Condition
(TE) 512 kHz
tPQ
1822
1953
2084
ns
OSC ± 100 ppm
(TE) 512 kHz 2:1
tW HQ
1121
1302
1483
ns
OSC ± 100 ppm
(TE) 512 kHz 2:1
tW LQ
470
651
832
ns
OSC ± 100 ppm
(TE) 512 kHz 1:2
tW HQ
470
651
832
ns
OSC ± 100 ppm
(TE) 512 kHz 1:2
tW LQ
1121
1302
1483
ns
OSC ± 100 ppm
(NT, LT-S, LT-T)
tW HI
90
ns
OSC ± 100 ppm
(NT, LT-S, LT-T)
tW LI
90
ns
OSC ± 100 ppm
Unit
Test Condition
Table 10
CP
Parameter
Symbol
Limit Values
min.
typ.
max.
(TE) 1536 kHz
tPQ
520
651
782
ns
OSC ± 100 ppm
(TE) 1536 kHz
tW HQ
240
391
541
ns
OSC ± 100 ppm
(TE) 1536 kHz
tW LQ
240
260
281
ns
OSC ± 100 ppm
(TE, LT-T)
tR , tF
20
10
ns
CL = 100 pF
CL = 50 pF
(LT-T) 512 kHz
tPQ
1822
1953
2084
ns
OSC ± 100 ppm
(LT-T) 512 kHz
tW HQ
1121
1302
1483
ns
OSC ± 100 ppm
(LT-T) 512 kHz
tW LQ
470
651
832
ns
OSC ± 100 ppm
Semiconductor Group
62
Electrical Characteristics
Table 11
X1
Parameter
Symbol
Limit Values
min.
typ.
Unit
Test Condition
max.
(TE) 3840 kHz
tPQ
– 100 ppm 260
100 ppm
ns
OSC ± 100 ppm
(TE) 3840 kHz
tW HQ
120
130
140
ns
OSC ± 100 ppm
(TE) 3840 kHz
tW LQ
120
130
140
ns
OSC ± 100 ppm
Unit
Test Condition
Table 12
X2
Parameter
Symbol
Limit Values
min.
typ.
max.
(TE) 2560 kHz
tPQ
– 100 ppm 391
100 ppm
ns
OSC ± 100 ppm
(TE) 2560 kHz
tW HQ
110
130
150
ns
OSC ± 100 ppm
(TE) 2560 kHz
tW LQ
250
260
270
ns
OSC ± 100 ppm
(TE) 1280 kHz
tPQ
– 100 ppm 781
100 ppm
ns
OSC ± 100 ppm
(TE) 1280 kHz
tW HQ
250
260
270
ns
OSC ± 100 ppm
(TE) 1280 kHz
tW LQ
511
521
531
ns
OSC ± 100 ppm
Semiconductor Group
63
Electrical Characteristics
CP, DCL and FSC Relationships in IOM® Master Mode
Figure 35
Parameter
Symbol
Limit Values
min.
max.
Unit
Test Condition
Clock delay CP - DCL
tD C
0
50
ns
CL = 100 pF
Clock delay CP - FSC
tF C
0
50
ns
CL = 100 pF
Delay DCL - FSC
tF D
– 20
20
ns
CL = 100 pF
Semiconductor Group
64
Electrical Characteristics
IOM® Interface
Normal Mode
Master Mode (TE)
Figure 36
Parameter
Frame sync delay
Symbol
tF D
Limit Values
Unit
min.
max.
– 20
20
ns
200
ns
CL = 100 pF
IOM output data delay
tI OD
CL = 100 pF
IOM input data setup
tI IS
20
ns
IOM input data hold
tI IH
50
ns
Semiconductor Group
65
Electrical Characteristics
Slave Mode (NT, LT-S, LT-T)
Figure 37
Parameter
Symbol
Limit Values
min.
Unit
max.
Frame sync hold
tF H
30
ns
Frame sync setup
tF S
50
ns
Frame sync high
tF WH
40
ns
Frame sync low
tF WL
2150
ns
IOM data output delay
tI OD
IOM input data setup
tI IS
20
ns
IOM input data hold
tI IH
50
ns
200
ns*)
*) For push-pull output. For open drain output with integrated pull-up resistor, the maximum value is 900 ns.
Semiconductor Group
66
Electrical Characteristics
Inverted Mode
Figure 38
Parameter
Symbol
Frame sync delay
CL = 100 pF
tF SD
IOM output data delay
tI OD
Limit Values
Unit
min.
max.
– 20
20
ns
200
ns
CL = 100 pF
IOM input data setup
tI IS
20
ns
IOM input data hold
tI IH
50
ns
Semiconductor Group
67
Electrical Characteristics
Inverted Mux Mode
Figure 39
Parameter
Symbol
Limit Values
min.
Unit
max.
Frame sync hold
tF H
50
ns
Frame sync setup
tF S
20
ns
Frame sync high
tF WH
124.8
µs
Frame sync low
tF WL
70
IOM data output delay
CL = 150 pF; IOL = 7 mA
tI OD
IOM input data setup
tI IS
20
ns
IOM output data hold
tI IH
50
ns
Semiconductor Group
68
200
ns
200
ns
Electrical Characteristics
Timing of Special Function Pins
RST Characteristics
Parameter
Symbol
Limit Values
min.
Length of active (low) state
tW L
Unit
max.
1
ms
RDY Characteristics
Figure 40
Parameter
Symbol
Limit Values
min.
Unit
max.
Length of low state
tW L
360
µs
Length of high state
tW H
60
µs
Semiconductor Group
69
Electrical Characteristics
DE Characteristics
The form of the DE input/output (pin X0, NT mode) is given by figure 41 for the case of two S
interfaces having a minimum frame delay and a maximum frame delay, respectively.
Figure 41
Star Configuration in NT
The AC characteristics of DE output and input are shown in figure 42 and 43 and table 13.
Semiconductor Group
70
Electrical Characteristics
Figure 42
Timing of DE Output
Figure 43
Timing of DE Input
Table 13
Parameter
Symbol
Limit Values
min.
Unit
max.
µs
DE delay
CL = 100 pF
tDED
DE setup
tDES
3
µs
DE hold
tDEH
0
µs
Semiconductor Group
2
71
Electrical Characteristics
Figure 44
Timing of DE
Semiconductor Group
72
Electrical Characteristics
ECHO Characteristics
The timing of the ECHO output (pin X2, TE mode) is identical with that of output SDO: however, the
signal is “1” everywhere except in bit positions 24 and 25 (“D”-bit positions) of IOM frame, where it
is equal to the E bits received from the S interface.
Adaptive Receiver Characteristics
The integrated receiver uses an adaptively switched threshold detector. The detector controls the
switching of the receiver between two sensitivity levels. The hysteresis characteristics of the
receiver are shown in figure 45.
Figure 45
Switching of the Receiver between High Sensitivity and Low Sensitivity
Semiconductor Group
73
Package Outlines
5
Package Outlines
Plastic Dual-in-Line Package, P-DIP-22
Plastic-Leaded Chip Carrier, P-LCC-28-R (SMD)
SMD = Surface Mounted Device
Semiconductor Group
Dimensions in mm
75
This datasheet has been download from:
www.datasheetcatalog.com
Datasheets for electronics components.