EXAR XR-T6166IP

XR-T6166
...the analog plus
company TM
Codirectional Digital Data
Processor
June 1997–3
APPLICATIONS
FEATURES
CCITT G.703 Compliant 64kbps Codirectional
Interface
Low Power CMOS Technology
All Receiver and Transmitter Inputs and Outputs are
TTL Compatible
Transmitter Inhibits Bipolar Violation Insertion for
Transmission of Alarm Conditions
Alarm Output Indicates Loss of Received Bipolar
Violations
Tolerance of 125µs Variance of Data Transfer
Timing in Both Transmit and Receive Paths
Allows Operation in Plesiochronous Networks
Both Receiver and Transmitter Perform Byte
Insertion or Deletion in Response to Local Clock
Slips and Provide Outputs Indicating Slip Logic
Activity
Performs the Digital and Analog Functions for
a Complete 64kbps Data Adaption Unit (DAU) When
Used With the XR-T6164
GENERAL DESCRIPTION
stream. The receiver, which performs the reverse
operation, decodes the 64kbps data, extracts a clock
signal, and then outputs the data to a 2.048Mbps
time-slot. The XR-T6166 provides features which allow
the repetitions and deletions of both received and
transmitted data as clock skews and transients occur.
These slip occurrences are indicated by byte insertion
and deletion flags. Outputs are also provided for
extracted receive clock and clock recovery circuit loss of
lock.
The XR-T6166 is a CMOS device which contains the
digital circuitry necessary to interface both directions of a
64kbps data stream to 2.048Mbps transmit and receive
PCM time-slots. The XR-T6166 and the companion
XR-T6164 line interface chip together form a CCITT
G.703 compliant 64kbps codirectional interface.
The XR-T6166 contains separate transmit and receive
sections. The transmitter transforms 8 bit serial data from
a 2.048Mbps time-slot into an encoded 64kbps data
ORDERING INFORMATION
Part No.
Package
Operating
Temperature Range
XR-T6166CP
28 Lead 600 Mil PDIP
0°C to +70°C
XR-T6166IP
28 Lead 600 Mil PDIP
–40°C to 85°C
XR-T6166CD
28 Lead 300 Mil JEDEC SOIC
0°C to +70°C
XR-T6166ID
28 Lead 300 Mil JEDEC SOIC
–40°C to 85°C
Rev. 2.02
1990
EXAR Corporation, 48720 Kato Road, Fremont, CA 94538 (510) 668-7000 (510) 668-7010
1
XR-T6166
PCMIN
19
D
TX2MHz
20
TS1T
10
TS2T
12
TTSEL
15
8 Bit Input Register
CLK
Byte
Deletion
8
11
BDT
18
BIT
D
CLK
Q
13
T+R
D
CLK
Q
14
T-R
8 Bit Latch
time-slot
Mux
Load
Byte
Insertion
8
CLK
8 Bit Output Register
Load
Q
Control
Circuitry
TX256kHz
17
Octet
Counter
Violation
Insertion
Coding
Logic
16
ALARMIN
Figure 1. XR-T6166 Transmitter Section Block Diagram
Byte Sync
Detection
CLK
S+R
2
S-R
3
BLS
4
RX2MHz
5
TS1R
23
Violation
Loss
Alarm
1
Data
Decoder
CLK
D
TS2R
24
RTSEL
27
BLANK
6
time-slot
Mux
Register
Select
Logic
Time
Slot
Mux
Q
8 Bit Reg 0
CLK
Q
8 Bit Reg 1
CLK
REG 0 SEL
REG 1 SEL
time-slot
28
PCMOUT
Byte
Insertion
26
BIR
Byte
Deletion
25
BDR
D
128kHz Recovered Clock
RXCK2MHz
9
ALARM
Clock
Recovery
7
22
Figure 2. XR-T6166 Receiver Section Block Diagram
Rev. 2.02
2
RXCKOUT
CS
XR-T6166
PIN CONFIGURATION
ALARM
S+R
S-R
BLS
RX2MHz
BLANK
RXCKOUT
VDD
RXCK2MHz
TS1T
BDT
TS2T
T+R
T-R
1
28
2
27
3
26
4
25
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
ALARM
S+R
S-R
BLS
RX2MHz
BLANK
RXCKOUT
VDD
RXCK2MHz
TS1T
BDT
TS2T
T+R
T-R
PCMOUT
RTSEL
BIR
BDR
TS2R
TS1R
CS
VSS
TX2MHz
PCMIN
BIT
TX256kHz
ALARMIN
TTSEL
28 Lead PDIP (0.600”)
1
28
2
27
3
26
4
25
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
PCMOUT
RTSEL
BIR
BDR
TS2R
TS1R
CS
VSS
TX2MHz
PCMIN
BIT
TX256kHz
ALARMIN
TTSEL
28 Lead SOIC (Jedec, 0.300”)
PIN DESCRIPTION
Pin #
Symbol
Type
Description
1
ALARM
O
Octet Timing Alarm. When active, indicates loss of received bipolar violations that are used
for octet timing. Active high.
2
S+R
I
Positive AMI Data to Receiver. Positive data from the XR-T6164 receive-side. Active low.
3
S-R
I
Negative AMI Data to Receiver. Negative data from the XR-T6164 receive-side. Active low.
4
BLS
I
Byte Locking Supervision. When active, causes blanking of PCMOUT under received
alarm conditions. Active low.
5
RX2MHz
I
Receiver 2.048MHz Clock. Used to clock out PCM data.
6
BLANK
I
PCMOUT Data Blanking. When active, forces PCMOUT data to all ones (AIS). Active high.
7
RXCKOUT
O
128kHz Extracted Clock. Clock recovered from received data.
8
VDD
9
RXCK2MHz
I
2.048MHz Clock. Used by receiver clock recovery circuit.
10
TS1T
I
Transmitter Time-slot 1 Input.
11
BDT
O
Transmitter Byte Deletion Flag. Active when a transmit byte is deleted. Active high.
12
TS2T
I
Transmitter Time-slot 2 Input.
13
T+R
O
Transmit Positive AMI Data Output. Data to XR-T6164 positive transmitter input. Active low.
14
T-R
O
Transmit Negative AMI Data Output. Data to XR-T6164 negative transmitter input. Active
low.
15
TTSEL
I
Transmit Time-slot Select. When high, pin 10 is selected; when low, pin 12 is selected.
16
ALARMIN
I
Alarm Input. When active, inhibits insertion of violations used for octet timing in transmitter
output. Active high.
+5V 10% Power Source.
Rev. 2.02
3
XR-T6166
PIN DESCRIPTION (CONT’D)
Pin #
Symbol
Type
Description
17
TX256kHz
I
Transmitter 256kHz Clock. Used to output 64kbps encoded data.
18
BIT
O
Transmitter Byte Insertion Flag. Active when a transmit byte is repeated. Active high.
19
PCMIN
I
Transmitter PCM Input. Data read from the system PCM bus.
20
TX2MHz
I
Transmitter 2.048MHz Clock. Clocks PCM data in PCMIN.
21
VSS
22
CS
O
Clock Seek. Indicates that clock recovery circuit has loss of lock with received data. Active
high.
23
TS1R
I
Receiver Time-slot 1 Input.
24
TS2R
I
Receiver Time-slot 2 Input.
25
BDR
O
Receiver Byte Deletion Flag. Active when received data byte is deleted. Active high.
26
BIR
O
Receiver Byte Insertion Flag. Active when a received data byte is repeated. Active high.
27
RTSEL
I
Receive Time-slot Select. When high, pin 23 is selected; when low, pin 24 is selected.
28
PCMOUT
O
Received PCM Output Data. Data sent to the system PCM bus.
Ground.
Rev. 2.02
4
XR-T6166
ELECTRICAL CHARACTERISTICS
Test Conditions: VDD = 5V 10%, TA = 25°C, Unless Otherwise Specified
Symbol
Parameter
Min.
Typ.
Max.
Unit
Conditions
DC Electrical Characteristics
VIH
Logic 1
VIL
Logic 0
VDD
Supply
IDD
Supply Current
IIL
Input Leakage
2.4
V
4.5
V
5.5
V
µA
500
VOL
VOH
0.4
Dynamic Supply Current
1
µA
0.4
V
At 1.6mA
mA
At 0.4mA
20
ns
All Outputs
2.4
AC Electrical Characteristics
General
tr, tf
Output Rise/Fall Time
Receiver
tRS
RX2MHz Rising Edge to TS
Rising Edge Set Up Time
0
tRXL100
ns
Figure 3
tRH
RX2MHz Rising Edge to TS
Falling Edge Hold Time
0
tRXL100
ns
Figure 3
10
ns
Figure 3
10
ns
Figure 3
10
ns
Figure 3
tDRS
TS Rising Edge to Leading Edge
of PCMOUT D0 Bit Delay
tDRH
TS Falling Edge to Trailing Edge
of PCMOUT D7 Bit Hold Time
tRXD
RX2MHz Rising Egde to
PCMOUT Bits D1 Through D6
Rising Edge Delay
tPW
PCMOUT Pulse Width
488
ns
Figure 3
tRXH
RX2MHz High Time
244
ns
Figure 3
tRXL
RX2MHz Low Time
244
ns
Figure 3
RX2MHz Period
488
ns
100ppm
tRXCLK
0
Transmitter
tTS
TS Rising Edge to TX2MHz Set
Up Time
20
tTXL100
ns
Figure 5
tTH
TS Falling Edge to TX2MHz Hold
Time
0
tTXL100
ns
Figure 5
tDS
PCMIN Edge to TX2MHz Set Up
Time
100
ns
Figure 5
tDH
PCMIN Edge to TX2MHz Hold
Time
100
ns
Figure 5
tTXH
TX2MHz High Time
244
ns
Figure 5
tTXL
TX2MHz Low Time
244
ns
Figure 5
TX2MHz Period
488
ns
100ppm
tTXCLK
Rev. 2.02
5
XR-T6166
ELECTRICAL CHARACTERISTICS (CONT’D)
Symbol
Parameter
Min.
Typ.
Max.
Unit
Conditions
AC Electrical Characteristics (Cont’d)
Transmitter (Cont’d)
tKXH
TX256kHz High Time
1.95
µs
tKXL
TX256kHz Low Time
1.95
µs
3.9063
µs
tKXCLK
TX256kHz Period
tBDTH
BDT High Time
488
ns
tBITH
BIT High Time
12.5
µs
tALH
ALARMIN High Time
15.6
µs
Specifications are subject to change without notice
ABSOLUTE MAXIMUM RATINGS
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20V
Operating Temperature . . . . . . . . . . . . . 0°C to +70°C
Storage Temperature . . . . . . . . . . . . -65°C to +150°C
Magnetic Supplier Information:
Transpower Technologies, Inc.
24 Highway 28, Suite 202
Crystal Bay, NV 89402-0187
Tel. (702) 831-0140
Fax. (702) 831-3521
Pulse
Telecom Product Group
P.O. Box 12235
San Diego, CA 92112
Tel. (619) 674-8100
Fax. (619) 674-8262
Rev. 2.02
6
XR-T6166
tRS
tRXL
tRXH
tRXCLK
tRH
RX2MHz
tDRS
tDRH
time-slot
tPW
tRXD
PCMOUT
D0
D1
D2
D3
D4
D5
D6
D7
Figure 3. Receive Time-slot Timing
tRCKS
S+R
S-R
tRCKP
RXCKOUT
Figure 4. Extracted Clock Timing
tTS
tTXH
tTXL
tTH
tTXCLK
TX2MHz
time-slot
tDS
tDH
PCMIN
D0
D1
D2
D3
D4
D5
D6
D7
Figure 5. Transmit Time-slot Timing
tKXCLK
tKXH
tKXL
Tr
Tf
VIH
50%
Clock
VIL
VIH
50%
50%
VIL
Figure 6. Clock Timing
Rev. 2.02
7
XR-T6166
seventh and eighth data bits in each word to the same
transmitter output. This function may be inhibited by
setting ALARMIN (pin 16) high to transmit an alarm
condition.
SYSTEM DESCRIPTION
Transmitter
Should skew occur between the TX2MHz and TX256kHz
clocks signals, or during an adjustment of the timing of the
time-slot signal, circuitry is included to delete or repeat
complete words of data. This could happen, for example,
when changing from one time-slot position to another.
Outputs are provided to indicate when a data byte is
inserted or deleted. A byte repetition or insertion occurs
once if no new PCM data is received. The BIT flag (pin 18)
is active during the transmission of inserted data. A byte
repetition just occurs once. If no new PCM data is
received, the T+R and T-R outputs stay high. A byte
deletion occurs when the transmitter receives a new byte
of data before the previous byte is transferred from the
storage latch to the output register. Under this condition,
the stored data is overwritten and the BDT flag (pin 11) is
active.
Figure 1 shows the XR-T6166 transmitter section block
diagram. The transmitter converts eight bit bursts or
octets of 2.048Mbps serial data present in a PCM
time-slot to a coded continuous 64kbps data stream.
During operation, data input is controlled by external
clock and time-slot signals, and the 64kbps data output is
timed by an external 256kHz clock. Since the input and
output rates may not be exactly equal because of slight
clock rate differences, periodic slips can occur.
Therefore, circuitry is included to delete or repeat octets, if
necessary. Transmitter operation is as follows.
PCM data is applied to PCMIN (pin 19), a 2.048MHz local
clock is applied to TX2MHz (pin 20), and a time-slot signal
is applied through the time-slot multiplexer. This
multiplexer allows the transmitter to be hard wired to two
time-slot positions. A time-slot signal is applied to
multiplexer inputs TS1T (pin 10) or TS2T (pin 12), and a
time-slot select logic level is applied to TTSEL (pin 15). A
high level at TTSEL selects TS1T while a low level
enables TS2T. The time-slot is an envelope derived
externally from TX2MHz that covers eight clock pulses.
The rising edge of the time-slot signal should be made to
coincide with the falling edge of TX2MHz. Eight bits of
PCM data are clocked into the transmitter input register
on the rising edge of TX2MHz while the selected time-slot
signal is high. The input register data is then transferred
to a storage latch.
Receiver
Figure 2 shows the block diagram of the XR-T6166
receiver section. The receiver converts coded continuous
64kbps data to eight bit bursts of 2.048Mbps serial data
suitable for insertion in a PCM time-slot. During
operation, data input is timed by a clock that is extracted
from the input signal, while output is controlled by external
locally supplied clock and time-slot signals. Since the
data input and output rates may not be exactly equal,
circuitry is included to delete or repeat eight bit data
blocks, if necessary. Receiver operation is as follows.
Transmission of 64kbps data is controlled by the 256kHz
local clock that is applied to TX256kHz (pin 17). It is not
necessary for this clock to be synchronized with any other
signals that are applied to the transmitter. The output
process begins by transferring data from the storage latch
to the output shift register after transmission of the
previous eight bits of data is complete. Four periods of
TX256kHz are required to encode each data bit. A “logic
0” applied to PCMIN is coded as 0101 while a “logic 1” is
coded as 0011. This data is output on either T+R (pin 13)
or T-R (pin 14) according to the AMI (alternate mark
inversion) coding rule. Note that the T+R and T-R outputs
as well as the corresponding XR-T6164 transmitter inputs
(TX+I/P, TX-I/P) are all active-low. Therefore, a “logic 0” is
coded as a 1010 and a “logic 1” as a 1100 at the bipolar
transmitter output as specified by CCITT G.703.
Transmission of octet timing is performed by feeding the
A line interface chip such as the receive section of the
XR-T6164 converts the encoded bipolar 64kbps signal to
dual-rail active-low logic levels. These signals are
applied to the XR-T6166 receiver S+R (pin 2) and S-R
(pin 3) inputs. A 128kHz clock, which is derived from the
received signal, is used to decode this data, and then to
clock it into one of two storage registers. Two registers
are used so that one may be receiving continuous data at
64kbps while the other is sending eight bit bursts at a
2.048Mbps rate to PCMOUT (pin 28) while the receiver
time-slot signal is high. The time-slot is an envelope
derived externally from RX2MHz (pin 5) that covers eight
clock pulses. The rising edge of the time-slot signal
should be made to coincide with the rising edge of
RX2MHz. Eight bits of PCM data are clocked out of the
receiver register on the rising edge of RX2MHz while the
Rev. 2.02
8
XR-T6166
applied to the BLANK input (pin 6) will also force
PCMOUT to an all-ones state.
time-slot signal is high. A two input multiplexer at the
time-slot input allows the receiver to be hard wired to two
time-slot positions. time-slot signals are applied to TS1R
(pin 23) and TS2R (pin 24) and the active time-slot is
selected by RTSEL (pin 27). A high level applied to
RTSEL selects TS1R and a low level selects TS2R. Data
appearing at PCMOUT is framed by the read time-slot
signal and is guaranteed glitch free.
Slip control logic is included in the receiver to
accommodate rate differences between input and output
data. The 64kbps input rate is determined by the remote
transmitter, while the PCMOUT rate is set by RX2MHz
which is a local clock. If this clock is slow, an octet will be
deleted periodically, while the last octet will be repeated
under fast conditions. Octet timing is maintained during
these operations. Outputs are provided to indicate when
an octet is inserted or deleted. The BIR flag (pin 26) is
high when PCMOUT data is repeated, and the BDR flag
(pin 25) is high when the receiver deletes an octet.
Recovery of the 128kHz timing signal is performed by a
variable length counter which is clocked by the 2.048MHz
signal applied to RXCK2MHz (pin 9). This clock is not
required to be synchronized with any other signals that
are applied to the XR-T6166. However, the RX2MHz
clock may also be used for this function. Positive input
data transitions are used to synchronize this counter with
the data. If synchronization is lost, the counter length is
shortened, and the clock recovery circuit enters a seek
mode until a transition is found. This mode is identified by
a high level at the CS output (pin 22). The extracted
128kHz signal is available at RXCKOUT (pin 7).
APPLICATION INFORMATION
64kbps Codirectional Interface
Figure 7 shows a codirectional interface circuit using the
XR-T6166 with the XR-T6164 line interface. The
XR-T6164 first converts the bipolar 64kbps transmit and
receive signals to active-low TTL compatible data
required by the XR-T6166. The XR-T6166 then performs
the digital functions that are necessary to interface this
64kbps continuous data to a 2.048Mbps PCM time-slot.
The 64kbps signals that have been attenuated and
distorted
by
the
twisted
pair
cable
are
transformer-coupled to the line side of the XR-T6164 as
shown on the left side of Figure 7. A suggested
transformer for both the input and output applications is
the pulse type PE-65535.
Octet timing ensures that bit grouping is maintained when
the data is converted from a 64kbps continuous stream to
eight bit 2.048Mbps bursts. Bipolar violations are used to
identify the last bit in each eight bit octet. In the absence of
these violations, for example when receiving a
transmitted alarm condition (transmitter ALARMIN is
high), the circuit will continue to operate in
synchronization with respect to the last received violation.
During this time, the data present at PCMOUT is still
correct as long as synchronization based on the last
received violation is still valid, and the BLS input (pin 4) is
held high. However, if BLS is low and an octet timing
violation is not received, receiver output data is blanked
by forcing PCMOUT to a high level. Also, if eight
successive octet timing violations are not received, the
ALARM output (pin 1) goes to a high level. A high level
The right side of Figure 7 shows the XR-T6164 LOS (Loss
of Signal) output and the XR-T6166 digital inputs and
outputs. All of these pins are TTL compatible. Please
refer to the Pin Description section of this data sheet for
detailed information about each signal.
Rev. 2.02
9
XR-T6166
T6164 LOS Output
+5V
+5V
XR-T6166
8
PCMOUT
VDD
BIR
0.1µF
0.1µF
BDR
RXCKOUT
0.1µF
64kbps Data
To Line
TIP
16
1:2
RX+I/P
480
1
RING
2
PE-65535 0.1µF
TTI-17147
64kbps Data
To Line
TIP
14
RX-I/P
9
V
13 15
V
T
C C
C
C C
M
D A
C
O
N
3
R
12
X S+R
A
L
5
A
R S-R
M
CS
Receive
Side
2
3
BLS
RX2MHz
S+R
TS1R
TS2R
S-R
RTSEL
I/P BIAS
BLANK
PEAK CAP
0.1µF
RXCK2MHz
BDT
RING
PE-65535
TTI-17147
300
300
1
28
26
25
7
22
4
5
Loss of TX Sync
Data to PCM Bus
Byte Repeat Flag
Byte Delete Flag
Recovered CLK
CLK Seek Flag
Blank O/P for Alarm
2.048MHz Clock
23
time-slot 1
24
27
time-slot 2
time-slot Select
6
9
Forces All Ones
2.048MHz Clock
XR-T6164
+5V
1:2
ALARM
10
8
TX+O/P
TX-O/P
TX+I/P
G
N
D
D
G
N
D
A
TX-I/P
11
6
13
14
T+R
T-R
0.1µF
4
BIT
Transmit
Side
PCMIN
TX2MHz
TS1T
TS2T
7
21
VSS
TTSEL
TX256kHz
ALARMIN
Figure 7. Typical Codirectional Application Circuit
Rev. 2.02
10
11
18
19
20
10
12
15
17
16
Byte Delete Flag
Byte Insert Flag
Data from PCM Bus
2.048MHz Clock
time-slot 1
time-slot 2
time-slot Select
256kHz Clock
Inhibit Violations
XR-T6166
Step 2 - A binary 1 is coded as a 1100.
Transmitter Code Conversion
Step 3 - A binary 0 is coded as a 1010.
Figure 8 shows the transmitter code conversion process
that CCITT G.703 specifies for a 64kbps codirectional
interface.
Step 4 - The binary signal is converted into a three-level
signal by alternating the polarity of consecutive blocks.
Step 5 - The alternation in polarity of the blocks is violated
every eighth block. The violation block marks the last bit
in an octet.
Step 1 - A 64kbps bit period is divided into four unit
intervals.
Bit Number
64kbps data
7
8
1
2
3
4
5
6
7
8
1
1
0
0
1
0
0
1
1
1
0
1
Steps 1-3
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
ÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌÌ
Step 4
Step 5
Violation
Violation
Octel Timing
Figure 8. Transmitter Code Conversion for a 64kbps Bipolar Line Signal
Rev. 2.02
11
XR-T6166
Codirectional Interface Pulse Masks
0.1 0.1
0.5
0
Ì
Ì
Ì
Ì
Ì
Ì
Ì
Ì
is for the pulse measured at the XR-T6164 transmitter
output (application circuit shown in Figure 5) when
terminated with a 120Ω resistor.
3.12µs
(3.9 -0.78)
3.51µs
(3.9 -0.39)
3.9µs
0.2
0.1 0.1
2.0
V
1.0
2.0
Figure 9 and Figure 10 show the CCITT G.703 64kbps
codirectional interface pulse masks for single and double
pulses respectively of either polarity. Note that this mask
4.29µs
(3.9 + 0.39)
6.5µs
(3.9 + 2.6)
7.8µs
(3.9 + 3.9)
0
0.1 0.1
0.5
ÌÌ
Ì
ÌÌ
Ì
ÌÌ
7.02µs
(7.8 - 0.78)
7.41µs
(7.8 - 0.39)
7.8µs
0.2
2.0
2.0
V
1.0
0.1 0.1
Figure 9. Mask for a Single Pulse
8.19µs
(7.8 + 0.39)
10.4µs
(7.8 + 2.6)
11.7µs
(7.8 + 3.9)
Figure 10. Mask for a Double Pulse
Rev. 2.02
12
XR-T6166
28 LEAD PLASTIC DUAL-IN-LINE
(600 MIL PDIP)
Rev. 1.00
28
15
E1
1
14
E
D
Seating
Plane
A2
A
L
A1
α
C
B
B1
e
MILLIMETERS
INCHES
SYMBOL
eA
eB
MIN
MAX
MIN
A
0.160
0.250
4.06
6.35
A1
0.015
0.070
0.38
1.78
A2
0.125
0.195
3.18
4.95
B
0.014
0.024
0.36
0.56
B1
0.030
0.070
0.76
1.78
C
0.008
0.014
0.20
0.38
D
1.380
1.565
35.05
39.75
E
0.600
0.625
15.24
15.88
E1
0.485
0.580
12.32
14.73
e
eA
0.100 BSC
0.600 BSC
MAX
2.54 BSC
15.24 BSC
eB
0.600
0.700
15.24
17.78
L
0.115
0.200
2.92
5.08
α
0°
15°
0°
Note: The control dimension is the inch column
15°
Rev. 2.02
13
XR-T6166
28 LEAD SMALL OUTLINE
(300 MIL JEDEC SOIC)
D
28
15
E
H
14
C
A
Seating
Plane
B
e
A1
L
INCHES
SYMBOL
MILLIMETERS
MIN
MAX
MIN
A
0.093
0.104
2.35
2.65
A1
0.004
0.012
0.10
0.30
B
0.013
0.020
0.33
0.51
C
0.009
0.013
0.23
0.32
D
0.697
0.713
17.70
18.10
E
0.291
0.299
7.40
7.60
e
0.050 BSC
MAX
1.27 BSC
H
0.394
0.419
10.00
10.65
L
0.016
0.050
0.40
1.27
Rev. 2.02
14
XR-T6166
Notes
Rev. 2.02
15
XR-T6166
NOTICE
EXAR Corporation reserves the right to make changes to the products contained in this publication in order to improve design, performance or reliability. EXAR Corporation assumes no responsibility for the use of any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are
free of patent infringement. Charts and schedules contains herein are only for illustration purposes and may vary
depending upon a user’s specific application. While the information in this publication has been carefully checked;
no responsibility, however, is assumed for inaccuracies.
EXAR Corporation does not recommend the use of any of its products in life support applications where the failure or
malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly
affect its safety or effectiveness. Products are not authorized for use in such applications unless EXAR Corporation
receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized; (b) the
user assumes all such risks; (c) potential liability of EXAR Corporation is adequately protected under the circumstances.
Copyright 1990 EXAR Corporation
Datasheet June 1997
Reproduction, in part or whole, without the prior written consent of EXAR Corporation is prohibited.
Rev. 2.02
16