Download SP319

®
SP319
10Mbps, +5V-Only V.35 Interface
with RS-232 (V.28) Control Lines
■
■
■
■
■
■
■
■
■
10Mbps V.35 Data Throughput
+5V-Only, Single Supply Operation
3 Drivers, 3 Receivers – V.35
4 Drivers, 4 Receivers – RS-232
Improved V.35 Receiver Propagation
Delays
No External V.35 Termination
Resistors Required
Termination Disable for V.35
80-pin MQFP Surface Mount Packaging
Pin Compatible with SP320
Now Available in Lead Free Packaging
DESCRIPTION
The SP319 is a complete V.35 interface transceiver offering 3 drivers and 3 receivers for
V.35, and 4 drivers and 4 receivers for RS-232 (V.28). A Sipex patented charge pump allows
+5V only low power operation. RS-232 drivers and receivers are specified to operate at 120kbps,
all V.35 drivers and receivers operate up to 10Mbps.
www.BDTIC.com/EXAR
Typical Applications Circuit
Pinout
80 R1OUT
79 RCOUT3
78 R2OUT
77 RCB3
76 RCA3
75 ENT
74 NC
73 VCC
72 GND
71 RCB1
70 RCA1
69 NC
68 R2IN
67 NC
66 R1IN
65 DRB3
64 GND
63 DRA3
62 VCC
61 DRA1
+5V
25, 33, 41, 62, 73
26
+
C1+
+
30 C128 C2+
0.1µF
+5V
31
VCC
VDD
SP319
VSS
0.1µF
27
+
32
0.1µF
+
C2-
RCOUT1 1
NC 2
TS000 3
NC 4
NC 5
TTEN 6
RTEN 7
NC 8
ENV35 9
NC 10
NC 11
NC 12
T1IN 13
DRIN1 14
DRIN3 15
T2IN 16
T3IN 17
NC 18
R3OUT 19
RCOUT2 20
3 TS000
75 ENT
9 ENV35
Vcc
RCOUT 1
61 DRA1
100Ω
RCB1 71
RCA2 37
RCOUT2 20
Vcc
Vcc
100Ω
Vcc
5kΩ
Vcc
5kΩ
Vcc
22 DRIN2
400kΩ
R4OUT 21
51 T4OUT
SP319
5kΩ
R4IN 39
42 DRA2
5kΩ
Vcc
RCA3 76
400kΩ
RCOUT3 79
47 T3OUT
24 T4IN
400kΩ
R3IN 35
R3OUT 19
54 T2OUT
17 T3IN
400kΩ
R2IN 68
58 T1OUT
16 T2IN
400kΩ
R1IN 66
R2OUT 78
59 DRB1
13 T1IN
400kΩ
RCB2 38
R1OUT 80
14 DRIN1
400kΩ
RCA1 70
60 GND
59 DRB1
58 T1OUT
57 NC
56 NC
55 NC
54 T2OUT
53 NC
52 NC
51 T4OUT
50 NC
49 NC
48 NC
47 T3OUT
46 NC
45 NC
44 DRB2
43 GND
42 DRA2
41 VCC
44 DRB2
23 STEN
ROUT4 21
DRIN2 22
STEN 23
T4IN 24
VCC 25
C1+ 26
VDD 27
C2+ 28
GND 29
C1- 30
C2- 31
VSS 32
VCC 33
GND 34
R3IN 35
NC 36
RCA2 37
RCB2 38
R4IN 39
NC 40
0.1µF
15 DRIN3
63 DRA3
100Ω
65 DRB3
6 TTEN
RTEN 7
RCB3 77
www.BDTIC.com/Exar/
29, 34, 43, 60, 64, 72
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
1
Copyright © 2006 Sipex Corp.
ABSOLUTE MAXIMUM RATINGS
These are stress ratings only and functional operation of the device at
these ratings or any other above those indicated in the operation
sections of the specifications below is not implied. Exposure to absolute
maximum rating conditions for extended periods of time may affect
reliability.
VCC.....................................................................................................+7V
Input Voltages
Logic........................................................-0.3V to (VCC+0.5V)
Drivers..................................................-0.3V to (VCC+0.5V)
Receivers..................................................±30V at ≤100mA
Output Voltages
Logic........................................................-0.3V to (VCC+0.5V)
Drivers.......................................................................±14V
Receivers..............................................-0.3V to (VCC+0.5V)
Storage Temperature.......................................................-65˚C to +150˚C
Power Dissipation per Package
80-pin QFP (derate 18.3mW/oC above +70oC)..........................1500mW
ELECTRICAL SPECIFICATIONS
TAMB = TMIN to TMAX and VCC = 5V±5% unless otherwise noted.
PARAMETER
MIN.
V.35 DRIVER
TTL Input Levels
VIL
VIH
TYP.
MAX.
+0.44
50
135
Voltage Output Offset
-0.6
+0.55
100
150
CONDITIONS
0.8
Volts
Volts
+1.2
+0.66
150
165
Volts
Volts
Ohms
Ohms
+0.6
Volts
Refer to Figure 1
RL=100Ω from A to B; Figure 2
Figure 4
Measured from A=B to Gnd,
VOUT=-2V to +2V; Figure 5; TAMB = +25oC
VOffset={[|VA|+|VB|]/2}; Figure 3
ns
Mbps
TAMB = +25oC for all AC parameters
10% to 90%; Figure 6
VDIFF OUT= 0.55V+20% ; Figure 9
2.0
Voltage Outputs
Open Circuit Voltage
Differential Outputs
Source Impedance
Short Circuit Impedance
UNITS
www.BDTIC.com/EXAR
AC Characteristics
Transition Time
Maximum Transmission Rate
Propagation Delay
tPHL
40
10
tPLH
V.35 RECEIVER
TTL Output Levels
VOL
VOH
Receiver Inputs
Differential Input
Threshold
Input Impedance
Short Circuit Impedance
AC Characteristics
Maximum Transmission Rate
Propagation Delay
tPHL
tPLH
80
100
ns
80
100
ns
Measured from 1.5V of VIN
to 50% of VOUT; Figure 9, 10
Measured from 1.5V of VIN
to 50% of VOUT; Figure 9, 10
0.4
Volts
Volts
IOUT=-3.2mA
IOUT=1.0mA
+0.3
110
165
Volts
Ohms
Ohms
2.4
-0.3
90
135
100
150
10
Mbps
60
80
ns
60
80
ns
Figure 7
Measured from A=B to Gnd
VIN=-2V to +2V; Figure 8; TAMB = +25oC
TAMB = +25oC for all AC parameters
VIN = +0.55V +20%; Figure 9
Measured from 50% of VIN to
1.5V of ROUT; Figure 9, 11
Measured from 50% of VIN to
1.5V of ROUT; Figure 9, 11
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
2
Copyright © 2006 Sipex Corp.
ELECTRICAL SPECIFICATIONS (CONTINUED)
TAMB = TMIN to TMAX and VCC = 5V±5% unless otherwise noted.
PARAMETER
RS-232 DRIVER
TTL Input Levels
VIL
VIH
MIN.
TYP.
MAX.
UNITS
0.8
Volts
Volts
+15.0
-5.0
+15
+100
Volts
Volts
Volts
mA
Ohms
RL= 3kΩ to Gnd; Figure 13
RL= 3kΩ to Gnd; Figure 13
RL= ∞; Figure 12
RL= Gnd; Figure 15
VCC= 0V; VOUT= +2V; Figure 16
30
V/µs
Figure 14
kbps
RL= 3kΩ, CL= 2500pF
2.0
Voltage Outputs
High Level Output
Low Level Output
Open Circuit Output
Short Circuit Current
Power Off Impedance
+5.0
-15.0
-15
-100
300
AC Characteristics
Slew Rate
Maximum Transmission Rate
120
Transition Time
Propagation Delay
tPHL
tPLH
RS-232 RECEIVER
TTL Output Levels
VOL
VOH
CONDITIONS
1.56
µs
Rise/fall time, between +3V
RL= 3kΩ, CL= 2500pF; Figure 17
2
8
µs
2
8
µs
RL= 3kΩ, CL= 2500pF; From 1.5V
of TIN to 50% of VOUT
RL= 3kΩ, CL= 2500pF; From 1.5V
of TIN to 50% of VOUT
0.4
Volts
Volts
IOUT = -3.2mA
IOUT = 1.0mA
Volts
Volts
Volts
Volts
Volts
kΩ
VCC= 5V; TA= +25˚C
Figure 19
VIN= +15V; Figure 18
2.4
www.BDTIC.com/EXAR
Receiver Input
Input Voltage Range
High Threshold
Low Threshold
Hysteresis
Receiver Input Circuit Bias
Input Impedance
AC Characteristics
Maximum Transmission Rate
Propagation Delay
tPHL
tPLH
-15
0.8
0.2
1.7
1.2
0.5
3
5
+15
3.0
1
+2.0
7
120
kbps
0.1
0.1
1
1
µs
µs
From 50% of RIN to 1.5V of ROUT
From 50% of RIN to 1.5V of ROUT
POWER REQUIREMENTS
No Load VCC Supply Current
Full Load VCC Supply Current
40
60
70
80
mA
mA
Shutdown Current
1.5
10
mA
No load; VCC= 5.0V; TA= 25˚C
RS-232 drivers RL= 3kΩ to Gnd;
DC Input
V.35 drivers RL= 100Ω from A to B;
DC Input
TS000 = ENV35 = 0V
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
3
Copyright © 2006 Sipex Corp.
A
A
50Ω
V
OCA
VT
VOC
3.9kΩ
50Ω
V
OCB
B
VOS
B
C
C
Figure 2. V.35 Driver Output Test Terminated Voltage
Figure 1. V.11 and V.35 Driver Output Open-Circuit
Voltage
V1
A
A
50Ω
24kHz, 550mVp-p
Sine Wave
50Ω
V2
VT
50Ω
www.BDTIC.com/EXAR
VOS
B
B
C
C
Figure 3. V.35 Driver Output Offset Voltage
Figure 4. V.35 Driver Output Source Impedance
A
A
50Ω
Oscilloscope
B
50Ω
ISC
B
50Ω
±2V
C
C
www.BDTIC.com/Exar/
Figure 6. V.35 Driver Output Rise/Fall Time
Figure 5. V.35 Driver Output Short-Circuit Impedance
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
4
Copyright © 2006 Sipex Corp.
A
V1
A
50Ω
24kHz, 550mVp-p
Sine Wave
V2
Isc
B
B
±2V
C
C
Figure 7. V.35 Receiver Input Source Impedance
CL1
TIN
A
A
B
B
Figure 8. V.35 Receiver Input Short-Circuit Impedance
ROUT
CL2
fIN (50% Duty Cycle, 2.5VP-P)
15pF
www.BDTIC.com/EXAR
Figure 9. Driver/Receiver Timing Test Circuit
f > 10MHz; tR < 10ns; tF < 10ns
DRIVER
INPUT
DRIVER
OUTPUT
+3V
1.5V
1.5V
0V
A
tPLH
VO 1/2VO
1/2VO
B
tDPLH
DIFFERENTIAL
OUTPUT
VB – VA
tPHL
VO+
0V
VO–
tDPHL
tR
tF
tSKEW = | tDPLH - tDPHL |
www.BDTIC.com/Exar/
Figure 10. Driver Propagation Delays
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
5
Copyright © 2006 Sipex Corp.
f > 10MHz; tR < 10ns; tF < 10ns
V0D2+
0V
A–B
0V
INPUT
V0D2–
OUTPUT
VOH
(VOH - VOL)/2
(VOH - VOL)/2
RECEIVER OUT
VOL
tPLH
tPHL
tSKEW = | tPHL - tPLH |
Figure 11. Receiver Propagation Delays
A
A
www.BDTIC.com/EXAR
VOC
3kΩ
VT
C
C
Figure 12. V.28 Driver Output Open Circuit Voltage
Figure 13. V.28 Driver Output Loaded Voltage
A
A
7kΩ
VT
Isc
Oscilloscope
C
C
Scope used for slew rate
measurement.
www.BDTIC.com/Exar/
Figure 15. V.28 Driver Output Short-Circuit Current
Figure 14. V.28 Driver Output Slew Rate
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
6
Copyright © 2006 Sipex Corp.
VCC = 0V
A
A
Ix
3kΩ
2500pF
Oscilloscope
±2V
C
C
Figure 17. V.28 Driver Output Rise/Fall Times
Figure 16. V.28 Driver Output Power-Off Impedance
A
A
Iia
±15V
www.BDTIC.com/EXAR
C
C
Figure 18. V.28 Receiver Input Impedance
Figure 19. V.28 Receiver Input Open Circuit Bias
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
Voc
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
7
Copyright © 2006 Sipex Corp.
All of the V.35 receivers can operate at data
rates as high as 10Mbps. The sensitivity of the
V.35 receiver inputs is +300mV.
THEORY OF OPERATION
The SP319 is a single chip +5V-only serial
transceiver that supports all the signals necessary
to implement a full V.35 interface. Three V.35
drivers and three V.35 receivers make up the
clock and data signals. Four RS-232 (V.28)
drivers and four RS-232 (V.28) receivers are
used for control line signals for the interface.
RS-232 (V.28) Drivers
The RS-232 drivers are inverting transmitters,
which accept either TTL or CMOS inputs and
output the RS-232 signals with an inverted sense
relative to the input logic levels. Typically, the
RS-232 output voltage swing is +9V with no
load, and +5V minimum with full load. The
transmitter outputs are protected against infinite
short-circuits to ground without degradation in
reliability.
V.35 Drivers
The V.35 drivers are +5V-only, low power
voltage output transmitters. The drivers do not
require any external resistor networks, and will
meet the following requirements:
In the power off state, the output impedance of
the RS-232 drivers will be greater than 300Ω
over a +2V range. Should the input of a driver be
left open, an internal 400kΩ pullup resistor to
VCC forces the input high, thus committing the
output to a low state. The slew rate of the
transmitter output is internally limited to a
maximum of 30V/µs in order to meet the EIA
standards. The RS-232 drivers are rated for
120kbps data rates.
1. Source impedance in the range of 50Ω to
150Ω.
2. Resistance between short-circuited terminals
and ground is 150Ω +15Ω.
3. When terminated with a 100Ω resistive load
the terminal to terminal voltage will be 0.55
Volts ±20% so that the A terminal is positive to
the B terminal when binary 0 is transmitted, and
the conditions are reversed to transmit binary 1.
RS-232 (V.28) Receivers
The RS-232 receivers convert RS-232 input
signals to inverted TTL signals. Each of the four
receivers features 500mV of hysteresis margin
to minimize the effects of noisy transmission
lines. The inputs also have a 5kΩ resistor to
ground; in an open circuit situation the input of
the receiver will be forced low, committing the
output to a logic high state. The input resistance
will maintain 3kΩ-7kΩ over a +15V range.
The maximum operating voltage range for the
receiver is +30V, under these conditions the
input current to the receiver must be limited to
less than 100mA. The RS-232 receivers can
operate to beyond 120kbps.
www.BDTIC.com/EXAR
4. The arithmetic mean of the voltage of the A
terminal with respect to ground, and the B
terminal with respect to ground will not exceed
0.6 Volts when terminated as in 3 above.
The V.35 drivers can operate at data rates as
high as 10Mbps. The driver outputs are protected against short-circuits between the A and
B outputs and short circuits to ground.
Two of the V.35 drivers, DRIN2 and DRIN3 are
equipped with enable control lines. When the
enable pins are high the driver outputs are
disabled, the output impedance of a disabled
driver will nominally be 300Ω. When the enable
pins are low, the drivers are active.
CHARGE PUMP
The charge pump is a Sipex patented design
(U.S. 5,306,954) that uses an innovative
approach. The charge pump, with four external
capacitors, uses a four-phase voltage shifting
technique to attain a symmetrical +10V power
supply. The capacitors can be as low as
0.1µF with a 16 Volt rating. Either polarized
or non-polarized capacitors can be used.
V.35 Receivers
The V.35 receivers are +5V only, low power
differential receivers which meet the following
requirements:
1. Input impedance in the range of 100Ω +10Ω.
2. Resistance to ground of 150Ω +15Ω,
measured from short-circuited terminals.
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
8
Copyright © 2006 Sipex Corp.
Since both V+ and V- are separately generated
from Vcc in a no load condition, V+and V- will
be symmetrical. Older charge pump approaches
that generate V- from V+ will show a decrease
in the magnitude of V- compared to V+ due to
the inherent inefficiencies in design.
+10V
a) C2+
The clock rate for the charge pump typically
operates at 15kHz with 0.1µF, 16V external
capacitors.
GND
GND
b) C2–
Shutdown Mode
The SP319 can be put into a low power
shutdown mode by bringing both TS000 (pin 3)
and ENV35 (pin 9) low. In shutdown mode,
SP319 draws less than 2mA. For normal
operation, both pins should be connected to +5V.
–10V
Figure 20. Charge Pump Waveforms
Figure 20 shows the waveforms on the positive
and negative sides of capacitor C2 respectively.
A free-running oscillator controls the four
phases of the voltage shifting. A description
of each phase follows.
Termination Enable
The SP319 includes a termination enable pin
that connects or disconnects the receiver input
termination circuitry. A TTL logic LOW at ENT
(pin 75) will connect the "Y" termination network
to the V.35 receiver inputs. A TTL logic HIGH
at ENT (pin 75) will disconnect the "Y" termination network and the receivers will operate as
V.11 compliant receivers. The ENT pin has an
internal pull-down resistor so that a floating
input will enable the termination network. The
SP319 is compatible with the SP320 since pin 75
on the SP320 is designated as a no connect.
Phase 1: VSS Charge Storage (Figure 21)
During this phase of the clock cycle, the positive
side of capacitors C1 and C2 are charged to
+5V. C1+ is switched to ground and the charge
on C1- is transferred to C2-. Since C2+ is
connected to +5V, the voltage potential across
capacitor C2 becomes 10V.
www.BDTIC.com/EXAR
Phase 2: VSS Transfer (Figure 22)
Phase two of the clock connects the negative
terminal of C2 to the Vss storage capacitor
and the positive terminal of C2 to ground,
and transfers the generated -10V to C3.
Simultaneously, the positive side of capacitor
C1 is switched to +5V and the negative side
is connected to ground.
External Power Supplies
For applications where separate external
supplies can be applied at the V+ and V- pins.
The value of the external supply voltages should
not exceed +10V. It is critical the external power
supplies provide a power supply sequence of :
+10V, +5V, and then -10V.
Phase 3: VDD Charge Storage (Figure 23)
The third phase of the clock is identical to
the first phase - the transferred charge on C1
produces -5V on the negative terminal of C1,
which is applied to the negative side of
capacitor C2. Since C2+ is at +5V, the voltage
potential across C2 is +10V.
Applications Information
The SP319 is a single chip device that can
implement a complete V.35 interface. Three (3)
V.35 drivers and three (3) V.35 receivers are
used for clock and data signals and four (4)
RS-232 (V.28) drivers and four (4) RS-232
(V.28) receivers can be used for the control
signals of the interface. Figures 25 to 28
show the SP319 configured in DTE and DCE
applications along with an ISO-2593 pin out.
Phase 4: VDD Transfer (Figure 24)
The fourth phase of the clock connects the
negative terminal of C2 to ground and transfers
the generated +10V across C2 to C4, the Vdd
storage capacitor. The positive side of capacitor
C1 is switched to +5V and the negative side is
connected to ground, and the cycle begins again.
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
9
Copyright © 2006 Sipex Corp.
VCC = +5V
VCC = +5V
C4
+10V
+
C1
+
C2
–
–
+
–
VDD Storage Capacitor
+
C1
VSS Storage Capacitor
C3
+
–
–
+
VDD Storage Capacitor
+
C2
–
–5V
Figure 21. Charge Pump Phase 1
–
VSS Storage Capacitor
C3
–5V
Figure 22. Charge Pump Phase 2
VCC = +5V
VCC = +5V
C4
+
C1
C4
+5V
–
+
+
C2
–
–
–
+
VDD Storage Capacitor
C1
VSS Storage Capacitor
C3
–10V
+
C2
–
–5V
Figure 23. Charge Pump Phase 3
28
C2+
0.1µF
25
31
C2-
VCC
–
DRIN3
15
–
+
0.1µF
27 26 30
VDD C1+ C1- 32
VSS
28
0.1µF
C2+
0.1µF
31
C2-
25
VCC
1N5819
0.1µF
27 26 30
TxD (103)
P
S
TxC (113)
U
U
W
W
A
RCOUT1
1
A
79
TxCC (114)
Y
AA
RCOUT1
T
R
T2IN
16
H
T1IN
13
C
T3IN
17
N
T4IN
24
L
R2OUT
78
E
AA
F
R4OUT
21
NN
X
V
RxD (104)
T
R
DTR (108)
RTS (105)
RL (140)
LL (141)
DSR (107)
CTS (106)
D
R3OUT
19
Y
RxC (115)
X
V
R1OUT
80
DCD (109)
TM (142)
B
29, 34, 43, 60, 64, 72
RCOUT2
20
RCOUT3
RCOUT2
20
1
0.1µF
VDD C1+ C1- 32
VSS
SP319CF (DCE)
DRIN2
22
79
VSS Storage Capacitor
C3
–5V
www.BDTIC.com/EXAR
RCOUT3
VDD Storage Capacitor
+5V
1N5819
0.1µF
P
S
14
–
Figure 24. Charge Pump Phase 4
SP319CF (DTE)
DRIN1
+
+
+5V
0.1µF
C4
+5V
–
+
DRIN2
22
DRIN3
15
DRIN1
14
H
R2OUT
78
C
R1OUT
80
N
R4OUT
21
L
R3OUT
19
E
T2IN
16
D
T1IN
13
F
T3IN
17
NN
T4IN
24
B
ISO2593
34-PIN DCE
INTERFACE CONNECTOR
ISO2593
34-PIN DTE
INTERFACE CONNECTOR
29, 34, 43, 60, 64, 72
www.BDTIC.com/Exar/
Figure 25. Typical DTE-DCE V.35 Connection using the SP319
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
10
Copyright © 2006 Sipex Corp.
Signal Ground
Clear to Send
Data Carrier Detect
Ring Indicator
Local Loopback
Remote Loopback
Receive Data (A)
Receive Data (B)
Receive Timing (A)
Receive Timing (B)
Unassigned--Unassigned--Unassigned--Unassigned--Unassigned--Unassigned--Test Mode
A
C
E
H
K
M
P
S
U
W
Y
AA
CC
EE
HH
KK
MM
B
D
F
J
L
N
R
T
V
X
Z
BB
DD
FF
JJ
LL
NN
Chasis Ground
Request to Send
DCE Ready (DSR)
DTE Ready (DTR)
Unassigned--Unassigned--Transmitted Data (A)
Transmitted Data (B)
Terminal Timing (A) } 113(A)
Terminal Timing (B) } 113(B)
Transmit Timing (A) } 114(A)
Transmit Timing (B) } 114(B)
Unassigned--Unassigned--Unassigned--Unassigned--Unassigned---
Figure 26. ISO-2593 Connector Pin Out
+5V
www.BDTIC.com/EXAR
25, 33, 41, 62, 73
26
+
0.1µF
C1+
VCC
VDD
30
+
0.1µF
+5V
C128 C2+
SP319
RCOUT 1
75 ENT
Vcc
400kΩ
108
R1OUT 80
Vcc
400kΩ
R2OUT 78
Vcc
5kΩ
400kΩ
106
DSR
107
DCD
109
47 T3OUT
24 T4IN
R3IN 35
140
104(B)
CTS
54 T2OUT
17 T3IN
5kΩ
R2IN 68
DTR
104(A)
58 T1OUT
16 T2IN
400kΩ
R1IN 66
105
RTS
RXD
61 DRA1
13 T1IN
Vcc
100Ω
RCB2 38
113(B)
14 DRIN1
400KΩ
100Ω
59 DRB1
RCOUT2 20
TXC
0.1µF
+
Vcc
RCB1 71
RCA2 37
103(B)
113(A)
0.1µF
3 TS000
RCA1 70
TXD
32
+
31 C2-
9 ENV35
103(A)
VSS
27
RI
125
51 T4OUT
Vcc
RLPBK
5kΩ
22 DRIN2
400kΩ
141
R4IN 39
LLPBK
R4OUT 21
5kΩ
Vcc
RCA3 76
SPARE
400kΩ
SPARE
SPARE
R3OUT 19
RCOUT3 79
100Ω
RTEN 7
RCB3 77
TXCC
42 DRA2
114(A)
44 DRB2
23 STEN
114(B)
15 DRIN3
RXC
63 DRA3
115(A)
65 DRB3
115(B)
6 TTEN
www.BDTIC.com/Exar/
29, 34, 43, 60, 64, 72
Figure 27. Typical DCE V.35 Interface
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
11
Copyright © 2006 Sipex Corp.
+5V
25, 33, 41, 62, 73
26
+
0.1µF
C1+
VCC
VDD
30
+
0.1µF
+5V
C128 C2+
SP319
104(A)
75 ENT
RCOUT2 20
14 DRIN1
400kΩ
100Ω
Vcc
400kΩ
TXD
61 DRA1
103(A)
107
Vcc
400kΩ
R2IN 68
R2OUT 78
109
Vcc
5kΩ
R3IN 35
108
RLPBK
47 T3OUT
24 T4IN
400kΩ
105
DTR
54 T2OUT
17 T3IN
5kΩ
103(B)
RTS
58 T1OUT
16 T2IN
400kΩ
R1IN 66
R1OUT 80
13 T1IN
Vcc
100Ω
RCB2 38
106
DSR
Vcc
RCB1 71
RCA2 37
114(B)
CTS
0.1µF
+
59 DRB1
104(B)
114(A)
TXCC
32
3 TS000
RCA1 70
RCOUT 1
+
31 C2-
9 ENV35
RXD
VSS
0.1µF
27
140
LLPBK
51 T4OUT
141
Vcc
DCD
R3OUT 19
5kΩ
22 DRIN2
400kΩ
125
RI
R4IN 39
R4OUT 21
115(A)
5kΩ
Vcc
RCA3 76
400kΩ
RXC
RCOUT3 79
115(B)
100Ω
RTEN 7
RCB3 77
TXCT
42 DRA2
113(A)
44 DRB2
23 STEN
113(B)
15 DRIN3
SPARE
63 DRA3
SPARE
65 DRB3
SPARE
6 TTEN
www.BDTIC.com/EXAR
29, 34, 43, 60, 64, 72
Figure 28. Typical DTE V.35 Interface
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
12
Copyright © 2006 Sipex Corp.
PACKAGE: 80 PIN MQFP
D
D1
D2
0.30" RAD. TYP.
PIN 1
c
0.20" RAD. TYP.
E1
E
E2
CL
5°-16°
0° MIN.
0°–7°
5°-16°
CL
L
L1
www.BDTIC.com/EXAR
A2
A
b
A1
e
DIMENSIONS
Minimum/Maximum
(mm)
SYMBOL
80–PIN MQFP
JEDEC MS-22
(BEC) Variation
MIN
NOM
A
COMMON DIMENTIONS
MAX
SYMBL MIN
2.45
A1
0.00
A2
1.80
b
0.22
2.00
Seating
Plane
c
0.11
0.25
L
0.73
2.20
L1
NOM
MAX
23.00
0.88
1.03
1.60 BASIC
0.40
D
17.20 BSC
D1
14.00 BSC
D2
12.35 REF
E
17.20 BSC
E1
14.00 BSC
E2
12.35 REF
e
0.65 BSC
N
80
80 PIN MQFP (MS-022 BC)
www.BDTIC.com/Exar/
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
13
Copyright © 2006 Sipex Corp.
ORDERING INFORMATION
Model
Temperature Range
Package Types
..................................................................... 0˚C to +70˚C .............................................. 80-pin JEDEC MQFP
Please consult the factory for pricing and availability on a Tape-On-Reel option.
Available in lead free packaging. To order add "-L" suffix to part number.
Example: SP319CF = standard; SP319CF-L/TR = lead free.
REVISION HISTORY
DATE
REVISION
DESCRIPTION
1/27/04
A
Implemented tracking revision.
6/8/05
B
Added Lead Free information for ordering.
6/12/05
C
Fixed typo on figure 25 DCE RCout1.
1/18/06
C
SP319CF is being obsoleted per PCN 06-0117-01.
www.BDTIC.com/EXAR
Corporation
ANALOG EXCELLENCE
Sipex Corporation
Headquarters and
Sales Office
22 Linnell Circle
Billerica, MA 01821
TEL: (978) 667-8700
FAX: (978) 670-9001
e-mail: [email protected]
Sales Office
233 South Hillview Drive
Milpitas, CA 95035
TEL: (408) 934-7500
FAX: (408) 935-7600
www.BDTIC.com/Exar/
Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the
application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others.
Rev: D Date: 1/18/06
SP319 10Mbps, +5V-Only V.35 Interface with RS-232 (V.28) Control Lines
14
Copyright © 2006 Sipex Corp.