SONY CXB1563Q

CXB1563Q
2R IC for Optical Fiber Communication Receiver
Description
The CXB1563Q achieves the 2R optical-fiber
communication receiver functions (Reshaping and
Regenerating) on a single chip. This IC is also
equipped with the signal interruption alarm output
function, which is used to discriminate the existence
of data input.
32 pin QFP (Plastic)
Features
• Auto-offset canceler circuit
• Signal interruption alarm output
• 2-level switching function of identification maximum voltage amplitude for alarm block
• Single 5V power supply
Applications
• SONET/SDH : 622.08Mb/s
• Fiber channel : 531.25Mb/s
Absolute Maximum Ratings
• Supply voltage
• Storage temperature
• Input voltage difference : I VD – VD I
• SW input voltage
• Output current (Continuous)
(Surge current)
VCC – VEE
Tstg
Vdif
Vi
IO
Recommended Operating Conditions
• Supply voltage
VCC – VEE
• Termination voltage (for data/alarm)
VCC – VT1
• Termination voltage (for alarm 2)
VT2
• Termination resistance (for data/alarm) RT1
• Termination resistance (for alarm 2)
RT2
• Operating temperature
Ta
–0.3 to +7.0
–65 to +150
0.0 to +2.5
VEE to VCC
0 to 50
0 to 100
V
°C
V
V
mA
mA
5.0±0.5
1.8 to 2.2
VEE
45 to 55
460 to 560
–40 to +85
V
V
V
Ω
Ω
°C
Structure
Bipolar silicon monolithic IC
Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by
any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the
operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.
–1–
E95710A6Z
CXB1563Q
VccD
VccDA
SD
SD
VccDA
Q
Q
N.C.
Block Diagram and Pin Configuration
24
23
22
21
20
19
18
17
N.C. 25
16
TM
15
VccD
14
VEED
13
VccA
12
VEEA
N.C. 26
N.C. 27
Alarm
Block
CAP3 28
∆V
R2
R2
peak hold
CAP2 29
DOWN 30
peak hold
Limiting
Amplifier
Block
11 CAP1
UP 31
R4
R1
VccA 32
R3
–2–
VccA
VEEI
SW
5
6
7
8
CAP1
4
VCCA
3
D
2
D
1
VccA
R1
10
R2K
9
R1K
CXB1563Q
Pin Description
Typical pin
voltage
(V)
Pin No. Symbol
DC AC
1,2
VCCA
Equivalent circuit
Description
Positive power supply for analog
block.
0V
VccA
993
110.3
110.3
31
3
VEEI
30
–5V
SW
Vcs
VEEA
Generates the default voltage
between UP and DOWN.
The voltage (8.0mV for input
conversion) can be generated
between UP and DOWN
(Pins 30 and 31) as alarm
setting level by connecting this
pin to VEEA.
3
VCCA
Switches the identification
maximum voltage amplitude.
High voltage when open; the
identification maximum voltage
amplitude becomes 50mVp-p.
Low voltage when connecting
this pin to VEE; the amplitude
becomes 20mVp-p.
150k
100k
0V
4
SW
4
(OPEN)
VREF
or
–5V
VEEA
5
6
7
D
–1.3V
–0.9V
to
–1.7V
D
–1.3V
–0.9V
to
–1.7V
VCCA
0V
Limiting amplifier block input.
Be sure to make this input with
AC coupled.
VCCA
200
5
11
6
200
10k 100p 200
2k
10
8
CAP1 –1.8V
1.5k
9
R1K
1.5k
10
R2K
11
CAP1 –1.8V
10k
200
1k
9
8
VEEA
–3–
Positive power supply for analog
block.
Pins 8 and 11 connect a
capacitor which determines the
cut-off frequency for feedback
block, and 1kΩ is connected
between Pins 8 and 9; 2kΩ
between Pins 10 and 11. A
resistor which is to be inserted in
parallel with a capacitor can be
selected 5 ways by external
wiring, and DC feedback can be
varied.
CXB1563Q
Typical pin
voltage
(V)
Pin No. Symbol
DC AC
Equivalent circuit
Description
12
VEEA
–5V
Negative power supply for
analog block.
13
VCCA
0V
Positive power supply for analog
block.
14
VEED
–5V
Negative power supply for digital
block.
15
VCCD
0V
Positive power supply for digital
block.
16
TM
17
N.C
18
14
–3.4V
16
Chip temperature monitor.
No connected.
VCCDA
–0.9V
to
–1.7V
Q
19
19
20
21
–0.9V
to
–1.7V
Q
VCCDA
18
VEED
Positive power supply for output
buffer.
0V
VCCDA
–0.9V
to
–1.7V
SD
21
22
–0.9V
to
–1.7V
SD
Data signal output.
Terminate this pin in 50Ω at
VTT = –2V.
Alarm signal output.
Terminate this pin in 50Ω at
VTT = –2V.
22
VEED
23
VccDA
0V
Positive power supply for digital
block.
24
VccD
0V
Positive power supply for digital
block.
25
N.C
26
N.C
27
N.C
No connected.
–4–
CXB1563Q
Typical pin
voltage
(V)
Pin No. Symbol
DC AC
Equivalent circuit
Description
28
29
VCCA
CAP3 –1.8V
29
CAP2 –1.8V
80
80
10p
10p
28
5µA
5µA
VEEA
Connects a peak hold circuit
capacitor for alarm block. 470pF
should be connected to VccA
each.
CAP2 pin → Peak hold
capacitor connection for
alarm level setting block.
CAP3 pin → Peak hold
capacitor connection for
limiting amplifier signal.
VccA
30
–0.84V
(for
DOWN
VEEI
= –5V)
993
110.3
110.3
31
30
31
32
UP
VccA
–0.8V
(for
VEEI
= –5V)
Vcs
SW
Connects a resistor for alarm
level setting.
Default voltage can be
generated without an external
resistor by shorting the VEEI pin
to VEEA.
VEEA
3
Positive power supply for analog
block.
0V
–5–
CXB1563Q
Electrical Characteristics
• DC characteristics
(VCC = GND, VEE = –5V±10%, Ta = –40 to +85°C, VCC = VCCD, VCCDA, VCCA VEE = VEED, VEEA)
Item
Symbol
Power supply
IEE
Q/Q SD/SD High output voltage
VOH
Q/Q SD/SD Low output voltage
VOL
SD/SD High output voltage 2
VOHb
SD/SD Low output voltage 2
VOLb
SW High input voltage
Conditions
Min.
Typ.
Max.
Unit
RT1 = 50Ω,
VT1 = –2V termination
–50
–37
–28
mA
RT1 = 50Ω,
VT1 = –2V termination,
Ta = 0 to 85°C
–1025
–880
–1810
–1620
RT2 = 510Ω,
VEE termination,
Ta = 0 to 85°C
–1075
–830
–1860
–1570
VIH
–1900
0
SW Low input voltage
VIL
VEE
–2500
SW High input current
IIH
SW Low input current
IIL
–60
D/D input resistance
Rin
1125
1500
1875
Internal resistance 1 for alarm level
setting
Ra1
Refer to Fig. 3.
745
993
1241
Internal resistance 2 for alarm level
setting
Ra2A, B Refer to Fig. 3.
82.7
110.3
137.9
Pare ratio of internal resistance 2 for
alarm level setting
δRa2
0.97
Resistance between CAP1 and R1K
R3
745
993
1241
Resistance between CAP1 and R2K
R4
1489
1986
2482
2
Ra2A/Ra2B
–6–
mV
µA
Ω
1.03
Ω
CXB1563Q
• AC characteristics
(VCC = GND, VEE = –5V±10%, Ta = –40 to +85°C, VCC = VCCD, VCCDA, VCCA VEE = VEED, VEEA)
Item
Symbol
Maximum input voltage amplitude
Vmax
Amplifier gain
(in Limiting Amplifier)
Gv
Identification maximum voltage
amplitude of alarm level
VminA1
Conditions
Single-ended input
SW pad: Low,
single-ended input
Min. Typ. Max.
Unit
1600
mVp-p
40
dB
20
mVp-p
SW pad: Open High,
VminA2
single-ended input
50
Hysteresis width
∆P
4
SD response assert time
Tas
SD response deassert time
6
7
dB
0
100
Tdas
Low → High∗1
High → Low∗2
2.3
100
SD response assert time for alarm
level default
Tasd
Low → High∗3
0
100
SD response deassert time for
alarm level default
Tdasd
High → Low∗4
2.3
100
Alarm setting level for default
Vdef
UP/DOWN pins; Open,
connect VEEI to VEE.
6.6
8.0
9.3
mV
Propagation delay time
TPD
D to Q
0.4
1.0
1.6
ns
Q/Q rise time
Tr_Q
Q/Q fall time
Tf_Q
SD/SD rise time
Tr_SD
RT1 = 50Ω, VT1 = –2V termination,
250
VEE = –5V, Ta = 0 to 85°C
20% to 80%
0.45
SD/SD fall time
Tf_SD
0.45
250
∗1 VUP – VDOWN = 100mV, Vin = 100mVp-p (single ended), SW pin: High
Peak hold capacitance (CAP2, CAP3 pins) of 470pF; connect VEEI to VEE.
∗2 VUP – VDOWN = 100mV, Vin = 1Vp-p (single ended), SW pin: High
Peak hold capacitance (CAP2, CAP3 pins) of 470pF; connect VEEI to VEE.
∗3 Vin = 50mVp-p (single ended), SW pin: Low
Peak hold capacitance (CAP2, CAP3 pins) of 470pF; connect VEEI to VEE.
∗4 Vin = 1Vp-p (single ended), SW pin: Low
Peak hold capacitance (CAP2, CAP3 pins) of 470pF; connect VEEI to VEE.
–7–
µs
450
ps
450
1.6
1.6
ns
CXB1563Q
DC Electrical Characteristics Measurement Circuit
V
24
23
VT1
–2V
51
51
V
21
22
51 51
V
19
20
V
17
18
25
16
26
15
27
Alarm
Block
14
Limiting
Amplifier
Block
28
∆V
30
12
R2
29
13
peak hold
peak hold
C3
R2
C3
11
V
31
V
R4
R1
C2
10
32
V
9
R3
R1
V
V
1
2
5
4
3
6
7
8
V
A
C1
VS
V
C1
A
VD
VEE
–8–
–5V
CXB1563Q
AC Electrical Characteristics Measurement Circuit
Oscilloscope
50Ω input
Z0 = 50
Z0 = 50
Z0 = 50
Z0 = 50
24
23
21
22
20
19
17
18
25
16
26
15
27
Alarm
Block
470pF
14
28
Limiting
Amplifier
Block
13
REX1
R2
∆V
30
12
R2
29
peak hold
peak hold
470pF
V
11
31
R1
R4
10
32
0.22µF
9
REX2
R1
1
2
3
5
4
6
R3
7
0.022µF
0.022µF
51
51
–9–
8
VEE
–3V
VCC
+2V
CXB1563Q
Application Circuit
VT1
51
24
23
–2V
51
51
21
22
20
51
19
17
18
25
16
26
15
27
Alarm
Block
14
28
Limiting
Amplifier
Block
470pF
29
∆V
30
12
R2
470pF
13
peak hold
peak hold
C3
R2
C3
11
31
R1
R4
10
32
C2
0.22µF
9
R1
1
2
3
5
4
C1
0.022µF
6
R3
7
8
C1
0.022µF
VEE
51
–5V
51
Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for
any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same.
– 10 –
CXB1563Q
Notes on Operation
1. Limiting amplifier block
The limiting amplifier block is equipped with the auto-offset canceler circuit. When external capacitors C1 and
C2 are connected as shown in Fig. 1, the DC bias is set automatically in this block. External capacitor C1 and
IC internal resistor R1 determine the low input cut-off frequency f2 as shown in Fig. 2. Similarly, external
capacitor C2 and IC internal resistor R2 determine the high cut-off frequency f1 for DC bias feedback. Since
peaking characteristics may occur in the low frequency area of the amplifier gain characteristics depending on
the f1/f2 combination, set the C1 and C2 so as to avoid the occurrence of peaking characteristics. The target
values of R1 and R2 and the typical values of C1 and C2 are as indicated below. When a single-ended input is
used, provide AC grounding by connecting Pin 6 to a capacitor which has the same capacitance as capacitor
C1.
R1 (internal): 1.5kΩ
R2 (internal): 10kΩ
f2: 4.8kHz
f1: 72Hz
C1 (external): 0.022µF
C2 (external): 0.22µF
1kΩ is incorporated between Pins 8 and 9; 2kΩ between Pins 10 and 11. A resistance value which is to be
inserted in parallel with a capacitor f2 can be selected 5 ways (∞, 3kΩ, 2kΩ, 1kΩ, 1k//2kΩ) by external wiring,
and DC feedback can be varied.
D
5
C1
To IC interior
6
C1
R1
R1
8
R3
R2
R4
R2
9
C2
10
11
Fig. 1
Gain
Feedback
frequency response
f1
f2
Frequency
Fig. 2
– 11 –
Amplifier
frequency response
CXB1563Q
2. Alarm block
In order to operate the alarm block, give the voltage difference between Pins 30 and 31 to set an alarm level
and connect the peak hold capacitor C3 shown in Fig. 3.
This IC has two setting methods of alarm level; one is to connect VEE to Pin 3 and leave Pins 30 and 31 open
to set an alarm level default value (8mV for input conversion). The other is to connect Pin 3 to VEE and set a
desired alarm level using the external resistors REX1 and REX2 and REX3 shown in Fig. 3.
Connect REX1 between Pins 30 and 31, or between Pin 30 and VCC when less alarm level is desired to be set
than its default value; connect REX2 between Pin 31 and Vcc potential when more alarm level is desired to be
set than its default value. However, the Pin 31 voltage must be higher than that of Pin 30. Refer to Figs. 5, 8 to
13 for this alarm level setting.
This IC also features two-level setting of identification maximum voltage amplitude. The amplitude is set to
50mVp-p when Pin 4 is left open (High level) and it is set to 20mVp-p when Pin 4 is Low level. Therefore, noise
margin can be increased by setting Pin 4 to Low level when small signal is input. The relation of input voltage
and peak hold output voltage is shown in Fig. 6.
In the relation between the alarm setting level and hysteresis width, the hysteresis width is designed to
maintain a constant gain (design target value: 6dB) as shown in Fig. 4. The C3 capacitance value should be
set so as to obtain desired assert time and deassert time settings for the alarm signal.
The electrical characteristics for the SD response assert and deassert times are guaranteed only when the
waveforms are input as shown in the timing chart of Fig. 7.
The typical values of REX1, REX2, REX3 and C3 are as follows: (Approximately 10pF capacitor is built in Pins 28
and 29 each.)
REX1 : 217Ω (when the alarm level is set to 4mV for input conversion.)
REX2 : 634Ω (when the alarm level is set to 19mV for input conversion.)
REX3 : 4kΩ (when the alarm level is set to 4mV for input conversion.)
C3 : 470pF
The table below shows the alarm logic.
Optical signal input state
SD
SD
Signal input
High level
Low level
Signal interruption
Low level
High level
Ra1, Ra2A and Ra2B values
are typical values.
From
Limiting Amplifier
Peak hold
VCCA
Ra1
Ra2A
110.3
SD
SD
993
Ra2B
110.3
Peak hold
Vcs
VccA
VccA
∆V
4
3
31
10p
30
10p
IC interior
31
30
28
29
C3
C3
3
REX2
IC exterior
Vcc
Fig. 3
– 12 –
REX1
REX3
Vcc
Vcc
Vcc
CXB1563Q
VDAS → Deassert level
VAS → Assert level
High
level
VAS, VDAS [mV]
Low
level
VAS
VDAS
Small
Large
3dB
3dB
Alarm setting
input level
VAS
SW = High
SW = Low
20
15
VDAS
10
5
0
0
Hysteresis
20
40
60
80
Voltage between Pins 30 and 31 [mV]
Input electrical signal amplitude
Fig. 4
Peak hold output voltage
SD output
AAA
AAA
25
Fig. 5
SW → Low
SW → Open High
0
2
0
5
0
Input voltage [mVp-p]
Fig. 6
Data input
(D)
Hysteresis width
Alarm setting level
Data output
(Q)
Alarm output
(SD)
Assert time
Deassert time
Fig. 7
– 13 –
100
CXB1563Q
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TM pin temperature characteristics
REX1-VUD temperature characteristics data
1800
40
35
1400
1200
1000
–50
Vup-Vdown [mV]
TM-VEE [mV]
1600
Iin=100µA
Iin=1mA
Iin=5mA
–25
0
25
50
75
100
30
25
20
15
–40°C
27°C
85°C
125°C
10
125
5
Tj [°C]
0
400
800
1200
1600
2000
REX1 [Ω]
Fig. 8
Fig. 9
REX3-VUD temperature characteristics data
REX2-VUD temperature characteristics data
40
130
–40°C
27°C
85°C
125°C
120
30
Vup-Vdown [mV]
Vup-Vdown [mV]
110
35
100
90
80
70
20
15
–40°C
27°C
85°C
125°C
10
60
5
50
40
25
0
1000
2000
3000
4000
5000
6000
0
7000
0
10
5
Fig. 10
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Ta = 27°C
0
1600
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Alarm Setting Level [mV]
Alarm Setting Level [mV]
6
1200
30
Alarm Setting Level vs. REX2
Alarm Setting Level vs. REX1
800
25
Fig. 11
8
400
20
REX3 [kΩ]
REX2 [Ω]
0
15
2000
Ta = 27°C
20
18
16
14
12
10
0
1000
2000
3000
4000
REX2 [Ω]
REX1 [Ω]
Fig. 12
Fig. 13
3. Others
Pay attention to handling this IC because its electrostatic discharge strength is weak.
– 14 –
5000
6000
7000
CXB1563Q
Example of Representative Characteristics
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80
70
Bit Error Rate
10–7
10–8
VEE = –5.0V
Ta = 27°C
D = 622.08Mbps
10–9
10–10
Output RMS Jitter [pS]
10–5
10–6
pattern : PRBS223 –1
10–11
1.8
2
2.2
2.4
2.6
2.8
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Output RMS Jitter vs. Data Input Level
Bit Error Rate vs. Data Input Level
10–4
3
Data Input Level [mVp-p]
Fig. 14
VEE = –5.0V
Ta = 27°C
D = 622.08Mbps
pattern: PRBS223 –1
60
50
40
30
20
10
0
1
10
100
1000
Data Input Level [mVp-p]
Fig. 15
Q Output Waveform
VEE = –5.0V
Ta = 27°C
D = 622.08Mbps
Vin = 3mVp-p, Single Input
pattern : PRBS223 –1
19.8500ns
Ch. 1
= 200.0mV/div
Timebase = 500ps/div
22.3500ns
24.8500ns
Offset = 680.0mV
Delay = 22.3500ns
Fig. 16
– 15 –
CXB1563Q
Package Outline
Unit: mm
32PIN QFP (PLASTIC)
9.0 ± 0.2
24
0.1
+ 0.35
1.5 – 0.15
+ 0.3
7.0 – 0.1
17
16
32
9
(8.0)
25
1
+ 0.2
0.1 – 0.1
0.8
± 0.12 M
+ 0.1
0.127 – 0.05
0° to 10°
PACKAGE MATERIAL
EPOXY RESIN
SONY CODE
QFP-32P-L01
LEAD TREATMENT
SOLDER PLATING
EIAJ CODE
∗QFP032-P-0707-A
LEAD MATERIAL
42 ALLOY
PACKAGE WEIGHT
0.2g
JEDEC CODE
– 16 –
0.50
8
+ 0.15
0.3 – 0.1