EUDYNA F0100109B

ADVANCE
01.08.28
♦ Features
• Low voltage of +3.3 V single power supply
• 27 kΩ high transimpedance
• Typical 130 MHz broad bandwidth
• 32 dB high gain
• 3 dBm large optical input
• Over 40 dB wide dynamic range
• Differential output
F0100109B
3.3 V /5V 156 Mb/s Receiver
Transimpedance Amplifier
♦ Applications
• Preamplifier of an optical receiver circuit for
OC-3/STM-1 (156 Mb/s)
♦ Functional Description
The F0100109B is a stable GaAs integrated transimpedance amplifier capable of 32 dB
gain at a typical 130 MHz 3 dB-cutoff-frequency, making it ideally suited for a 156 Mb/s
optical receiver circuit, for example, OC-3/STM-1, instrumentation, and measurement applications. The integrated feedback loop design provides broad bandwidth and stable operation. The F0100109B typically specifies a high transimpedance of 27 kΩ(Rs=RL=50 Ω) with
a wide dynamic range of over 40 dB. It also provides a large optical input overload of more
than 3 dBm. Furthermore, it can operate with a low supply voltage of single +3.3 V. It features
a typical dissipation current of 27 mA.
Only chip-shipment is available for all product lineups of GaAs transimpedance amplifiers, because the packaged preamplifier can not operate with the maximum performance
owing to parasitic capacitance of the package.
F0100109B
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
♦ Absolute Maximum Ratings
Ta=25 °C, unless specified
Parameter
Symbol
Value
Units
Supply Voltage
VDD
VSS-0.5 to VSS+4.0
V
Supply Current
IDD
50
mA
Input Current
IIN
3
mA
Ambient Operating Temperature
Ta
-40 to +90
°C
Storage Temperature
Tstg
-50 to +125
°C
♦ Recommended Operating Conditions
Ta=25 °C, VDD=+3.3 V, VSS=GND, unless specified
Value
Parameter
Symbol
Units
Min.
Max.
Supply Voltage
VDD
3.1
3.6
V
Ambient Operating Temperature
Ta
0
85
°C
Input Capacitance
CPD
0.5
pF
-
♦ Electrical Characteristics
Ta=25 °C, VDD=3.3 V, VSS= GND, unless specified
Value
Parameter
Symbol
Test Conditions
Units
Min.
Typ.
Max.
Supply Current
IDD
DC
19.0
27.0
40.0
mA
Gain(Positive)
S21P
PIN=-50dBm f=1MHz,
RL=50Ω
29
32
-
dB
Gain(negative)
S21N
PIN=-50dBm f=1MHz,
RL=50Ω
29
32
-
dB
-3dB High Frequency
Cut-off (positive)
FCP
PIN=-50dBm RL=50Ω
80
130
-
MHz
-3dB High Frequency
Cut-off (negative)
FCN
PIN=-50dBm RL=50Ω
80
130
-
MHz
Input Impedance
RI
f=1MHz
550
800
1100
Ω
Trans-Impedance(positive)
ZTP *
f=1MHz RL=50Ω
-
27
-
KΩ
Trans-Impedance(negative)
ZTN *
f=1MHz RL=50Ω
-
27
-
KΩ
Output Voltage(positive)
VOP
DC
1.6
2.5
3.2
V
Output Voltage(negative)
VON
DC
1.6
2.5
3.2
V
VI
DC
0.8
0.97
1.1
V
Inoise
f=10MHz
-
0. 7
-
pA/Hz1/2
tagc
Cout=2200pF
-
100
Input Voltage
Equivalent Input Noise
Current Density
AGC time constant
*1 ZTP, N=
(R I +50)
2
×10
S21P,N
20
µsec
F0100109B
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
♦ Block Diagram
VDD
OUT
IN
OUT
Rf
CAP
AGC
Cout
VSS
VDD
VSS
IN
OUT
OUT
CAP
Supply Voltage
Supply Voltage
Input
Output
Output
Connect outer Capasitance
F0100109B
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
♦ Die Pad Assignments
(12)
(11)
(10)
(9)
(13)
(8)
(7)
(14)
(6)
(5)
(1)
(2)
No.
Symbol
(3)
(4)
Center Coordinates(µm)
No.
Symbol
Center Coordinates(µm)
(1)
VDD3.3
(75,140 )
(10)
VSS
(395,715)
(2)
VDD5.0
(395,75)
(11)
VDD3.3
(235,715)
(3)
OUT
(555,75)
(12)
CAP
(75,715)
(4)
VSS
(715,75)
(13)
VSS
(75,555)
(5)
OUT
(715,235)
(14)
IN
(75,395)
(6)
VSS
(715,395)
(7)
OUT
(715,555)
(8)
VSS
(715,715)
O
(0,0)
(9)
OUT
(555,715)
A
(790,790)
F0100109B
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
♦ Test Circuits
1) AC Characteristics
Network Analyzer
50Ω
Pin=-50 dBm
f=300 kHz~3 GHz
VDD
IN
50Ω
OUT
DUT
CAP
*
VSS
Switch
OUT
50Ω
Prober
* PSPL 5501
2) Sensitivity Characteristics
VPD
3.3V
0.022µF
E/O
Converter
Pulse
Pattern
Generator
Optical
Attenuater
VCC
PD
DUT
CLK
0.022µF
Comparator
SEI
F0300232Q
Bit Error
Rate Tester
3.3V
0.022µF
F0100109B
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
♦ Examples of AC Characteristics
(1) Gain (S21P)
Ta=25 °C, VDD=+3.3 V, VSS=GND, Pin=-50 dBm, RL=50 Ω, 300 kHz-3 GHz
39
36
S21 [dB]
33
30
27
24
21
1
10
100
1000
Frequency [MHz]
(2) Gain (S21N)
Ta=25 °C, VDD=+3.3 V, VSS=GND, Pin=-50 dBm, RL=50 Ω, 300 kHz-3 GHz
39
36
S21 [dB]
33
30
27
24
21
1
10
100
Frequency [MHz]
1000
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
(3) Input Noise Current Density & Transimpedance
G
G
N
N
I
I
T
T
N
N
I
I
R
R
P
P
W
W
O
NO
N
F0100109B
F0100109B
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
♦ Typical Bit Error Rate
PRBS 223-1, Ta=25 °C, VDD=3.3 V, VSS=GND, RL=50 Ω
Bit Error Rate
10-4
10-6
10-8
10-10
10-12
155.6Mb/s
NRZ
PRB223 -1
Mark Ratio=1/2
-44
-42
-40
-38
Average Received Power [dBm]
-36
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
F0100109B
♦ General Description
A transimpedance amplifier is applied as a pre-amplifier which is an amplifier for a faint
photo-current from a PIN photo diode (PD). The performance in terms of sensitivity, bandwidth, and so on, obtained by this transimpedance amplifier strongly depend on the capacitance brought at the input terminal; therefore, “typical”, “minimum”, or “maximum” parameter
descriptions can not always be achieved according to the employed PD and package, the
assembling design, and other technical experts. This is the major reason that there is no
product lineup of packaged transimpedance amplifiers.
Thus, for optimum performance of the transimpedance amplifier, it is essential for customers to design the input capacitance carefully.
Hardness to electro-magnetic interference and fluctuation of a power supply voltage is
also an important point of the design, because very faint photo-current flows into the
transimpedance amplifier. Therefore, in the assembly design of the interconnection between
a PD and a transimpedance, noise should be taken into consideration.
♦ Low Voltage Operation
The F0100109B features a single 3.3 V supply operation, which is in great demand recently, because most of logic IC’s operate with the supply voltage of 3.3 V. The analog IC’s
with a single 3.3 V supply for use in fiber optic communication systems are offered by only
SEI.
♦ Recommendation
SEI basically recommends the F08 series PINAMP modules for customers of the
transimpedance amplifiers. In this module, a transimpedance amplifier, a PD, and a noise
filter circuit are mounted on a TO-18-can package hermetically sealed by a lens cap, having
typically a fiber pigtail. The F08 series lineups are the best choice for customers to using the
F01 series transimpedance amplifiers. SEI’s F08 series allows the customers to resolve
troublesome design issues and to shorten the development lead time.
♦ Noise Performance
The F0100109B based on GaAs FET’s shows excellent low-noise characteristics compared with IC’s based on the silicon bipolar process. Many transmission systems often demand superior signal-to-noise ratio, that is, high sensitivity; the F0100108B is the best choice
3.3 V / 5V 156 Mb/s Transimpedance Amplifier
F0100109B
for such applications.
The differential circuit configuration in the output enable a complete differential operation
to reduce common mode noise: simple single ended output operation is also available.
♦ Die-Chip Description
The F0100109B is shipped like the die-chip described above. The die thickness is
typically 280 µm ± 20 µm with the available pad size uncovered by a passivation film of 95 µm
square. The material of the pads is TiW/Pt/Au and the backside is metalized by Ti/Au.
♦ Assembling Condition
SEI recommends the assembling process as shown below and affirms sufficient wire-pull
and die-shear strength. The heating time of one minute at the temperature of 310 °C gave
satisfactory results for die-bonding with AuSn performs. The heating and ultrasonic wirebonding at the temperature of 150 °C by a ball-bonding machine is effective.
♦ Quality Assurance
For the F01 series products, there is only one technically inevitable drawback in terms of
quality assurance which is to be impossible of the burn-in test for screening owing to dieshipment. SEI will not ship them if customers do not agree on this point. On the other hand,
the lot assurance test is performed completely without any problems according to SEI’s authorized rules. A microscope inspection is conducted in conformance with the MIL-STD883C Method 2010.7.
♦ Precautions
Owing to their small dimensions, the GaAs FET’s from which the F0100109B is designed
are easily damaged or destroyed if subjected to large transient voltages. Such transients can
be generated by power supplies when switched on if not properly decoupled. It is also possible to induce spikes from static-electricity-charged operations or ungrounded equipment.
Electron Device Department