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AD9665ACPZ-REEL7 Datasheet, PDF (10/17 Pages) Analog Devices – 4-Channel, LVDS, Dual-Output, Laser Diode Driver with Oscillator
AD9665
APPLICATIONS
The AD9665 uses the current at one or more of its four inputs,
RSET, W1SET, W2SET, and W3SET, and generates an output
current proportional to the sum of the input currents. The read
channel has a typical gain of 105 mA/mA, Write Channel 1 has
a typical gain of 300 mA/mA, Write Channel 2 has a typical
gain of 200 mA/mA, and Write Channel 3 has a typical gain of
100 mA/mA. The input impedance of all the channels is
typically 200 Ω. In most cases, a voltage output DAC can be
used to drive these channels. In this case, a series resistance
should be placed between each of the DAC channels and the
respective input on the AD9665. These resistances should be
selected to scale the desired maximum output current for each
channel with an appropriate voltage from the DAC without
excessively loading it.
BOARD LAYOUT
Due to the fast rise and fall time (<1 ns) required for the
operation of high speed drives, trace lengths carrying high
speed signals, such as RDIS, W1DIS, W2DIS, and W3DIS, and
the output current should be kept as short as possible to
minimize series inductance. A decoupling capacitor should be
located near each VDD pin, and the ground return for the
cathode of the laser diode should be kept as short as possible.
An S11 measurement of a piece of flexible printed circuit board
(FPC) can show the inductance associated with that section of
the FPC. In Table 4, an S11 measurement of two different pieces
of a 19 mm (0.75 in) FPC was taken. The first piece is a single
layer of an FPC with 0.5 ounce copper and 25.4 micron (1 mil)
thick Kapton® and coverlay. The second piece is an FPC with
2 layers of 0.5 ounce copper and 25.4 micron (1 mil) thick
Kapton and coverlay.
Table 4. Inductance of FPC
S11
L, nH @ 10 MHz
Single-layer FPC
8.8
Double-layer FPC
4.3
L, nH @ 300 MHz
8.5
4.2
As indicated by the measurement results, using two layers of
copper in an FPC can reduce inductance by over 50%. Using the
basic circuit equation
V
=
L
di
dt
it can be seen that increasing the amplitude of a current step
increases the voltage drop across the inductor. For example, on
the single-layer FPC, a 200 mA pulse with a rise time of 1 ns
generates a voltage drop of 1.86 V, assuming an additional
0.5 nH of inductance due to the laser diode itself. Increase this
current to 250 mA, and the voltage drop is greater than 2.3 V.
Add this to the ~2 V of operating voltage that is required for the
laser diode, and voltage headroom can become a problem if
operating on a 5 V supply. Because the di/dt term seems to be a
system requirement, L is the only contributor that can be
changed when trying to reduce the voltage drop. Decreasing the
inductance of the FPC can be done by either making the trace
wider or by making it shorter. Because the distance from the
laser diode driver (LDD) to the laser diode is fixed, using a
wider trace is the only option. This can be accomplished by
changing from a single-layer FPC design to a double-layer FPC
design. This additional layer allows the full width of the FPC
from the LDD to the laser diode to be used for the drive
current, while the bottom layer can be used entirely for the
return path (see Figure 15).
VIA
I DIODE I DIODE
I DIODE I DIODE
LASER
DIODE
TOP
TRACE
SINGLE-LAYER
FPC
BOTTOM
TRACE
DOUBLE-LAYER
FPC
Figure 15. Single-Layer and Double-Layer Flexible Printed Circuit Boards
TEMPERATURE CONSIDERATIONS
The AD9665 is available in a 32-lead LFCSP with an exposed
heat pad on top of the package. Using a 4-layer JEDEC standard
test board, the θJA of this package was determined without any
external heat sink attached to the exposed pad. This board is
made of FR4, is 1.60 mm thick, and consists of four copper
layers. The two internal layers are solid copper (1 oz/in2 or
0.35 mm thick). The two surface layers (containing the
component and back side traces) use 2 oz/in2 (0.70 mm thick)
of copper. This method of construction yields a θJA for the
AD9665 of approximately 110°C/W. An integrated circuit
dissipating 500 mW and packaged in an LFCSP, while operating
in an ambient environment of 85°C, would have an internal
junction temperature of approximately 140°C.
85°C + 0.5 W × 110°C/W = 140°C
This junction temperature is within the maximum
recommended operating junction temperature of 150°C. This
can be improved by attaching an external heat sink to the exposed
heat pad of the package. Of course, this is not a realistic method for
mounting a laser diode driver in an optical storage device.
In an actual application, the laser diode driver would most
likely be mounted to a flexible circuit board. The θJA of a system
is highly dependent on the board layout, material, and heat
sink. The user must consider these conditions carefully.
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