AGILENT HSDL-3202

Agilent HSDL-3202
IrDA® Data 1.3 Low Power
Compliant 115.2 Kb/s Infrared
Transceiver
Data Sheet
Description
The HSDL-3202 is a new generation
of low-cost Infrared (IR) transceiver
modules from Agilent Technologies.
It features one of the smallest footprints in the industry at 2.5 H x
8.0 W x 3.0 D mm. Although the
supply voltage can range from 2.7 V
to 3.6 V, the LED drive current is
internally compensated to a constant 32 mA to guarantee link dis-
tance of IrDA Data 1.3 (low
power) physical layer
specification.
The HSDL-3202 meets the link
distance of 20 cm to other IrDA
1.3 low power devices, and 30 cm
to standard one meter IrDA 1.3
devices. It is designed to interface
to input/output logic circuits as
low as 1.8 V.
NE
CELL PHONES
PAGERS
PDAs
CAMERAS
CO
NA
I
UM
°
30
N
TIO
.3
IrDA 1 OR
ARD
STAND WER
O
LOW P
ILL
.3
IrDA 1 R
OWE
LOW P
20 CM TO LOW POWER DEVICES
30 CM TO STANDARD DEVICES
CELL PHONES
PAGERS
PRINTERS
PCs
PDAs
CAMERAS
Features
• Ultra small surface mount
package
• Minimal height: 2.5 mm
• VCC from 2.7 to 3.6 volts
• Interface to input/output logic
circuits as low as 1.8 V
• LED supply voltage can range from
2.7 to 6 volts
• Low ICC shutdown current
– 10 nA typical
• Complete shutdown
– TxD, RxD, PIN diode
• Three optional external
components
• Temperature performance guaranteed, –25°C to 85°C
• 32 mA LED drive current
• Integrated EMI shield
• IEC825-1 class 1 eye safe
• Edge detection input
– prevents the LED from
long turn on time
Applications
• Mobile telecom
– cellular phones
– pagers
– smart phones
• Data communication
– PDAs
– portable printers
• Digital imaging
– digital cameras
– photo-imaging printers
• Electronic wallet
Application Circuit
8 VLED
C1
1.0 µF
TXD
RXD
SHUT DOWN
7 TXD
LED
CURRENT
SOURCE
Pinout, Rear View
6 RXD
5 SD
SHIELD
4 AGND
3
C2
1.0 µF
2
C3
1.0 µF
VCC
I/O VCC
8
RX PULSE
SHAPER
1 GND
I/O Pins Configuration Table
Pin Symbol
Description
Notes
1
GND
Ground
Connect to system ground
2
IOVCC
Input/Output
ASIC VCC
Connect to ASIC logic
controller VCC voltage
3
VCC
Supply Voltage
Regulated, 2.7 to 3.6 volts
4
AGND
Analog Ground
Connect to a ”quiet“ ground
5
SD
Shut Down
Active High
This pin must be driven either high
or low. Do NOT float the pin.
6
RXD
Receiver Data Output
Active Low
Output is a low pulse for 1.6 µs
when a light pulse is seen
7
TXD
Transmitter Data Input
Active High
Logic High turns on the LED. If
held high longer than ~ 20 µs, the
LED is turned off. TXD must be
driven high or low. Do NOT float
the pin.
8
VLED
LED Supply Voltage
May be unregulated, 2.7 to 6 volts.
–
SHIELD
EMI Shield
Connect to system ground via a
low inductance trace. For best
performance, do not connect to
GND or AGND directly at the part.
Recommended Application Circuit Components
Component
Recommended Value
Note
C1
1.0 µF, ± 20%, Tantalum
1
C2
1.0 µF, ± 20%, Tantalum
1
C3
1.0 µF, ± 20%, Tantalum
1
2
7
6
5
4
3
2
1
Absolute Maximum Ratings
For implementations where case-to-ambient thermal resistance is ≤ 50°C/W.
Parameter
Symbol
Min.
Max.
Units
Storage Temperature
TS
–40
100
°C
Operating Temperature
TA
–25
85
°C
LED Supply Voltage
VVLED
0
7
V
Supply Voltage
VCC
0
7
V
Input/Output Voltage
IOVCC
0
7
V
Input Voltage: TXD, SD
VI
0
IOVCC + 0.5
V
Output Voltage: RXD
VO
–0.5
IOVCC + 0.5
V
Solder Reflow
Temperature Profile
See page 12
Transceiver I/O Truth Table
The outputs (LED and RXD) are
controlled by the combination of
the TXD and SD (shutdown) pins
and light falling on the receiver.
As shown in the table below, the
transmitter is non-inverting; the
LED is on when the TXD pin is
high and off when TXD is low.
VLED Pin: Typical leakage
current of 1.5 nA.
The receiver is inverting; the RXD
pin is low during IrDA signal
pulses and high when the receiver
does not see any light. When
shutdown (SD pin high), the LED
is off (the state of the TXD pin
does not matter), and the RXD
pin is pulled high with a weak
internal pullup.
TXD
LED
Receiver
RXD
Notes
Low
High
On
Don’t care
Not valid
2
Low
Off
IrDA signal
Low
3, 4
No signal
High
Don’t care
High
Don’t care
Off
RXD Pin: This pin is NOT Tristate. During shutdown the
equivalent circuit is a weak
pullup (~300 kΩ) to VCC. The
ESD protection diodes to VCC and
Ground are also present.
TXD Pin: Input protection
diodes are present.
SD
High
Shutdown Mode Notes
When the HSDL-3202 is in Shutdown Mode (SD pin high), the
part presents different impedances to the rest of the circuit
than when it is in normal mode.
SD Pin: Will draw approximately
10 nA when driven high.
5
Caution: The BiCMOS inherent to this design of this component increases the component’s susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions
be taken in handling and assembly of this component to prevent damage and/or degradation
which may be induced by ESD.
3
Recommended Operating Conditions
Parameter
Symbol
Min.
Max.
Units
Operating Temperature
TA
–25
85
°C
Supply Voltage
VCC
2.7
3.6
V
Input/Output Voltage
IOVCC
1.8
VCC
V
LED Supply Voltage
VLED
2.7
6
V
TXD, SD Input
Voltage
Logic High
Logic Low
VIH
VIL
2/3 IOVCC
0
IOVCC
1/3 IOVCC
V
V
IOVCC ≥ 1.8 V
IOVCC ≥ 1.8 V
Receiver Input
Irradiance
Logic High
Logic Low
EIH
EIL
0.0081
500
0.4
mW/cm2
µW/cm2
For in-band signals
For in-band signals
2.4
115.2
Kb/s
Receiver Data Rate
Ambient Light
Receiver Wakeup Time Definition
tPW
SD
90%
RX
LIGHT
50%
VOL
10%
RXD
tF
VALID DATA
tR
tRW
LED Optical Waveform
Transmitter Wakeup Time Definition
tPW
LED ON
90%
SD
50%
TXD
10%
LED OFF
tR
tF
TX
LIGHT
tTW
TXD “Stuck ON” Protection
TXD
LED
tOPW (MAX.)
4
Notes
IOVCC operational at
1.5 V at reduced spec
See Test Methods on page 15 for details
RXD Output Waveform
VOH
Conditions
7
7
Electrical & Optical Specifications
Specifications hold over the recommended operating conditions unless otherwise noted. Unspecified test conditions
may be anywhere in their operating range. All typical values are at 25°C and 3.0 V unless otherwise noted.
Parameter
Symbol Min.
Typ.
Max.
Units
Conditions
Note
Viewing Angle
2θ1/2
30
–
–
°
Peak Sensitivity Wavelength
λp
–
880
–
nm
RXD Output
Voltage
Logic High
VOH
IOVCC – 0.2 –
IOVCC
V
IOH = –200 µA, EI ≤ 0.3
µW/cm2
IOL = 200 µA
Logic Low
VOL
0
–
0.3
V
7
RXD Pulse Width
tPW
–
2.5
3.5
µs
RXD Rise Times
tR
–
20
70
ns
tPW (EI) = 1.6 µs, CL = 9.0 pF
Max. value @ IOVCC = 1.8 V
RXD Fall Times
tF
–
25
50
ns
tPW (EI) = 1.6 µs, CL = 9.0 pF
Receiver Latency Time
tL
–
20
50
µs
8
Receiver Wake Up Time
tRW
–
20
100
µs
9
Radiant Intensity
IEH
4
8
28.8
mW/Sr TA = 25°C, θ1/2 ≤ 15°,
TXD ≥ 2/3 IOVCC
Viewing Angle
2θ1/2
30
–
60
°
Peak Wavelength
λp
–
875
–
nm
Spectral Line Half Width
∆λ 1/2
–
35
–
nm
Optical Pulse Width
tOPW
–
–
2.0
20
2.23
30
µs
µs
tPW (TXD) = 1.6 µs
TXD pin stuck high
Optical Rise and Fall Times
tOR
–
–
600
ns
tPW (TXD) = 1.6 µs
Optical Rise and Fall Times
tOF
–
–
600
ns
tPW (TXD) = 1.6 µs
TXD Logic Levels
VIH
VIL
2/3 IOVCC
0
–
–
IOVCC
V
1/3 IOVCC V
TXD Input Current High
Low
IH
IL
–
–1
0.01
-0.01
1
–
µA
µA
VI ≥ 2/3 IOVCC
0 ≤ VI ≤ 1/3 IOVCC
LED Current
On
IVLED
–
32
38
mA
Off
IVLED
–
0.0015 1
µA
Shutdown
IVLED
–
0.0015 1
µA
VVLED = VCC = 3.6 V, VI(TXD)
≥ 2/3 IOVCC
VVLED = VCC = 3.6 V, VI(TXD)
≤ 1/3 IOVCC
VI(SD) ≥ 2/3 IOVCC
tTW
–
12
µs
Receiver
7
Transmitter
High
Low
Transmitter Wake Up Time
5
100
IOVCC ≥ 1.8 V
IOVCC ≥ 1.8 V
10
Parameter
Symbol Min.
Typ.
Max.
Units
Conditions
Note
Transceiver
SD Logic
Levels
High
Low
VIH
VIL
2/3 IOVCC –
0
–
IOVCC
V
1/3 IOVCC V
IOVCC ≥ 1.8 V
IOVCC ≥ 1.8 V
SD Input
Current
High
Low
IH
IL
–
–300
10
–10
200
–
nA
nA
VI ≥ 2/3 IOVCC. Max value at 25°C
0 ≤ VI ≤ 1/3 IOVCC. Max value at 25°C
Supply
Shutdown ICC1
–
10
200
nA
VCC = 3.6 V, VSD = IOVCC
Current
Idle
ICC2
–
100
250
µA
VCC = 3.6 V, VI(TXD) ≤ 1/3 IOVCC, EI=0
Peak
Active
Receive
ICC3
–
2.0
10.0
mA
VCC = 3.6 V, VI(TXD) ≤ 1/3 IOVCC
11, 12
Peak
Active
Transmit
ICC4
–
5.0
9.0
mA
VCC = 3.6 V, VI(TXD) ≤ 2/3 IOVCC
11
IIOVCC
–
30
200
nA
IOVCC Current
Notes:
1. C1,C2, and C3 must be placed within 0.7 cm of the HSDL-3202 to obtain optimum noise immunity. If VLED and VCC are tied together, then the
application may use one less capacitor.
2. If TXD is stuck in the high state, the LED will turn off after about 20 µs.
3. In-Band IrDA signals and data rates ≤ 115.2 Kb/s.
4. RXD Logic Low is a pulsed response. The condition is maintained for a duration that is dependent upon the data pattern.
5. RXD Logic High during shutdown is a weak pullup resistor (300 kΩ).
6. An in-band optical signal is a pulse/sequence where the peak wavelength, λp, is defined as 850 nm ≤ λp ≤ 900 nm, and the pulse
characteristics are compliant with the IrDA Serial Infrared Physical Layer Link Specification.
7. For in-band signals [115.2 Kb/s where 8.1 µW/cm2 ≤ EI ≤ 500 mW/cm2].
8. Latency is defined as the time from the last TXD light output pulse until the receiver has recovered full sensitivity.
9. Receiver wake up time is measured from the SD pin high-to-low transition or V CC power on to valid RXD output.
10. Transmitter wake up time is measured from the SD pin high-to-low transition or VCC power on to valid light output in response to a TXD pulse.
11. Typical values are at EI = 10 mW/cm 2.
12. Maximum value is at EI = 500 mW/cm 2.
6
Package Dimensions
MOUNTING
CENTER
4.0
1.025
CL
2.05
RECEIVER
EMITTER
2.2
2.5
1.175
0.35
0.65
0.80
1.05
1.25
2.85
2.55
4.0
8.0
3.0
2.9
1.85
CL
UNIT: mm
TOLERANCE: ± 0.2 mm
PIN 1
0.6
3.325
6.65
7
Moisture Proof Packaging
The HDSL-3202 is shipped in
moisture proof packaging. Once
opened, moisture absorption
begins.
Recommended Storage Conditions
Storage
Temperature
10°C to 30°C
Relative
Humidity
below 60% RH
Time from Unsealing to Soldering
After removal from the bag, the
parts should be soldered within
two days if stored at the recommended storage conditions. If
times longer than two days are
needed, the parts must be stored
in a dry box.
Baking
If the parts are not stored in dry
conditions, they must be baked
before reflow to prevent damage
to the parts.
Package
Temp.
Time
In reels
60°C
≥48 hours
In bulk
100°C
125°C
150°C
≥4 hours
≥2 hours
≥1 hour
Solder Pad, Mask and Metal Stencil
METAL STENCIL
FOR SOLDER PASTE
PRINTING
STENCIL
APERTURE
LAND
PATTERN
SOLDER
MASK
PCB
Recommended Land Pattern
CL
SHIELD
SOLDER PAD
1.35
MOUNTING
CENTER
1.25
2.05
0.10
Baking should only be done once.
0.775
1.75
FIDUCIAL
0.60
0.475
1.425
UNIT: mm
2.375
3.325
8
Recommended Metal Solder
Stencil Aperture
It is recommended that only a
0.152 mm (0.006 inch) or a
0.127 mm (0.005 inch) thick
stencil be used for solder paste
printing. This is to ensure
adequate printed solder paste
volume and no shorting. See the
table below the drawing for
combinations of metal stencil
aperture and metal stencil thickness that should be used.
APERTURES AS PER
LAND DIMENSIONS
t
w
l
Aperture opening for shield pad
is 2.7 mm x 1.25 mm as per land
pattern.
Adjacent Land Keepout and Solder
Mask Areas
Adjacent land keepout is the
maximum space occupied by the
unit relative to the land pattern.
There should be no other SMD
components within this area.
0.2 mm is the minimum solder
resist strip width required to
avoid solder bridging adjacent
pads.
Stencil Thickness, t (mm)
Aperture Size (mm)
Length, l
Width, w
0.152 mm
2.60 ± 0.05
0.55 ± 0.05
0.127 mm
3.00 ± 0.05
0.55 ± 0.05
8.2
0.2
2.6
It is recommended that two
fiducial crosses be placed at midlength of the pads for unit
alignment.
Note: Wet/Liquid PhotoImageable solder resist/mask is
recommended.
9
SOLDER MASK
3.0
UNITS: mm
PCB Layout Suggestion
The following PCB layout shows a
recommended layout that should
result in good electrical and EMI
performance. Things to note:
Component Side
1. The ground plane should be
continuous under the part, but
should not extend under the
shield trace.
C3
C1
5. VLED can be connected to
either unfiltered or unregulated power. If C1 is used, and
if VLED is also connected to
VCC, the connection should be
before the C1 cap.
10
Circuit Side
SHIELD
GROUND
VCC
RXD
TXD
SHUTDOWN
4. C1, C2, and C3 are optional
supply filter capacitors; it may
be left out if the supply is
clean.
VLED
GROUND
3. The AGND pin is connected to
the ground plane and not to
the shield tab.
C2
I/O VCC
2. The shield trace is a wide, lowinductance trace back to the
system ground.
Pick and Place Misalignment
Tolerance and Self-Alignment after
Solder Reflow
If the printed solder paste volume
is adequate, the HSDL-3202 will
self-align after solder reflow.
Units should be properly reflowed
in IR/hot air convection oven
using the recommended reflow
profile. The direction of board
travel does not matter.
Tolerance for Rotational (θ)
Misalignment
Mounted units should not be
rotated more than ± 3 degrees
with reference to center X-Y as
shown in the direction definition.
Units that are rotated more than
± 3 degrees will not self-align
after solder reflow. Units with
less than a ± 3 degree misalignment will self-align after solder
reflow.
Recommended Solder Paste/Cream
Volume for Castellation Joints
Based on calculation and experiment, the printed solder paste
volume required per castellation
pad is 0.22 cubic mm (based on
either no-clean or aqueous solder
cream types with typically 60% to
65% solid content by volume).
Using the recommended stencil
will result in this volume of solder
paste.
Direction Definition
Y
X
θ
Y-axis Misalignment of Castellation
In the Y direction, the HSDL3202 does not self-align after
solder reflow. Agilent recommends that the part be placed in
line with the fiducial mark (midlength of land pad). This will
enable sufficient land length
(minimum of 1/2 land length) to
form a good joint. See the
drawing below.
Allowable Misalignment
Direction
Tolerance
X
≤ 0.2 mm
Y
See text
θ
≤ ± 3 degrees
Tolerance for X-axis Alignment of
Castellation
Misalignment of castellation to
the land pad should not exceed
0.2 mm or about one-half the
width of the castellation during
placement of the unit. The
castellations will self-align to the
pads during solder reflow.
11
EDGE
MINIMUM 1/2 THE LENGTH
OF THE LAND PAD
FIDUCIAL
Reflow Profile
MAX. 245°C
T – TEMPERATURE – (°C)
230
R3
200
183
170
150
R2
90 sec.
MAX.
ABOVE
183°C
125
R1
100
R4
R5
50
25
0
50
100
150
200
250
300
t-TIME (SECONDS)
P1
HEAT
UP
P2
SOLDER PASTE DRY
P3
SOLDER
REFLOW
P4
COOL
DOWN
Process Zone
Symbol ∆T
Maximum ∆T/∆time
Heat Up
P1, R1
25°C to 125°C
4°C/s
Solder Paste Dry P2, R2
125°C to 170°C
0.5°C/s
Solder Reflow
P3, R3
170°C to 230°C (245°C max.) 4°C/s
P3, R4
230°C to 170°C
–4°C/s
P4, R5
170°C to 25°C
–3°C/s
Cool Down
The reflow profile is a straight
line representation of a nominal
temperature profile for a convective reflow solder process. The
temperature profile is divided
into four process zones, each
with different ∆T/∆time temperature change rates. The ∆T/∆time
rates are detailed in the above
table. The temperatures are
measured at the component to
printed-circuit board
connections.
In process zone P1, the PC
board and HSDL-3202
castellation I/O pins are heated to
a temperature of 125°C to activate the flux in the solder paste.
The temperature ramp-up rate,
R1, is limited to 4°C per second
to allow for even heating of both
the PC board and HSDL-3202
castellation I/O pins.
12
Process zone P2 should be of
sufficient time duration (> 60
seconds) to dry the solder paste.
The temperature is raised to a
level just below the liquidus point
of the solder, usually 170°C
(338°F).
Process zone P3 is the solder
reflow zone. In zone P3, the temperature is quickly raised above
the liquidus point of solder to
230°C (446°F) for optimum results. The dwell time above the
liquidus point of solder should be
between 15 and 90 seconds. It
usually takes about 15 seconds to
assure proper coalescing of the
solder balls into liquid solder and
the formation of good solder
connections. Beyond a dwell time
of 90 seconds, the intermetallic
growth within the solder connections becomes excessive, result-
ing in the formation of weak and
unreliable connections. The temperature is then rapidly reduced
to a point below the solidus
temperature of the solder, usually
170°C (338°F), to allow the
solder within the connections to
freeze solid.
Process zone P4 is the cool
down after solder freeze. The
cool down rate, R5, from the
liquidus point of the solder to
25°C (77°F) should not exceed
–3°C per second maximum. This
limitation is necessary to allow
the PC board and HSDL-3202
castellation I/O pins to change
dimensions evenly, putting minimal stresses on the HSDL-3202
transceiver.
Window Design
To ensure IrDA compliance, some
constraints on the height and
width of the window exist. The
minimum dimensions ensure that
the IrDA cone angles are met
without vignetting. The
maximum dimensions minimize
the effects of stray light. The
minimum size corresponds to a
cone angle of 30 degrees, the
maximum to a cone angle of
60 degrees.
The drawing below shows the
module positioned in front of a
window.
Minimum and Maximum Window Sizes
Dimensions are in mm.
Depth (Z)
Y min.
X min.
Y max.
X max.
0
1.70
6.80
3.66
8.76
1
2.23
7.33
4.82
9.92
2
2.77
7.87
5.97
11.07
3
3.31
8.41
7.12
12.22
4
3.84
8.94
8.28
13.38
5
4.38
9.48
9.43
14.53
6
4.91
10.01
10.59
15.69
7
5.45
10.55
11.74
16.84
8
5.99
11.09
12.90
18.00
9
6.52
11.62
14.05
19.15
10
7.06
12.16
15.21
20.31
Window Height Y vs. Module Depth Z
16
Z
Y
X
WINDOW HEIGHT Y – mm
14
12
10
ACCEPTABLE
RANGE
8
6
4
2
X = 5.1 +2(Z + D) tan θ
Y = 2(Z + D) tan θ
Where θ is the required half angle
for viewing. For the IrDA minimum, it is 15 degrees; for the
IrDA maximum, it is 30 degrees.
(D is the depth of the LED image
inside the part, 3.17 mm). These
equations result in the following
tables and graphs:
13
0
0
2
4
6
8
10
MODULE DEPTH Z – mm
Window Width X vs. Module Depth Z
22
20
WINDOW WIDTH X – mm
X is the width of the window, Y is
the height of the window, and Z is
the distance from the HSDL-3202
to the back of the window. The
distance from the center of the
LED lens to the center of the
photodiode lens is 5.1 mm. The
equations for the size of the
window are as follows:
18
16
14
ACCEPTABLE
RANGE
12
10
8
6
0
2
4
6
8
MODULE DEPTH Z – mm
10
Flat Window
Shape of the Window
From an optics standpoint, the
window should be flat. This ensures that the window will not
alter either the radiation pattern
of the LED, or the receive pattern
of the photodiode.
If the window must be curved for
mechanical design reasons, place
a curve on the back side of the
window that has the same radius
as the front side. While this will
not completely eliminate the lens
effect of the front curved surface,
it will reduce the effects. The
amount of change in the radiation
pattern is dependent upon the
material chosen for the window,
the radius of the front and back
curves, and the distance from the
back surface to the transceiver.
Once these items are known, a
lens design can be made which
will eliminate the effect of the
front surface curve.
The following drawings show the
effects of a curved window on the
radiation pattern. In all cases,
the center thickness of the window is 1.5 mm, the window is
made of polycarbonate plastic,
and the distance from the transceiver to the back surface of the
window is 3 mm.
14
Curved Front, Flat Back
(This option is not recommended
and should not be used.)
Curved Front and Back
(This option can be used if necessary for application purpose. A
large radius of curvature is
recommended and both front and
back should have the same
radius.)
Test Methods
Background Light and
Electromagnetic Field
There are four ambient interference conditions in which the
receiver is to operate correctly.
The conditions are to be applied
separately:
1. Electromagnetic Field:
3 V/m maximum (please refer
to IEC 801-3, severity level 3
for details).
2. Sunlight:
10 kilolux maximum at the
optical port. This is simulated
with an IR source having a
peak wavelength within the
range of 850 nm to 900 nm
and a spectral width of less
than 50 nm biased to provide
490 µW/cm2 (with no modulation) at the optical port. The
light source faces the optical
port.
This simulates sunlight within
the IrDA spectral range. The
effect of longer wavelength
radiation is covered by the
incandescent condition.
3. Incandescent Lighting: 1000
lux maximum. This is produced with general service,
tungsten-filament, gas-filled,
inside frosted lamps in the
60 Watt to 100 Watt range to
15
generate 1000 lux over the
horizontal surface on which
the equipment under test rests.
The light sources are above the
test area. The source is
expected to have a filament
temperature in the 2700 to
3050 Kelvin range and a
spectral peak in the 850 to
1050 nm range.
4. Fluorescent Lighting:
1000 lux maximum. This is
simulated with an IR source
having a peak wavelength
within the range of 850 nm to
900 nm and a spectral width of
less than 50 nm biased and
modulated to provide an
optical square wave signal
(0 µW/cm2 minimum and 0.3
µW/cm2 peak amplitude with
10% to 90% rise and fall times
less than or equal to 100 ns)
over the horizontal surface on
which the equipment under
test rests. The light sources are
above the test area. The frequency of the optical signal is
swept over the frequency
range from 20 kHz to 200 kHz.
Due to the variety of fluorescent lamps and the range of IR
emissions, this condition is not
expected to cover all circumstances. It will provide a common floor for IrDA operation.
www.semiconductor.agilent.com
Data subject to change.
Copyright © 2001 Agilent Technologies, Inc.
March 21, 2001
Obsoletes 5980-1500E (5/00)
5988-2313EN