LITEON HSDL-3208-021

HSDL-3208
Ultra Small Profile Package IrDA® Data Compliant
Low Power 115.2 kbit/s Infrared Transceiver
Data Sheet
Description
Features
The HSDL-3208 is an ultra-small low cost infrared
transceiver module that provides the interface between logic and infrared (IR) signals for through air,
serial, half-duplex IR data link. The module is compliant to IrDA Physical Layer Specifications version 1.4
Low Power from 9.6 kbit/s to 115.2 kbit/s with extended
link distance. It is IEC 825-Class 1 eye safe and able to
switch to Low Tx Power Mode when programming
sequence is applied to both SD and TXD inputs.
• Fully compliant to IrDA 1.4 low power specification from
9.6 kbit/s to 115.2 kbit/s
• Miniature package
– Height: 1.60 mm
– Width: 7.00 mm
– Depth: 2.80 mm
• Miniature package (with shield)
– Height: 1.80 mm
– Width: 7.40 mm
– Depth: 2.90 mm
• Guaranteed temperature performance, -25 to +70°C
– Critical parameters are guaranteed over temperature
and supply voltage
• Low power consumption
– Low shutdown current (1 nA typical)
– Complete shutdown of TXD, RXD, and PIN diode
• Withstands >100 mVp-p power supply ripple typically
• Excellent EMI performance without shield
• VCC supply 2.4 to 3.6 volts
• LED stuck-high protection
• Designed to accommodate light loss with cosmetic
windows
• IEC 825-class 1 eye safe
• Lead-free and RoHS compliant
The HSDL-3208 can be shut down completely to
achieve very low power consumption. In the shutdown
mode, the PIN diode will be inactive and thus producing very little photocurrent even under very bright
ambient light. Such features are ideal for battery
operated handheld products.
VCC
CX2
Applications
SD (5)
RXD (4)
CX1
RECEIVER
VCC (6)
HSDL-3208
GND (7)
• IRFM
• Mobile telecom
– Cellular phones
– Pagers
– Smart phones
• Data communication
– PDAs
– Portable printers
• Digital imaging
– Digital cameras
– Photo-imaging printers
TXD (3)
LED C (2)
VCC
TRANSMITTER
R1
LED A (1)
7
Figure 1. Functional block diagram of HSDL-3208.
6
5
4
3
2
1
Figure 2. Rear view diagram with pinout.
Application Support
Information
technical understanding
associated with HSDL-3208
infrared transceiver module. You
can contact them through your
local Lite-On sales representatives
for additional details.
The Application Engineering
group in Lite-On Technology is
available to assist you with the
Order Information
Part Number
Packaging Type
Package
Quantity
HSDL-3208-021
Tape and Reel
Front View
2500
Marking Information
The unit is marked with ‘YWL’ on the back of the PCB for front option
without shield.
Y = year
W = work week
L = lot information
I/O Pins Configuration Table
Pin
Symbol
Description
I/O Type
Notes
1
LED A
LED Anode
Input
1
2
LED C
LED Cathode
3
TXD
Transmit Data
Input, Active High
3
4
RXD
Receive Data
Output, Active Low
4
5
SD/Mode
Shutdown
Input, Active High
5
6
VCC
Supply Voltage
Supply Voltage
6
7
GND
Ground
Ground
7
2
Notes:
1. This pin can be connected directly to VCC (i.e. without series resistor) at less than 3 V.
2. Leave this pin unconnected.
3. This pin is used to transmit serial data when SD pin is low. Do not float the pin. This pin has an internal 500 kΩ pulldown with a typical input
capacitance of 2 pF.
4. This pin is capable of driving a standard CMOS or TTL load. No external pull-up or pull down resistor is required. It is in tri-state
mode when the transceiver is in shutdown mode. This pin tristates with a weak 500 kΩ pullup resistor.
5. The transceiver is in shutdown mode if this pin is high. Do not float the pin.
6. Regulated, 2.4 to 3.6 volts.
7. Connect to system ground.
Recommended Application Circuit Components
Component
Recommended Value
Notes
R1
30 Ω ± 5%, 0.25 Watt for 2.4 <= VCC <= 3.6 V
CX1
0.47 µF ± 20%, X7R Ceramic
8
CX2
6.8 µF ± 20%, Tantalum
9
Notes:
8. CX1 must be placed within 0.7 cm of the HSDL-3208 to obtain optimum noise immunity.
9. In environments with noisy power supplies, supply rejection performance can be enhanced
by including CX2, as shown in “Figure 1: HSDL-3208 Functional Block Diagram” in Page 1.
2
TX Power Mode Switching
The transceiver is in default High TX Power Mode
upon powered on. User needs to apply the following
programming sequence to both SD and TXD inputs
to switch the module to Low TX Power Mode. Both
settings of High TX Power and Low TX Power Mode
can be achieved as follows:
VIH
SD/MODE
VIH
SD/MODE
50%
50%
VIL
tS
VIL
tH
tS
tH
VIH
TXD
50%
50%
TXD
50%
50%
VIL
VIL
Figure 3. High power mode selection timing diagram.
Figure 4. Low power mode selection timing diagram.
1. Set SD/Mode input to logic High.
2. TXD input should remain at logic Low.
3. After waiting for ts ≥ 25 ns, set SD/Mode to logic
Low. The High to Low negative edge transition will
determine the TX Power Mode.
4. Ensure that TXD input remains low for tH ≥ 100 ns.
The transmitter is now in High mode.
5. SD input pulse width for mode selection should be
> 50 ns.
1. Set SD/Mode input to logic High.
2. After SD/Mode input remains High at > 25 ns, set
TXD input to logic High, wait ts ≥ 25 ns (from 50%
of TXD rising edge until 50% of SD falling edge).
3. Then set SD/Mode to logic Low. The High to Low
negative edge transition will determine the TX
Power Mode.
4. After waiting for tH ≥ 100 ns, set the TXD input to
logic Low.
5. SD input pulse width for mode selection should be
> 50 ns.
3
CAUTIONS: The BiCMOS inherent to the design of this component increases the component’s susceptibility to
damage from the 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.
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 Anode Voltage
VLEDA
0
6.5
V
Supply Voltage
VCC
0
6.5
V
Input Voltage: TXD, SD/Mode
VI
0
6.5
V
Output Voltage: RXD
VO
0
6.5
V
DC LED Transmit Current
ILED (DC)
50
mA
Peak LED Transmit Current
ILED (PK)
250
mA
Notes
10
Note:
10. ≤ 20% duty cycle, ≤ 90 µs pulse width.
Recommended Operating Conditions
Parameter
Symbol
Min.
Operating Temperature
TA
Supply Voltage
Max.
Units
-25
70
°C
VCC
2.4
3.6
V
Logic Input Voltage Logic High
for TXD, SD/Mode
Logic Low
VIH
2/3 VCC
VCC
V
VIL
0
1/3 VCC
V
Receiver Input
Irradiance
Logic High
EIH
0.0081
500
mW/cm2
For in-band signals ≤ 115.2kbit/s[11]
Logic Low
EIL
1
µW/cm2
For in-band signals[11]
LED (Logic High) Current
Pulse Amplitude
Receiver Data Rate
ILEDA
Typ.
50
9.6
Conditions
mA
115.2
kbit/s
Note:
11. An in-band optical signal is a pulse/sequence where the peak wavelength, λp, is defined as 850 ≤ λp ≤ 900 nm, and the pulse characteristics
are compliant with the IrDA Serial Infrared Physical Layer Link Specification v1.4.
4
Electrical & Optical Specifications
Specifications (Min. & Max. values) hold over the recommended operating conditions unless otherwise noted.
Unspecified test conditions may be anywhere in their operating range. All typical values (Typ.) are at 25°C with VCC set to
3.0 V unless otherwise noted.
Parameter
Symbol
Min.
Typ.
Max.
Units
Conditions
Viewing Angle
2θ
30
Peak Sensitivity Wavelength
λp
RXD Output
Voltage
Logic High
VOH
VCC-0.2
VCC
V
IOH = -200 µA, EI ≤ 1 µW/cm2
Logic Low
VOL
0
0.4
V
IOL = 200 µA, EI ≥ 8.1 µW/cm2
RXD Pulse Width (SIR)
tPW (SIR) 1
4.0
µs
θ ≤ 15°, CL =12 pF
RXD Rise and Fall Times
tr, tf
50
ns
CL =12 pF
Receiver Latency Time
tL
70
µs
Receiver Wake Up Time
tW
90
µs
Receiver
°
880
nm
Transmitter
High Power IEH
4
8
mW/sr
ILEDA = 50 mA, θ ≤ 15°, VTXD ≥ VIH
T = 25°C
Low Power IEH
2.4
4.8
mW/sr
ILEDA = 30 mA, θ ≤ 15°, VTXD ≥ VIH
T = 70°C, VCC = 2.4 V
Viewing Angle
2θ
30
Peak Wavelength
λp
875
nm
Spectral Line Half Width
∆λ
35
nm
TXD Input Current
High
IH
0.02
10
µA
VI ≥ VIH
Low
IL
-0.02
10
µA
0 ≤ VI _≤ VIL
On
IVLED
50
mA
VI (TXD) ≥ VIH, VI (SD) ≤ VIL
Shutdown
IVLED
20
100
nA
VI (SD) ≥ VIH
tPW (SIR) 1.5
1.6
1.8
µs
tPW (TXD) = 1.6 µs at 115.2 kbit/s
25
100
µs
600
ns
tpw (TXD) = 1.6 µs
Radiant Intensity
LED Current
Optical Pulse Width (SIR)
Maximum Optical PW tPW(max.)
TXD Rise and Fall Time (Optical)
LED Anode
on State Voltage
LED Anode Current
-10
60
tr, tf
°
High Power VON(LEDA)
1.7
1.8
V
ILEDA = 50 mA, VI(TXD) ≥ VIH
Low Power VON(LEDA)
2.1
2.25
V
ILEDA = 30 mA, VI(TXD) ≥ VIH
T = 70°C, VCC = 2.4 V
Low Power ILEDA
32
42
mA
max. current measured at VLED = 4.3 V
and R = 33 Ω
Shutdown
ICC1
0.001 1
µA
VSD ≥ VCC -0.5, TA = 25°C
Idle
ICC2
100
200
µA
VI (TXD) ≤ VIL, EI = 0
Active
Receiver
ICC3
0.8
3.1
mA
VCC = 3.6 V, VI(TXD)≤ 1/3 VCC[12]
Transceiver
Supply Current
Notes:
12. Typical value is at EI = 10 mW/cm2, maximum value is at EI = 500 mW/cm2.
5
tpw
tpw
VOH
LED ON
90%
90%
50%
50%
10%
VOL
10%
LED OFF
tf
tr
tr
Figure 5. RXD output waveform.
Figure 6. LED optical waveform.
TXD
SD
RX
LIGHT
LED
RXD
tpw (MAX.)
tRW
Figure 7. TXD "stuck on" protection waveform.
Figure 8. Receiver wakeup time waveform.
SD
TXD
TX
LIGHT
tTW
Figure 9. TXD wakeup time waveform.
19
90.0E-3
17
15
13
11
7
45.0E-3
80.0E-3
70.0E-3
60.0E-3
50.0E-3
9
65.0E-3
85.0E-3
AVE. TXD ILED_A (A)
Figure 10. LOP vs. ILED.
6
AVE. TXD ILED_A vs. AVE. TXD VLED_A,
TEMPERATURE = 25°C
100.0E-3
AVE. TXD ILED_A (A)
AVE. RADIANT INTENSITY (mW/Sr)
AVE. TXD RADIANT INTENSITY vs. AVE. TXD ILED_A,
TEMPERATURE = 25°C
21
105.0E-3
40.0E-3
1.44 1.46 1.48 1.50 1.52 1.54 1.56 1.58 1.60
AVE. TXD VLED_A (V)
Figure 11. VLED vs. ILED.
tf
HSDL-3208 (Unshielded) Package Dimensions
0.80
2.80
MOUNTING CENTER
3.50
7.00 ± 0.10
1.60 ± 0.10
0.80
0.95
5.10
;;;
R 1.10
0.95
R 1.10
2.80
LED A LED C TXD
0.95 (6X)
0.34 (5X)
RXD
SD
1.60
0.80
VCC GND
0.60 (7X)
0.40 (2X)
Figure 12. Package outline dimensions. (Unit: mm, Tolerance: ± 0.2 mm)
7
HSDL-3208 (Unshielded) Tape and Reel Dimensions
4.0 ± 0.1
UNIT: mm
1.75 ± 0.1
+ 0.1
∅ 1.5 0
2.0 ± 0.1
POLARITY
PIN 7: GND
7.5 ± 0.1
16.0 ± 0.2
7.35 ± 0.1
PIN 1: LED A
2.93 ± 0.1
0.3 ± 0.05
4.0 ± 0.1
1.78 ± 0.1
PROGRESSIVE DIRECTION
EMPTY
PARTS MOUNTED
LEADER
(400 mm MIN.)
(40 mm MIN.)
EMPTY
(40 mm MIN.)
OPTION # "B" "C" QUANTITY
021
178
60
2500
UNIT: mm
DETAIL A
2.0 ± 0.5
B
C
∅ 13.0 ± 0.5
R 1.0
LABEL
21 ± 0.8
DETAIL A
2
16.4 + 0
2.0 ± 0.5
Figure 13. Tape and reel dimensions.
8
HSDL-3208 (Shielded) Package Dimensions
1. Unless otherwise stated, dimension tolerance: ± 0.2 mm.
2. Castellation length, mentioned below, is the minimum value i.e., 0.6 mm.
The specification is: 0.63 ± 0.03 mm.
3.7
MOUNTING CENTER
0.99
7.40 ± 0.10
+0.03
7.00 –0.00
1.80 ± 0.05
0.8
2.5
2.0
0.95
0.95
5.1
COPLANARITY =
–0.1 mm to 0.0 mm
R1.1
EMITTER
RECEIVER
0.95
2.9
0.6
1.6
1
2
3
4
5
6
7
0.2
6.96
0.64
+0.02
0.15 –0.01
Figure 14a. Package outline dimensions.
9
0.95
0.6
0.63 ± 0.03
1.97
HSDL-3208 (Shielded) Tape Dimensions
2.0 ± 0.10
Po
Do
P2
B
T
E
B-B SECTION
5°(MAX.)
F
W
Bo
A
A
B
P1
8 ± 0.10
Ko
D1
Ao
3°(MAX.)
A-A SECTION
UNIT: mm
SYMBOL
SPEC
SYMBOL
SPEC
Ao
Bo
Ko
Po
P1
P2
T
3.15 ± 0.10
7.70 ± 0.10
1.95 ± 0.10
4.00 ± 0.10
8.00 ± 0.10
2.35 ± 0.10
0.30 ± 0.10
E
F
Do
D1
W
10Po
1.75 ± 0.10
7.50 ± 0.10
1.55 ± 0.05
1.50 ± 0.10
16.00 ± 0.30
40.00 ± 0.20
+0.5
16 –0
+0.5
n 13.1 –0
62.3
+0.1
–0.1
+0.1
2.6 –0.1
PS
Figure 15. Tape dimensions.
10
Moisture Proof Packaging
Baking Conditions
All HSDL-3208 options are
shipped in moisture proof
package. Once opened, moisture
absorption begins.
If the parts are not stored in dry
conditions, they must be baked
before reflow to prevent damage
to the parts.
This part is compliant to JEDEC
Level 4.
Package
Temp.
Time
In reels
60°C
≥ 48 hours
In bulk
100°C
≥ 4 hours
125°C
≥ 2 hours
150°C
≥ 1 hour
UNITS IN A SEALED
MOISTURE-PROOF
PACKAGE
Baking should only be done once.
Recommended Storage
Conditions
PACKAGE IS
OPENED (UNSEALED)
ENVIRONMENT
LESS THAN 30°C,
AND LESS THAN
60% RH
YES
NO BAKING
IS NECESSARY
YES
11
Relative
Humidity
below 60% RH
After removal from the bag, the
parts should be soldered within
three days if stored at the recommended storage conditions.
NO
Figure 16. Baking conditions chart.
10°C to 30°C
Time from Unsealing to
Soldering
PACKAGE IS
OPENED LESS
THAN 72 HOURS
PERFORM RECOMMENDED
BAKING CONDITIONS
Storage
Temperature
NO
Recommended Reflow Profile
MAX. 260°C
T – TEMPERATURE – (°C)
255
R3
R4
230
220
200
R2
180
60 sec.
MAX.
ABOVE
220°C
160
R1
120
R5
80
25
0
50
100
150
200
250
300
t-TIME (SECONDS)
P1
HEAT
UP
P2
SOLDER PASTE DRY
P3
SOLDER
REFLOW
P4
COOL
DOWN
Figure 17. Reflow graph.
Process Zone
Symbol
∆T
Maximum ∆T/∆time
Heat Up
P1, R1
25°C to 160°C
4°C/s
Solder Paste Dry
P2, R2
160°C to 200°C
0.5°C/s
Solder Reflow
P3, R3
200°C to 255°C (260°C at 10 seconds max.)
4°C/s
P3, R4
255°C to 200°C
–6°C/s
P4, R5
200°C to 25°C
–6°C/s
Cool Down
The reflow profile is a straightline 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-3208 castellation I/O pins are heated to a
temperature of 160°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-3208
castellation I/O pins.
12
Process zone P2 should be of
sufficient time duration (60 to
120 seconds) to dry the solder
paste. The temperature is raised
to a level just below the liquidus
point of the solder, usually 200°C
(392°F).
Process zone P3 is the solder
reflow zone. In zone P3, the
temperature is quickly raised
above the liquidus point of solder
to 255°C (491°F) for optimum
results. The dwell time above the
liquidus point of solder should be
between 20 and 60 seconds. It
usually takes about 20 seconds to
assure proper coalescing of the
solder balls into liquid solder and
the formation of good solder
connections. Beyond a dwell time
of 60 seconds, the intermetallic
growth within the solder
connections becomes excessive,
resulting 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 200°C (392°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
6°C per second maximum. This
limitation is necessary to allow
the PC board and HSDL-3208
castellation I/O pins to change
dimensions evenly, putting
minimal stresses on the HSDL3208 transceiver.
HSDL-3208 (Unshielded)
1.0 Solder Pad, Mask and Metal
Stencil Aperture
METAL STENCIL
FOR SOLDER PASTE
PRINTING
STENCIL
APERTURE
LAND
PATTERN
SOLDER
MASK
PCBA
Figure 18. Stencil and PCBA.
1.1 Recommended Land Pattern
CL
MOUNTING
CENTER
0.10
0.775
1.75
FIDUCIAL
0.60
0.95
1.9
UNIT: mm
Figure 19. Stencil and PCBA.
13
2.85
1.2 Recommended Metal Solder
Stencil Aperture
It is recommended that only a
0.152 mm (0.006 inches) or a
0.127 mm (0.005 inches) 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.
Aperture opening for shield pad
is 2.7 mm x 1.25 mm as per land
pattern.
1.3 Adjacent Land Keepout and
Solder Mask Areas
Adjacent land keep-out is the
maximum space occupied by
the unit relative to the land
pattern. There should be no other
SMD components within this
area.
The minimum solder resist strip
width required to avoid solder
bridging adjacent pads is
0.2 mm. It is recommended that
two fiducial crosses be placed at
mid-length of the pads for unit
alignment.
APERTURES AS PER
LAND DIMENSIONS
t
w
l
Figure 20. Solder stencil aperture.
Aperture size(mm)
Stencil thickness, t (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
7.2
0.2
2.6
SOLDER MASK
Note: Wet/Liquid PhotoImageable solder resist/mask is
recommended.
UNITS: mm
Figure 21. Adjacent land keepout and solder mask areas.
14
3.0
Appendix A : SMT Assembly
Application Note
HSDL-3208 (Shielded)
2.0 Solder Pad, Mask and Metal
Stencil Aperture
METAL STENCIL
FOR SOLDER PASTE
PRINTING
STENCIL
APERTURE
LAND
PATTERN
SOLDER
MASK
PCBA
Figure 22. Stencil and PCBA.
2.1 Recommended Land Pattern
CL
SHIELD
SOLDER
PAD
1.35
1.25
2.05
0.20
MOUNTING
CENTER
0.925
1.45
FIDUCIAL
0.60
0.95
1.9
UNIT: mm
Figure 23. Land Pattern.
15
2.85
2.2 Recommended Metal Solder
Stencil Aperture
It is recommended that only a
0.152 mm (0.006 inches) or a
0.127 mm (0.005 inches) 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.
Aperture opening for shield pad
is 2.7 mm x 1.25 mm as per land
pattern.
2.3 Adjacent Land Keepout and
Solder Mask Areas
Adjacent land keep-out is the
maximum space occupied by
the unit relative to the land
pattern. There should be no other
SMD components within this
area.
The minimum solder resist strip
width required to avoid solder
bridging adjacent pads is
0.2 mm. It is recommended that
two fiducial crosses be placed at
mid-length of the pads for unit
alignment.
APERTURES AS PER
LAND DIMENSIONS
t
w
l
Figure 24. Solder stencil aperture.
Aperture size(mm)
Stencil thickness, t (mm)
length, l
width, w
0.152 mm
1.45 ± 0.05
0.55 ± 0.05
0.127 mm
1.45 ± 0.05
0.55 ± 0.05
8.2
0.2
2.6
3.0
Solder mask
Units: mm
Note: Wet/Liquid PhotoImageable solder resist/mask is
recommended.
16
Figure 25. Adjacent land keepout and solder mask areas.
Appendix B: PCB Layout
Suggestion
The HSDL-3208 is a shieldless part
and hence does not contain a shield
trace, unlike the other transceivers.
The following PCB layout guidelines should be followed to obtain a
good PSRR and EM immunity,
resulting in good electrical
performance. Things to note:
1. The AGND pin should be
connected to the ground plane.
ground connected board layers.
Refer to the diagram below for
an example of a 4-layer board.
The area underneath the module at
the second layer, and 3 cm in all
directions around the module, is
defined as the critical ground plane
zone. The ground plane should be
maximized in this zone. Refer to
application note AN1114 or the
Lite-On IrDA Data Link Design
Guide for details. The layout below
is based on a 2-layer PCB.
2. C1 and C2 are optional supply
filter capacitors; they may be left
out if a clean power supply is
used.
TOP LAYER
CONNECT THE METAL SHIELD AND MODULE
GROUND PIN TO BOTTOM GROUND LAYER.
3. VLED can be connected to either
unfiltered or unregulated power
supply. If VLED and VCC share
the same power supply and C1 is
used, the connection should be
before the current limiting
resistor R2. In a noisy environment, including capacitor C2 can
enhance supply rejection. C1 is
generally a ceramic capacitor of
low inductance providing a wide
frequency response while C2 is a
tantalum capacitor of big volume
and fast frequency response. The
use of a tantalum capacitor is
more critical on the VLED line,
which carries a high current.
4. Preferably a multi-layered board
should be used to provide
sufficient ground plane. Use the
layer underneath and near the
transceiver module as VCC, and
sandwich that layer between
LAYER 2
CRITICAL GROUND PLANE ZONE. DO NOT
CONNECT DIRECTLY TO THE MODULE
GROUND PIN.
LAYER 3
KEEP DATA BUS AWAY FROM CRITICAL
GROUND PLANE ZONE.
BOTTOM LAYER (GND)
Top View
Figure 26. PCB layout suggestion.
17
Bottom View
Appendix C : General
Application Guide for the
HSDL-3208 Infrared IrDA®
Compliant 115.2 kb/s
Transceiver
Description
The HSDL-3208 is an ultra-small
low-cost infrared transceiver
module that provides the interface
between logic and infrared (IR)
signals for through air, serial,
half-duplex IR data link. The
device is designed to address the
mobile computing market such as
PDAs, as well as small embedded
mobile products such as digital
cameras and cellular phones. It is
fully compliant to IrDA 1.4 low
power specification from 9.6 kb/s
to 115.2 kb/s, and supports HPSIR and TV Remote modes. The
design of the HSDL-3208 also
includes the following unique
features:
Interface to Recommended I/O Chips
The HSDL-3208’s TXD data input
is buffered to allow for CMOS
drive levels. No peaking circuit or
capacitor is required.
Data rate from 9.6 kb/s up to
115.2 kb/s is available at the RXD
pin.
• Low passive component count
• Shutdown mode for low power
consumption requirement
The diagram below shows how
the IR port fits into the mobile
phone platform and PDA
platform.
Selection of Resistor R1
Resistor R1 should be selected to
provide the appropriate peak
pulse LED current over different
ranges of VCC as shown in the
table below.
Recommended R1
VCC
Intensity
Minimum Peak Pulse
LED Current
30 Ω
3.3 V
9 mW/Sr
50 mA
SPEAKER
AUDIO INTERFACE
DSP CORE
MICROPHONE
ASIC
CONTROLLER
RF INTERFACE
TRANSCEIVER
MOD/
DE-MODULATOR
IR
MICROCONTROLLER
USER INTERFACE
HSDL-3208
Figure 27. IR layout in mobile phone platform.
18
LCD
PANEL
RAM
IR
HSDL-3208
CPU
FOR EMBEDDED
APPLICATION
ROM
PCMCIA
CONTROLLER
TOUCH
PANEL
RS232C
DRIVER
Figure 28. IR layout in PDA platform.
The link distance testing is done
using typical HSDL-3208 units
with National Semiconductor’s
PC87109 3V Super I/O Controller
and SMC’s FDC37C669 and
FDC37N769 Super I/O
controllers. An 115.2 kb/s
datarate IR link distance of up to
40 cm has been demonstrated.
19
COM
PORT
Appendix D: Window Designs for HSDL-3208
Optical port dimensions for
HSDL-3208:
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°
and the maximum size corresponds
to a cone angle of 60°.
In the figure below, X is the width
of the window, Y is the height of
the window and Z is the distance
from the HSDL-3208 to the back of
the window. The distance from the
center of the LED lens to the
center of the photodiode lens, K, is
5.1 mm. The equations for
computing the window dimensions
are as follows:
comparable, Z' replaces Z in the
above equation. Z' is defined as
Z' = Z + t/n
where ‘t’ is the thickness of the
window and ‘n’ is the refractive
index of the window material.
X = K + 2*(Z + D)*tanA
Y = 2*(Z + D)*tanA
The above equations assume that
the thickness of the window is
negligible compared to the
distance of the module from the
back of the window (Z). If they are
The depth of the LED image inside
the HSDL-3208, D, is 3.17 mm.
‘A’ is the required half angle for
viewing. For IrDA compliance, the
minimum is 150 and the maximum
is 300. Assuming the thickness of
the window to be negligible, the
equations result in the following
tables and graphs:
;;;;;;;;
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OPAQUE
MATERIAL
IR TRANSPARENT WINDOW
Y
X
IR TRANSPARENT
WINDOW
K
Z
A
D
Figure 29. Window design diagram.
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OPAQUE
MATERIAL
Aperture Width (x, mm)
Max.
Min.
8.76
6.80
9.92
7.33
11.07
7.87
12.22
8.41
13.38
8.94
14.53
9.48
15.69
10.01
16.84
10.55
18.00
11.09
19.15
11.62
APERTURE WIDTH (X) vs. MODULE DEPTH
APERTURE HEIGHT (Y) vs. MODULE DEPTH
16
20
15
10
X MAX.
X MIN.
5
0
0
1
2
3
4
5
6
7
8
9
MODULE DEPTH (Z) – mm
Figure 30. Aperture width (X) vs. module depth.
21
Aperture Height (y, mm)
Max.
Min.
3.66
1.70
4.82
2.33
5.97
2.77
7.12
3.31
8.28
3.84
9.43
4.38
10.59
4.91
11.74
5.45
12.90
5.99
14.05
6.52
25
APERTURE HEIGHT (Y) – mm
APERTURE WIDTH (X) – mm
Module Depth
(z) mm
0
1
2
3
4
5
6
7
8
9
14
12
10
8
6
4
Y MAX.
Y MIN.
2
0
0
1
2
3
4
5
6
7
8
9
MODULE DEPTH (Z) – mm
Figure 31. Aperture height (Y) vs. module depth.
Window Material
Almost any plastic material will
work as a window material.
Polycarbonate is recommended.
The surface finish of the plastic
should be smooth, without any
texture. An IR filter dye may be
used in the window to make it look
black to the eye, but the total
optical loss of the window should
be 10% or less for best optical
performance. Light loss should be
measured at 875 nm.
The recommended plastic
materials for use as a cosmetic
window are available from General
Electric Plastics.
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 or industrial design
reasons, place the same curve on
the back side of the window that
has an identical radius as the front
side. While this will not completely
eliminate the lens effect of the
front curved surface, it will
significantly 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.
Recommended Plastic Materials:
Material
Number
Lexan 141L
Lexan 920A
Lexan 940A
Light
Transmission
88%
85%
85%
Haze
1%
1%
1%
Refractive
Index
1.586
1.586
1.586
Note: 920A and 940A are more flame retardant than 141L.
Recommended Dye: Violet #21051 (IR transmissant above 625 nm).
Flat Window
(First Choice)
Figure 32. Shape of windows.
22
Curved Front and Back
(Second Choice)
Curved Front, Flat Back
(Do Not Use)
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http://optodatabook.liteon.com/databook/databook.aspx
Data subject to change. Copyright © 2007 Lite-On Technology Corporation. All rights reserved.
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