LITEON ASDL-3023

ASDL-3023
IrDA Data Compliant Low Power 4Mbit/s
with Remote Control Infrared Transceiver
Data Sheet
Description
Features
The ASDL-3023 is a new generation low profile high
speed enhanced infrared (IR) transceiver module that
provides the capability of (1) interface between logic
and IR signals for through-air, serial, half-duplex IR data
link, and (2) IR remote control transmission for universal
remote control applications. The ASDL-3023 can be used
for IrDA as well as remote control application without the
need of any additional external components for multiplexing.
General Features
The ASDL-3023 is fully compliant to IrDA Physical Layer
specification version 1.4 low power from 9.6 kbit/s to 4.0
Mbit/s (FIR) and IEC825 Class 1 eye safety standards.
The ASDL-3023 can be shutdown 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. It is
also designed to interface to input/output logic circuits as
low as 1.5V. These features are ideal for battery operated
mobile devices such as PDAs and mobile phones that
require low power consumption.
Applications
Mobile data communication and universal remote control
• Mobile Phones
• PDAs
• Digital Still Camera
• Printer
• Handy Terminal
• Industrial and Medical Instrument
Application Support Information
The Application Engineering Group is available to assist
you with the application design associated with ASDL3023 infrared transceiver module. You can contact them
through your local sales representatives for additional
details.
• Operating temperature from -25° C ~ 85°C
- Critical parameters are guaranteed over temperature and supply voltage
• Vcc Supply 2.4 to 3.6 V
• Interface to Various Super I/O and Controller Devices
- Input/Output Interface Voltage of 1.5 V
• Miniature Package
Miniature Package (shielded)
Height : 1.75 mm
Height : 1.95 mm
Width : 7.5 mm
Width : 8.0 mm
Depth : 2.75 mm Depth : 3.00 mm
• Moisture Level 3
• Power Saving using 3 ILED range (SIR, MIR/FIR, RC
mode)
• LED stuck high protection
• High EMI Performance
• High ESD Performance
• Designed to Accommodate Light Loss with Cosmetic
Windows
• IEC 825-Class 1 Eye Safe
IrDA Features
• Fully Compliant to IrDA 1.4 Physical Layer Low Power
Specifications from 9.6 kbit/s to 4.0 Mb/s
- Link distance up to 30cm (minimum)
• Complete shutdown
• Low Power Consumption
- Low shutdown current
- Low idle current
Remote Control Features
• Wide angle and high radiant intensity
• Spectrally suited to remote control transmission
function
• Minimum peak wavelength of 880nm
• 2 RC Transmission Mode
- Single TXD (Programmable Mode)
- Dual TXD (Direct)
Vdd
R1
GND
CX2
Vdd
(7)
CX1
GND (8)
ASDL-3023 TRANSCEIVER
MODULE
IOVCC(5)
CX5
TRANSCEIVER
IC
Regulated
Voltage &
Current
Source
SD(4)
Photodetector
RECEIVER
VLED
CX4
LEDA (1)
TRANSMITTER
TXD_RC
Input
TxD_IR(2)
TXD_IR
Input
Figure 1a. Functional Block Diagram of ASDL-3023
Eye
Safety-RC
Eye
Safety-IR
Switched
Current
Source
IR_Buffer
TxD_RC(6)
TRANSMIT
TER
AGC & Signal
Reference
Processor
RC_Buffer
CX3
R2
Amplifier
Output�
Buffer
RXD(3)
Low Pass
Filter
LED
Vdd
R1
GND
CX2
Vdd
(7)
CX1
GND (8)
ASDL-3023 TRANSCEIVER
MODULE
IOVCC(5)
CX5
SD(4)
TRANSCEIVER
IC
Regulated
Voltage &
Current
Source
Photodetector
RECEIVER
CX4
LEDA (1)
TRANSMITTER
TXD_RC
Input
TxD_IR(2)
TXD_IR
Input
Figure 1b. Functional Block Diagram of ASDL-3023-S21
Eye
Safety-RC
Eye
Safety-IR
Switched
Current
Source
IR_Buffer
TxD_RC(6)
TRANSMIT
TER
AGC & Signal
Reference
Processor
RC_Buffer
CX3
R2
SHIELD
VLED
Amplifier
Output
Buffer
RXD(3)
Low Pass
Filter
LED
Order Information
Part Number
Packaging Type
Package
Quantity
ASDL-3023-021
Tape and Reel
Front Option
2500
ASDL-3023-008
Tape and Reel
Top Option
2500
ASDL-3023–S21 (Shielded)
Tape and Reel
Front Option
2500
Marking Information
The unit is marked with ‘XYWLL’ on the shield
Y = year
W = work week
LL = lot number
ASDL-3023-021, ASDL-3023-008 and ASDL-3023-S21
Pinout, Rear View
I/O Pins Configuration Table
Rear View
8
7
6
5
4
3
2
1
Figure 2a. Pin out for ASDL-3023-021 and ASDL-3023-008,
Rear View
8
7
6
5
4
(Shielded)
3
Figure 2b. Pin out for ASDL-3023-S21
2
1
Pin
Symbol
Description
I/O Type
Notes
1
LEDA
LED Anode
2
TxD_IR
IrDA transmitter data input.
Input. Active High
Note 2
3
RxD
IrDA receive data
Output. Active Low
Note 3
4
SD
Shutdown
Input. Active High
Note 4
5
IOVCC
Input/Output ASIC voltage
6
TxD_RC
RC transmitter data input.
7
VCC
Supply Voltage
Note 7
8
GND
Ground
Note 8
Note 1
Note 5
Input. Active High
Note 6
Notes:
1. Tied through external resistor, R2, to Vled. Refer to the table below for recommended series resistor value.
2. This pin is used to transmit serial data when SD pin is low. If held high for longer than 50 ms, the LED is turned off. Do NOT float this pin.
3. This pin is capable of driving a standard CMOS or TTL load. No external pull-up or pull-down resistor is required. The pin is in tri-state when the
transceiver is in shutdown mode
4. Complete shutdown of IC and PIN diode. The pin is used for setting IR receiver bandwidth, range of IR LED current and RC drive programming
mode. Refer to section on “Bandwidth Selection Timing” and “Remote Control Drive Modes” for more information. Do NOT float this pin. ***
5. Connect to ASIC logic controller supply voltage or Vcc. The voltage at this pin should be equal to or less than Vcc.
6. Logic high turns on the RC LED. If held high longer than 50 ms, the RC LED is turned off. Do NOT float the pin.
7. (i) Regulated, 2.4V to 3.6V
(ii) This pin recommended to turn on before other pin.
8. Connect to system ground.
Recommended Application Circuit Components
Component
Recommended Value
R1
4.7W,±5%, 0.25 watt for Vcc ≤ 3.0V
Note
R2
2.7W, for 2.4 ≤ VLED ≤ 2.7V;
3.3W, for 2.7 <VLED ≤ 3.0V
3.9W, for 3.0 <VLED ≤ 3.3V
4.7W, for 3.3 <VLED ≤ 3.6V
5.6W, for 3.6 <VLED ≤ 4.2V
10W, for 4.2 <VLED ≤ 5V
CX1, CX3, CX5
100 nF, ± 20%, X7R Ceramic
1
CX2, CX4
4.7mF, ± 20%, Tantalum
1
Notes: CX1, CX2, CX3 & CX4 must be placed within 0.7cm of ASDL-3023
to obtain optimum noise immunity
Absolute Maximum Ratings
For implementations where case to ambient thermal resistance is ± 50°C/W.
Parameter
Symbol
Min.
Max.
Units
Conditions
Ref
Storage Temperature
TS
-40
+100
°C
Operating Temperature
TA
-25
+85
°C
LED Anode Voltage
VLEDA
-0.3
6.5
V
Supply Voltage
VCC
-0.3
6
V
Input Voltage : TXD, SD/Mode
VI
-0.3
5.5
V
Output Voltage : RXD
VO
-0.3
5.5
V
Peak IR LED Current
IIRLED (PK)
200
mA
≤ 25% duty cycle, ≤ 90 ms pulse width Fig 3
Peak RC LED Current
IRCLED(PK)
300
mA
≤ 10% duty cycle, ≤ 90 ms pulse width Fig 4
CAUTION: The CMOS inherent to the 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
Recommended Operating Conditions
Parameter
Symbol Min.
Max.
Units
Operating Temperature
TA
-25
Typ.
+85
°C
Supply Voltage
VCC
2.4
3.6
V
Conditions
IOVCC
1.5
3.6
V
Logic Input Voltage for TXD,
SD/Mode
Logic High
VIH
IOVcc-0.5
IOVcc
V
Logic Low
VIL
0
0.4
V
Receiver Input Irradiance
Logic High
EIH
0.0090
500
0.0225
500
mW/cm2 For in-band signals ≤
115.2kbit/s [3] 0.576 Mbit/s ≤ in-band
signals ≤ 4.0 Mbit/s [3]
Input/Output Voltage
Logic Low
EIL
IR LED (Logic High) Current
Pulse Amplitude – SIR Mode
ILEDA
IR LED (Logic High) Current
Pulse Amplitude – MIR/FIR
Mode
ILEDA
RC LED (Logic High) Current
Pulse Amplitude
ILEDA
Receiver Data Rate
Ambient Light
0.3
65
For in-band signals [3]
mA
mA
150
250
0.0096
mW/cm2
mA
4.0
Mbit/s
See IrDA Serial Infrared
Physical Layer Link
Specification, Appendix A
for ambient levels
Note :
3. An in-band optical signal is a pulse/sequence where the peak wavelength, lp, is defined as 850 ≤ lp ≤ 900 nm, and the pulse characteristics are
compliant with the IrDA Serial Infrared Physical Layer Link Specification v1.4.
Electrical and 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, Vcc set to 3.0V and
IOVcc set to 1.5V unless otherwise noted.
Receiver
Parameter
Symbol
Viewing Angle
Peak Sensitivity Wavelength
RxD_IrDA Output Voltage
2q1/2
lP
Logic High VOH
RxD_IrDA Pulse Width (SIR)
Logic Low VOL
tRPW(SIR)
[4, 5]
Min.
Typ.
Max.
Units
Conditions
IOVcc
– 0.5
0
1
IOVCC
°
nm
V
IOH = -200 mA, EI ≤ 0.3 mW/cm2
0.4
4
V
ms
q1/2 ≤ 15°, CL=9pF
30
875
RxD_IrDA Pulse Width (MIR)
tRPW(MIR)
100
500
ns
q1/2 ≤ 15°, CL=9pF
RxD_IrDA Pulse Width (Single) (FIR) [4, 7]
RxD_IrDA Pulse Width (Double) (FIR) [4, 7]
RxD_IrDA Rise & Fall Times
Receiver Latency Time [8]
Receiver Wake Up Time [9]
tRPW(FIR)
tRPW(FIR)
tr, tf
tL
tRW
80
200
175
290
100
200
ns
ns
ns
ms
ms
q1/2 ≤ 15°, CL=9pF
q1/2 ≤ 15°, CL=9pF
CL=9pF
EI = 9.0 mW/cm2
EI = 10 mW/cm2
Parameter
Symbol
Min.
Typ.
Max.
Units
Conditions
IR Radiant Intensity
(SIR Mode)
IR Radiant Intensity (MIR/FIR
Mode)
IR Viewing Angle
IR Peak Wavelength
TxD_IrDA Logic Levels
IEH
4
20
mW/sr
IEH
10
50
mW/sr
IR_ILEDA = 65mA,
q1/2 ≤ 15°, TxD_IR ≥ VIH, TA = 25°C
IR_ILEDA = 150mA,
q1/2 ≤ 15°, TxD_IR ≥ VIH, TA = 25°C
2q1/2
lP
VIH
VIL
IH
IL
tTW
tPW(Max)
30
850
IOVcc-0.5
0
[4, 6]
60
Infrared (IR) Transmitter
TxD_IrDA Input Current
Wake Up Time [10]
Maximum Optical Pulse
Width [11]
TXD Pulse Width (SIR)
High
Low
High
Low
885
0.02
-0.02
180
25
60
900
IOVCC
0.5
120
°
nm
V
V
mA
mA
ns
ms
tPW(SIR)
1.6
ms
TXD Pulse Width (MIR)
tPW(MIR)
217
ns
TXD Pulse Width (FIR)
TxD Rise & Fall Times (Optical)
tPW(FIR)
tr, tf
125
IR LED Anode On-State
Voltage (SIR Mode)
IR LED Anode On-State
Voltage (MIR/FIR Mode)
VON
2.2
ns
V
2.1
V
600
40
ns
ns
(IR_LEDA)
VON
(IR_LEDA)
VI ≥ VIH
0 ≤ VI ≤ VIL
tPW(TXD_IR)=1.6ms at 115.2
kbit/s
tPW(TXD_IR)=217ns at 1.152
Mbit/s
tPW(TXD_IR)=125ns at 4.0 Mbit/s
tPW(TXD_IR)=1.6ms at 115.2
kbit/s
tPW(TXD_IR)=125ns at 4.0 Mbit/s
IR_ILEDA=65mA,
IR VLED = 3.6V,
R = 4.7W, VI(TxD) ≥ VIH
IR_ILEDA=150mA,
IR VLED = 3.6V,
R = 4.7W,
VI(TxD_IR) ≥ VIH
Remote Control (RC) Transmitter
Parameter
Symbol
RC Radiant Intensity
IEH
RC Viewing Angle
2q1/2
30
RC Peak Wavelength
lP
880
High
VIH
IOVcc-0.5
Low
VIL
0
High
IH
0.02
Low
IL
-0.02
VON
2
TxD_RC Logic Levels
TxD_RC Input Current
RC LED Anode On-State
Voltage
Min.
Typ.
Max.
80
885
Units
Conditions
mW/sr
RC_ILEDA = 250mA,
q1/2 ≤ 15°, TxD_RC ≥ VIH, TA = 25 °C
60
°
900
nm
IOVCC
V
0.5
V
1
mA
VI ≥ VIH
1
mA
0 ≤ VI ≤ VIL
V
RC_ILEDA=250mA, RC VLED = 3.6V,
R = 4.7W, VI(TxD_RC) ≥ VIH
(RC_LEDA)
Transceiver
Parameters
Symbol
Input Current
Supply Current
Min.
Typ.
Max.
Units
Conditions
0.01
1
mA
VI ≥ VIH
-0.02
1
mA
0 ≤ VI ≤ VIL
1
mA
VSD ≥ IOVCC-0.5, TA=25°C
2.9
mA
VI(TxD) ≤ VIL, EI=0
mA
VI(TxD) ≥ VIL, EI=10mW/cm2
High
IH
Low
IL
Shutdown
ICC1
Idle
(Standby)
ICC2
2.0
Active
ICC3
3.5
-1
Note:
[4] An in-band optical signal is a pulse/sequence where the peak wavelength, lP, is defined as 850 nm ≤ lP ≤ 900 nm, and the pulse characteristics
are compliant with the IrDA Serial Infrared Physical Layer Link Specification version 1.4.
[5] For in-band signals 115.2 kbit/s where 9 mW/cm2 ≤ EI ≤ 500 mW/cm2.
[6] For in-band signals 1.152 Mbit/s where 22 mW/cm2 ≤ EI ≤ 500 mW/cm2.
[7] For in-band signals 4 Mbit/s where 22 mW/cm2 ≤ EI ≤ 500 mW/cm2.
[8] Latency is defined as the time from the last TxD_IrDA light output pulse until the receiver has recovered full sensitivity.
[9] Receiver Wake Up Time is measured from Vcc power ON to valid RxD_IrDA output.
[10] Transmitter Wake Up Time is measured from Vcc power ON to valid light output in response to a TxD_IrDA pulse.
[11] The Max Optical PW is defined as the maximum time which the IR LED will turn on, this, is to prevent the long Turn On time for the IR LED.
Max. Permissible Peak LED Current
I LED(DC) , Maximum DC LED Current - mA
ILED(PK) Maximum Peak LED Current - mA
350
300
250
200
150
100
50
0
-40
-20
0
20
40
60
TA - Ambient Temperature - oC
80
100
Figure 3. Maximum Peak IR LED current vs. ambient temperature. Derated
based on TJMAX = 100°C.
Max. Permissible DC LED Current
70
60
50
40
R ja = 400degC/W
30
20
10
0
-40
-20
0
20
40
60
TA - Ambient Temperature - oC
80
100
Figure 4. Maximum Peak RC LED current vs. ambient temperature. Derated
based on TJMAX = 100°C.
Figure 5a. Timing Waveform - RXD Output Waveform
Figure 5b. Timing Waveform - LED Optical Waveform
Figure 5c. Timing Waveform – TXD “Stuck-on” Protection Waveform
Figure 5d. Timing Waveform – Receiver Wakeup Time Waveform
Figure 5e. Timing Waveform – TXD Wakeup Time Waveform
Package Dimension: ASDL-3023-021 (Shieldless, Front) and ASDL-3023-008 (Shieldless, Top)
10
Package Dimension: ASDL-3023-S21 (Shielded, Front)
11
Tape & Reel Dimensions
ASDL-3023-021 (Shieldless, Front)
ASDL-3023-008 (Shieldless, Top)
12
ASDL-3023-S21 (Shielded, Front)
Progressive Direction
Empty
Parts Mounted
Leader
(400mm min)
(40mm min)
Empty
(40mm min)
Option #
"B"
"C"
Quantity
021
330
80
2500
S21
330
2500
008
330
80
80
2500
Unit: mm
Detail A
2.0 ± 0.5
B
C
13.0 ± 0.5
R1.0
LABEL
21 ± 0.8
Detail A
16.4
+2
0
2.0 ± 0.5
13
ASDL-3023 Moisture Proof Packaging
All ASDL-3023 options are shipped in moisture proof package. Once opened, moisture absorption begins.
This part is compliant to JEDEC Level 3.
UNITS IN A SEALED
MOISTURE-PROOF
PACKAGE
PACKAGE IS OPENED
(UNSEALED)
PARTS ARE NOT
RECOMMENDED TO
BE USED
ENVIRONMENT
LESS THAN 30 oC
AND LESS THAN
60% RH
NO
YES
PACKAGE IS
OPENED LESS
THAN 168
HOURS
YES
NO BAKING IS
NECESSARY
NO
NO
PACKAGE IS
OPENED LESS
THAN 15 DAYS
YES
PERFORM
RECOMMENDED
BAKING CONDITIONS
Figure 6. Baking Conditions Chart
Recommended Storage Conditions
Baking Conditions
Storage Temperature
10°C to 30°C
Package
Temp
Time
Relative Humidity
below 60% RH
In reels
60 °C
≥ 48hours
In bulk
100 °C
≥ 4hours
Time from unsealing to soldering
After removal from the bag, the parts should be soldered
within 7 days if stored at the recommended storage conditions. When MBB (Moisture Barrier Bag) is opened and
the parts are exposed to the recommended storage conditions more than 7 days but less than 15 days the parts
must be baked before reflow to prevent damage to the
parts.
Note: To use the parts that exposed for more than 15 days is not
recommended.
14
Baking should only be done once.
Recommended Reflow Profile
MAX 260°C
T - TEMPERATURE (°C)
255
R3
230
217
200
180
R2
R4
60 sec to 90 sec
Above 217°C
150
R5
R1
120
80
25
0
P1
HEAT
UP
50
100
P2
SOLDER PASTE DRY
Process Zone
150
Symbol
200
250
P3
SOLDER
REFLOW
P4
COOL DOWN
DT
Maximum DT/Dtime
or Duration
Heat Up
P1, R1
25°C to 150°C
3°C/s
Solder Paste Dry
P2, R2
150°C to 200°C
100s to 180s
Solder Reflow
P3, R3
P3, R4
200°C to 260°C
260°C to 200°C
3°C/s
-6°C/s
Cool Down
P4, R5
200°C to 25°C
-6°C/s
Time maintained above liquidus point , 217°C
> 217°C
60s to 90s
Peak Temperature
260°C
-
Time within 5°C of actual Peak Temperature
-
20s to 40s
Time 25°C to Peak Temperature
25°C to 260°C
8mins
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 DT/Dtime temperature change rates or duration. The DT/Dtime rates or
duration 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 ASDL-3023 pins
are heated to a temperature of 150°C to activate the flux
in the solder paste. The temperature ramp up rate, R1,
is limited to 3°C per second to allow for even heating of
both the PC board and ASDL-3023 pins.
Process zone P2 should be of sufficient time duration
(100 to 180 seconds) to dry the solder paste. The temperature is raised to a level just below the liquidus point of
the solder.
300
t-TIME
(SECONDS)
Process zone P3 is the solder reflow zone. In zone P3,
the temperature is quickly raised above the liquidus
point of solder to 260°C (500°F) for optimum results. The
dwell time above the liquidus point of solder should be
between 60 and 90 seconds. This is to assure proper coalescing of the solder paste into liquid solder and the
formation of good solder connections. Beyond the recommended dwell time 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 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 ASDL-3023 pins to change dimensions evenly,
putting minimal stresses on the ASDL-3023.
It is recommended to perform reflow soldering no more
than twice.
15
Appendix A: ASDL-3023 SMT Assembly Application Note
Solder Pad, Mask and Metal Stencil
Figure A1. Stencil and PCBA
Recommended land pattern for ASDL-3023- 008
Recommended land pattern for ASDL-3023-021
Mounting
Centre
Mounting
Centre
0.44
1.74
1.55
0.4
1.05
0.17
0.1
0.7
0.775
FIDUCIAL 1.75
1.60
0.55
0.55
1.05
1.35
1.05
1.35
3.75
3.75
7.5
7.5
UNIT: mm
Figure A2a. Recommended land pattern, ASDL-3023-021
UNIT: mm
Figure A2c. Recommended land pattern, ASDL-3023-008
Recommended land pattern for ASDL-3023- S21
1.3
Mounting
Centre
1.5
0.3
1.55
0.1
0.775
1.75
0.55
1.05
1.35
3.75
7.5
UNIT: mm
Figure A2b. Recommended land pattern, ASDL-3023-S21
16
Recommended Metal solder Stencil Aperture
Adjacent Land Keepout and Solder Mask Areas
It is recommended that only a 0.11 mm (0.004 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 1 below the
drawing for combinations of metal stencil aperture and
metal stencil thickness that should be used. Aperture
opening for shield pad is 2.6 mm x 1.5 mm(for ASDL3023-S1) as per land pattern. Compared to 0.127mm
stencil thickness 0.11mm stencil thickness has longer
length in land pattern. It is extended outwardly from
transceiver to capture more solder paste volume.
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. The minimum
solder resist strip width required to avoid solder bridging
adjacent pads is 0.2mm.It is recommended that two fiducially crosses be placed at mid length of the pads for unit
alignment.
Note: Wet/Liquid Photo-imaginable solder resist/mask is recommended
j
k
h
l
Solder Mask
Figure A3. Solder stencil aperture
Table 1.
Stencil thickness,
t(mm)
Aperture size(mm)
Length,l
0.127mm
1.75+/-0.05
0.11mm
17
2.4+/-0.05
Dimension
mm
Width,w
h
0.2
0.55+/-0.05
l
3.0
0.55+/-0.05
k
3.85
j
10.1
Appendix B: PCB Layout Suggestion
The effects of EMI and power supply noise can potentially
reduce the sensitivity of the receiver, resulting in reduced
link distance. The PCB layout played an important role to
obtain a good PSRR and EM immunity resulting in good
electrical performance. Things to note:
1. The ground plane should be continuous under the
part, but should not extend under the shield trace.
2. The shield trace is a wide, low inductance trace back
to the system ground. CX1, CX2, CX3, CX4 and CX5 are
optional supply filter capacitors; they may be left out if
a clean power supply is used.
3. VLED can be connected to either unfiltered or
unregulated power supply. The bypass capacitors
should be connection before the current limiting
resistor R2 respectively. In a noisy environment,
including capacitor CX3and CX4 can enhance supply
rejection. CX3 that is generally a ceramic capacitor of
low inductance providing a wide frequency response
while CX4 is 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. VCC pin can be connected to either unfiltered or
unregulated power supply. The Resistor, R1 together
with the capacitors, CX 1and CX2 acts as the low pass
filter.
5. IOVCC is connected to the ASIC voltage supply or
the VCC supply. The capacitor, CX5 acts as the bypass
capacitor.
6. 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 ground connected
board layers. The diagram below demonstrate an
example of a 4 layer board :
• Top Layer: Connect the metal shield and
module ground pin to bottom
ground layer;
Place the bypass capacitors within
0.5cm from the VCC and ground
pin of the module.
• Layer 2: Critical ground plane zone. 3
cm in all direction around the
module. Connect to a clean,
noiseless ground node (eg
bottom layer).
• Layer 3:
Keep data bus away from critical
ground plane zone.
• Bottom layer: Ground layer. Ground noise <75
mVp-p. Should be separated from
ground used by noisy sources.
The area underneath the module at the second layer, and
3cm in all direction 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 Avago Technologies IrDA Data Link Design Guide
for details. The layout below is based on a 2-layer PCB.
Noise sources to be placed as far away from the transceiver as possible
Top Layer
R
1
CX1
CX2
CX5
R
2
CX3
CX4
Top Layer
Layer 3
Layer 2
Legend: ground via
Bottom Layer (GND)
18
Bottom Layer
Appendix C: General Application Guide for the ASDL-3023 infrared IrDA Compliant 4 Mb/s Transceiver.
Description
Interface to the Recommended I/O chip
The ASDL-3023, a wide-voltage operating range infrared
transceiver is a low-cost and small form factor device
that 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
spectrally suited to universal remote control transmission
function at 940 nm typically. It is fully compliant to IrDA
1.4 low power specification
The ASDL-3023’s TXD data input is buffered to allow
for CMOS drive levels. No peaking circuit or capacitor is
required. Data rate from 9.6kb/s to 4Mb/s is available at
RXD pin. The TXD_RC, pin6 together with LEDA, pin1 is
used to selected the remote control transmit mode. Alternatively, the TXD_IR, pin2 together with LEDA, pin1 is
used for infrared transmit selection.
up 4Mb/s and support most remote control codes The
design of ASDL-3023 also includes the following unique
features :
• Spectrally suited to universal remote
transmission function at 940nm typically;
control
• Low passive component count;
• Shutdown mode for low power consumption
requirement;
• Direct interface with I/O logic circuit.
Following shows the hardware reference design with
ASDL-3023
*Detail configuration of ASDL-3023 with the controller
chip is shown in Figure 3.
The use of the infrared techniques for data communication has increase rapidly lately and almost all mobile application processors have built in the IR port. This does
away with the external Endec and simplifies the interfacing to a direct connection between the processor and the
transceiver. The next section discusses interfacing configuration with a general processor.
Selection of Resistor R2
Resistor R2 should be selected to provide the appropriate
peak pulse IR and RC LED current respectively at different
ranges of Vcc as shown on page 3 under “Recommended
Application circuit components”.
STN/TFT LCD Panel
LCD Control
Touch Panel
Key Pad
Peripherial
interface PWM
A/D
LCD Backlight Contrast
*ASDL-3023
Mobile Application
chipset
IrDA
interface
AC97
sound
Logic Bus Driver
Memory Expansion
FLASH
SDRAM
Figure 2. Mobile Application Platform
19
Memory I/F
Baseband I2S
controller
ROM
PCM Sound
Power Management
Antenna
Audio Input
General mobile application processor
Remote Control Operation
The transceiver is directly interface with the microprocessor provided its support infrared communication
commonly known as Infrared Communications Port
(ICP). The ICP supports both SIR data rates up to 115.2kps
and sometimes FIR data with data rates up to 4Mbps.
The remote control commands can be sent one of the
available General Purpose IO pins or the UART block
with IrDA functionality. It should be should be observed
that although both IrDA data transmission and Remote
control transmission is possible simultaneously by the
hardware, hence the software is required to resolve this
issue to prevent the mixing and corruption of data while
being transmitted over the free air. The above Figure 3
illustrates a reference interfacing to implement both IR
and RC functionality with ASDL-3023.
The ASDL-3023 is spectrally suited to universal remote
control transmission function at 940nm typically. Remote
control applications are not governed by any standards,
owing to which there are numerous remote codes
in market. Each of those standards results in receiver
modules with different sensitivities, depending on the
carries frequencies and responsively to the incident light
wavelength. Remote control carrier frequencies are in
the range of 30KHz to 60KHz (for details of some the frequently used carrier frequencies, please refer to AN1314).
Some common carrier frequencies and the corresponding SA-1110 UART frequency and baud rate divisor are
shown in Table 3.
Table 3.
Remote Control Carrier
Frequency (KHz)
SA-1110 UART
Frequency (KHz)
Baud Rate
Divisor
30
28.8
8
32,33
32.9
7
36,36.7,38,39.2,40
38.4
6
56
57.6
4
VCC
R1
CX1
IOVCC
GND
CX2
GND
VCC
IOVCC
IOVCC
CX5
GND
GPIO
TXD_RC
IR_RXD
RXD
SD
GPIO
IR_TXD
100Kohm
VLED
TXD_IR
R3
VLEDA
100Kohm
HSDL3021
GND
CX3
GND
CX4
GND
Figure 3. ASDL-3023 configuration with general mobile architecture processor
20
Appendix E: Window Design for ASDL-3023
Optical Port Dimensions for ASDL-3023
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°.
IR TRANSPARENT
WINDOW
OPAQUE MATERIAL
Y
IR TRANSPARENT
WINDOW
X
OPAQUE MATERIAL
K
Z
A
D
T
Z
21
IR TRANSPARENT
WINDOW
In the figure above, X is the width of the window, Y is the height of the window and Z is the distance from the ASDL3023 to the back of the window. The distance from the center of the LED lens to the center of the photodiode lens, K, is
5.5mm. The equations for computing the window dimensions are as follows:
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 comparable,
W1 = 0.33*T,
W2 = 0.66*T,
where T is the window thickness and the refractive index of the window material is 1.586.
The depth of the LED image inside the ASDL-3023, D, is 3.17mm. ‘A’ is the required half angle for viewing. For IrDA
compliance, the minimum is 15° and the maximum is 30°. The equations result in the following tables and graphs. The
graphs are plotted assuming that the thickness of the window is negligible.
Aperture Width (X, mm)
Module Depth
(Z) mm
Aperture height (Y, mm)
Max
Min
Max
0
7.20 + W1
9.16 + W2
1.70 + W1
3.66 + W2
1
7.73 + W1
10.32 + W2
2.23 + W1
4.82 + W2
2
8.27 + W1
11.47 + W2
2.77 + W1
5.97 + W2
3
8.81 + W1
12.62 + W2
3.31 + W1
7.12 + W2
4
9.34 + W1
13.78 + W2
3.84 + W1
8.28 + W2
5
9.88 + W1
14.93 + W2
4.38 + W1
9.43 + W2
6
10.41 + W1
16.09 + W2
4.91 + W1
10.59 + W2
7
10.95 + W1
17.24 + W2
5.45 + W1
11.74 + W2
8
11.49 + W1
18.40 + W2
5.99 + W1
12.90 + W2
9
12.02 + W1
19.55 + W2
6.52 + W1
14.05 + W2
22.00
20.00
18.00
16.00
14.00
12.00
10.00
8.00
6.00
4.00
2.00
0.00
Aperture Width (X) vs Module Depth (Z)
Aperture Height (Y) vs Module Depth (Z)
16.00
Aperture Height (Y) mm
Aperture Width (X) mm
Min
Xmin
Xmax
0
1
2
3
4
5
6
Module Depth (Z) mm
7
8
9
14.00
Ymin
12.00
Ymax
10.00
8.00
6.00
4.00
2.00
0.00
0
1
2
3
4
5
6
7
Module Depth (Z) mm
8
9
It is recommended that the tolerance for assembly be considered as well. The recommended minimum window size
which will take into account of the assembly tolerance is defined as:
Xmin + assembly tolerance = Xmin + 2*(assembly tolerance) (Dimensions are in mm)
Ymin + assembly tolerance = Ymin + 2*(assembly tolerance) (Dimensions are in mm)
22
Window Material
Shape of the Window
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.
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 backside 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 #
Light Transmission
Haze
Refractive Index
Lexan 141
88%
1%
1.586
Lexan 920A
85%
1%
1.586
Lexan 940A
85%
1%
1.586
Note: 920A and 940A are more flame retardant than 141.
Recommended Dye: Violet #21051 (IR transmissant above 625mm)
Flat Window, (First Choice)
23
Curved Front and Back, (Second Choice)
Curved Front, Flat Back, (Do not use)
Appendix F: General Application Guide for the ASDL-3023
Two-TxD Direct Transmission Mode
Remote Control Drive Modes
In the two-TxD direct transmission mode, the LED can
be driven separately for IrDA and RC mode of operation
through the TxD_IR and TxD_RC pins respectively. This
mode can be used when the external controller utilizes
separate transmit pins for IrDA and RC operation modes,
thereby eliminating the need for external multiplexing.
The ASDL-3023 can operate in the single-TxD programmable mode or the two-TxD direct transmission mode.
Single-TxD Programmable Mode
In the single-TxD programmable mode, only one input
pin (TxD_IR input pin) is used to drive the LED in both
IrDA mode as well as Remote Control mode of operation.
This mode can be used when the external controller uses
only one transmit pin for both IrDA as well RC mode of
operation.
Please refer to the Transceiver I/O truth table for more
detail.
Transceiver Control I/O Truth Table for Two-TxD Direct
Transmission Mode
transceiver is in default mode (IrDA-SIR) when powered
up. The user needs to apply the following programming
sequence to both the TxD_IR and SD inputs to enable the
transceiver to operate in either the IrDA or remote control
mode.
SD
TxIR
TxRC
LED
Remarks
0
0
0
OFF
IR Rx enabled. Idle mode
0
0
1
ON
Remote control operation
0
1
0
ON
IrDA Tx operation
0
1
1
-
Not recommended
(Both Transmitters off )
1
0
0
OFF
Shutdown mode*
* The shutdown condition will set the transceiver to the default mode
(IrDA-SIR)
tC
tB
tA
tTL
tC
SHUTDOWN
(ACTIVE HIGH)
tH
tH
tH
TxIR
(ACTIVE HIGH)
SHUTDOWN
TxRC
(GND)
DRIVE
IrDA LED
DRIVE
RC LED
RC
MODE
DRIVE
IrDA LED
RESET
Mode Programming Timing Table
The following timings describe input constraints required using the active serial interface for mode programming with
pins SD, TxIR, and TxRC:
Parameter
Symbol
Min
Typ
Max
Unit
Notes
Shutdown input pulse width, at pin SD
tSDPW
30
-
∞
µs
Will activate
complete shutdown
SD mode setup time
tA
200
-
-
Ns
Setup for mode
programming
TxIR pulse width for RC mode
tB
200
-
-
Ns
RC drive enabled
with pin TxIR
SD programming pulse width
Note: ( tA + tB ) < tC < tSDPW
tC
-
-
5.0
µs
Pulse width mode
programming
TxIR setup time for
SIR or MIR/FIR mode
tS
50
-
-
Ns
Setup time for IrDA
bandwidth selection
TxIR or SD hold time to latch
SIR, MIR/FIR or RC mode
tH
50
-
-
Ns
Hold time for IrDA or RC
modes
24
Bandwidth Selection Timing
The power on state should be the IrDA SIR mode.
The data transfer rate must be set by a programming
sequence using the TxD_IR and SD inputs as described
below.
Note: SD should not exceed the maximum, tC ≤ 5µs, to
prevent shutdown.
Setting to the High Bandwidth MIR/FIR Mode
(0.576Mbits/s to 4Mbits/s)
Setting to the LOW Bandwidth SIR Mode
(2.4kbits/s to 115.2kbits/s)
1. Set SD input to logic “HIGH”. Wait tA ≥ 200ns
1. Set SD input to logic “HIGH”.
2. Set TxD_IR input to logic “HIGH”. Wait tS ≥ 50ns.
2. Set TxIR input to logic “LOW”. Wait tS ≥ 50ns.
3. Set SD to logic “LOW” (this negative edge latches state
of TxD_IR, which determines speed setting).
3. Set SD to logic “LOW” (this negative edge latches state
of TxIR, which determines speed setting).
4. After waiting tH ≥ 50ns TxD_IR can be set to logic
“LOW”. TxD_IR is now re-enabled as normal IrDA
transmit input for the High Bandwidth MIR/FIR mode.
4. TxIR must be held for tS ≥ 50ns. TxIR is now re-enabled
as normal IrDA transmit input for the Low Bandwidth
SIR mode.
50%
SD
tA
tS
50%
TxI R
25
50%
tC
tH
High: MIR/FIR
50%
Low: SIR
Power-Up Sequencing
To have a proper operation for ASDL-3023, the following power-up sequencing must be followed.
(a) It’s strongly recommended that Vcc must come prior to IOVcc.
V CC
t IOVccDL >− 0us
IOV CC
t SDDL >− 30us
t SDPW >− 30us
SD
(b) It is not recommended to turn on IOVcc before Vcc while SD is low.
However, for application that IOVcc come prior to Vcc while SD is low, SD pin has to set high to assure proper functionality.
V CC
IOV CC
t SDDL >− 30us
SD
t SDPW >− 30us
(c) Setting IOVcc high before Vcc while SD is high is forbidden.
V CC
IOV CC
SD
Note:
t IOVccDL : IOVcc delay time
t SDDL : SD delay time
t SDPW : Shutdown Input Pulse Width
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