ETC IRMT6400

IRMS6400
TOP VIEW IRMT6400
SIDE VIEW
4 Mb/s Infrared Data Transceiver
Dimensions in inches (mm)
C
.116 L .106
(2.95)
(2.70)
E
D
.157
(4.00)
.190
(4.83)
PIN 1
PIN 1
.138 (3.50)
.374 (9.86)
E=Emitter
D=Detector
IRMS6400
IRMS6400
IRMT6400
IRMT6400
Absolute Maximum Ratings, TA=25°C (except where noted)
FEATURES
•
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•
•
•
•
•
•
•
•
•
Compliant with IrDA Specification
Data Rates 9.6 Kb/s to 4.0 Mb/s
Wide Range of Supply Voltage 2.6 to 5.5 V
Standby Current 3.3 mA at 5.0 V Typical
Shut Down Current 0.01 µA Typical
Excellent Power Supply Noise Rejection
Tri-State Receiver Output and TxD Disable
AC Coupled Transmit Input
– Provides Integrated Protection for
Eye Safety
High DC Ambient Rejection
Independent LED Supply, Anode Pin Can Take
– up to 9.0 V DC when not Transmitting and
– up to 4.0 V above VCC when Transmitting
Receiver Latency Less than 100 µs
Slimline Package:
H 4.0 mm x D 4.8 mm x L 9.8 mm
ot
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f
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DESCRIPTION
With state of the art submicron BiCMOS circuitry,
coupled with Infineon optoelectronic expertise, the
IRMS6400/IRMT6400 outperforms its closest rival.
Infineon has incorporated a mode selection pin that
toggles the device to operate in FIR (4 Mb/s) or
SIR/MIR (9.6 Kb/s to 1.152 Mb/s) mode. Its external Shut Down (SD) feature cuts current consumption to typically 0.01 µA. The transmit input is AC
coupled, limiting transmit pulse duration to 70 µs,
preventing transmitter damage and continuous
LED output. Mode select determines the data rate.
Low for 9.6 Kb/s to 1.152 Mb/s, high for 4 Mb/s.
Supply Voltage Range, all states, VCC ................................... –0.5 to +7.0 V
LED Anode Voltage, not transmitting, VLEDA........................................9.0 V
LED Anode Voltage, transmitting, VLEDA .................................. 4.0 V + VCC
Input Currents, (pin 3 and 5) .............................................................. 20 mA
Output Sinking Current...................................................................... 50 mA
Storage Temperature, TS .......................................................–40 to +100°C
Ambient Temperature, operating, TA .......................................–25 to +85°C
Lead Solder Temperature, 230°C ........................................................<10 s
IC Junction Temperature, TJ ............................................................... 125°C
Average IR LED Current, DC, ILED ................................................... 100 mA
Repetitive Pulsed IR LED Current,
<90 µs, ton <25%, ILED(RP) ............................................................ 700 mA
Transmit Data Input Voltage, VTxD ..................................–0.5 to VCC + 0.5 V
Receive Data Output Voltage, VRxD ....................................... –0.5 to VCC + 0.5 V
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e
D
Table 1. Pin Functions
Pin no.
Function
Pin no.
Function
1
LED Anode
5
SD/Mode
2
LED Cathode
6
VCC
3
TxD
7
*Do not connect
4
RxD
8
GND
*Pin 7 internally grounded
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
1
March 21, 2000-19
Figure 1. Block Diagram
Bandwidth Control
Preamp
VCC
VCC
Tri-State
CMOS Buffer
Receive Detector
Lowpass
Filter
Main
AMP
VCC
Pin 6
RxD
+
Detector
Reference
Pin 4
Tri-state
Control
–
+
Receiver
Output
–
Ambient DC
Cancelling
Receive Ouput
Blanking
AGC & Signal
Reference
Processor
AGC
SD/Mode
Pin 5
LED Anode
Pin 1
Transmit
IR LED
Switched
Current Source
TxD Input
Buffer
Power
Down
Control
FIR/SIR-MIR
Flip/Flop
TxD Feedback
Blanking
Photodiode
Regulated
Voltage &
Current
Sources
VCC
TxD
Pin 3
LED Cathode
Pin 2
TxD In
Error
AMP
GND
Pin 8
Pull-down
Electrical Characteristics
Table 2. Basic Parameters, TA=25°C (except where noted)
Parameter
Min.
Typ.
Max.
Unit
Conditions
Data Rate
9.6 K
—
4M
bits/s
Standard pulse width
VCC Voltage
2.6
—
5.5
V
–25 to +85°C, VCC to VSS
Maximum LED Anode Voltage
—
—
4 V+VCC V
VCC=2.6 V to 5.5 V
ICC Standby Current (Avg.)
—
3.3
4.5
mA
SD=0, VCC=2.6 V to 5.5 V, no receive signal
ICC Receiving Current (Avg.)
—
3.8
5.0
mA
10 µW, 4.0 Mb/s, 15 pF load
ICC Shut Down Current (Note 1) (Avg.)
—
0.01
1.0
µA
SD=VCC, VCC=2.6 V to 5.5 V
ICC Transmitting Current (Avg.)
—
6
10
mA
TxD=VCC, VCC=5.0 V, VLED=5.0 V, Ro=5.1 Ω
Minimum VCC
—
2.5
—
V
Reduced performance
Parameter
Min.
Typ.
Max.
Unit
Conditions
TxD, SD Input Capacitance
—
5.0
—
pF
VCC=2.6 V to 5.5 V
TxD pull-down
350
500
700
kΩ
TxD=VCC, VCC=5.0 V
Minimum dV/dt of TxD Input Signal
0.7
1.4
—
V/µs
5.0 V pulse
TxD Minimum Hold Time for Mode
Change
90
200
—
ns
VCC=2.6 V to 5.5 V,
referenced to SD negative clocking edge
TxD Minimum Setup Time for Mode
Change (Note 2)
–70
–40
—
ns
VCC=2.6 V to 5.5 V,
referenced to SD negative clocking edge
TxD Input Threshold
1.0
1.4
1.8
VCC
VCC=2.6 V to 5.5 V, 125 ns input pulse
SD Transmit Enable
—
Table 3. I/O Parameters
500
—
ns
VCC=2.6 V to 5.5 V, (Note 3)
SD to TxD input disable & RxD tri-state —
50
70
ns
VCC=2.6 V to 5.5 V
SD Input Threshold
1.0
1.4
1.8
V
VCC=5.0 V
SD Input Threshold
0.6
0.9
1.2
V
VCC=2.6 V
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
IRMS6400/IRMT6400
2
March 21, 2000-19
Table 3. I/O Parameters (continued)
Parameter
Min.
Typ.
Max.
Unit
Conditions
RxD Output High
3.5
4.0
—
V
VCC=5.0 V, IOH=24 mA
RxD Output High
2.0
2.3
—
V
VCC=2.7 V, IOH=6.0 mA
RxD Output Low
—
1.0
1.5
V
VCC=5.0 V, IOL=24 mA
RxD Output Low
—
0.1
0.8
V
VCC=5.0 V, IOL<1 mA
RxD Output Low
—
0.4
0.8
V
VCC=2.7 V, IOL=6.0 mA
RxD Short Circuit
—
48
—
mA
VCC=5.0 V, RxD=0, RxD=VCC
RxD Short Circuit
—
48
—
mA
VCC=2.7 V, RxD=0, RxD=VCC
RxD to VCC Tri-State Impedance
RxD Rise/Fall Time
350
500
650
kΩ
SD=VCC, VCC=5.0 V, measured between RxD to VCC
—
7.0
—
ns
VCC=5.0 V, load=15 pF
RxD Rise/Fall Time
—
15
—
ns
VCC=5.0 V, load=100 pF
RxD Rise/Fall Time
—
10
—
ns
VCC=2.7 V, load=15 pF
RxD Rise/Fall Time
—
27
—
ns
VCC=2.7 V, load=100 pF
Table 4. Receiver Parameters, High Rate Mode (FIR), TA=25°C (except where noted)
Parameter
Symbol Min.
Typ.
Max.
Unit
Data Rate
—
4M
—
bit/s
—
Conditions
125 ns (low rate pulse), 0 to 70°C
2
Bit error rate=10–8
Logic High Input Irradiance
EIHmin
10
—
—
µW/cm
Logic High Input Irradiance
EIHmax
—
—
500
mW/cm2 In-band irradiance maximum
Minimum Detection Threshold
EEmin
—
4.0
—
µW/cm2
2
4.0 Mb/s
0.4
µW/cm
Ambient interference pulsed
500
800
µs
0 to 10 mW/cm2 ambient input
—
50
100
µs
0 to 10 mW/cm2 ambient input
—
—
30
50
µs
0 to 10 mW/cm2 ambient input
Pulse Width Correction Range
—
90
—
175
ns
40 µW/cm2 input to produce 115 ns to
135 ns output, VCC=2.7 V to 5.5 V
Pulse Width Settling
—
—
8.0
16
µs
40 µW/cm2 input
Output Pulse Edge Jitter & Bias at RxD —
—
10
—
ns
125 ns, 40 µW/cm2 input, load=15 pf,
measured at 1.4 V
Output Pulse Width at RxD
—
110
125
140
ns
125 ns, 40 µW/cm2 input, load=15 pf,
measured at 1.4 V
Power Supply Rejection <5 MHz
—
—
50
—
mVP
<0.1 pulse per second spurious output
Power Supply Rejection >5 MHz
—
—
25
—
mVP
<0.1 pulse per second spurious output
Logic Low Input Irradiance
EIL
—
Receive Latency (Near-far)
—
—
Powerup Latency
—
Transmit Latency (turn around)
Table 5: Receiver Parameters, Low Rate Mode (SIR/MIR), TA=25°C (except where noted)
Parameter
Symbol Min.
Typ.
Max.
Unit
Conditions
Data Rate
—
9.6 K
—
1.15 M
bits/s
9.6 Kb/s to 115 Kb/s=1.63 µs,
576 Kb/s=434 ns, 1.152 Mb/s=217 ns
Logic High Input Irradiance (MIR)
EIHmin
10
—
—
µW/cm2
Bit error rate=10–8
Logic High Input Irradiance (SIR)
EIHmin
4.0
—
—
µW/cm2
Bit error rate=10–8
Logic High Input Irradiance
EIHmax
—
—
500
mW/cm2 In band irradiance maximum
Logic Low Input Irradiance
EIL
—
—
0.4
µW/cm2
Ambient interference pulsed
Receive Latency (Near-far)
—
—
2.5
4.0
ms
0 to 10 mW/cm2 ambient input
Transmit Latency (turn around)
—
—
50
100
µs
0 to 10 mW/cm2 ambient input
Power-up Latency
—
—
50
150
µs
0 to 10 mW/cm2 ambient input
Power Supply Rejection <5 MHz
—
—
50
—
mVP
<0.1 pulse per second spurious output
Power Supply Rejection >5 MHz
—
—
25
—
mVP
<0.1 pulse per second spurious output
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
IRMS6400/IRMT6400
3
March 21, 2000-19
Table 5: Receiver Parameters, Low Rate Mode (SIR/MIR), TA=25°C (except where noted) (Continued)
Output Pulse Width (1.15 MB)
—
120
215
400
ns
217 ns pulse in
Output Pulse Width at RxD (115 Kb/s)
—
1.4
1.63
2.5
µs
1.63 ns pulse in
Output Pulse Width at RxD (9.6 Kb/s)
—
1.4
6
22
µs
19.5 µs pulse in
Min.
Typ.
Max.
Unit
Conditions
Table 6. Transmitter Output
Parameter
Transmit Delay
—
15
—
ns
125 ns pulse, VCC=5.0 V
Pulse Width Limit
50
70
100
µs
TxD pulse>100 µs, 5.0 V pulse, VCC=5.0 V
TxD Peak Wavelength
850
870
900
nm
IF=20 mA DC
LED Anode Current Limit
510
610
680
mA
TxD=VCC, LED anode=5.0 V, VCC=5.0 V,
averaged over 125 ns pulse
LED Anode Current Limit
310
450
550
mA
TxD=VCC, LED anode=3.0 V, VCC=3.0 V,
averaged over 125 ns pulse
LED Cathode Saturation Drop
—
0.3
0.4
V
400 mA, VCC=2.7 V
VCC Transient Immunity
VCC ±1
VCC ±2
—
V peak
10 ns pulse height, VCC=5.0 V (Note 4)
Transmit output rise and fall time (tr, tf) 10
—
40
ns
VLED=2.7 V, no resistor
Radiant Intensity (peak, 4 Mb/s mode)
170
400
mW/sr
VLED=2.7 V, no resistor
100
Note 1:
For Shut Down (SD) current to fall below 1 µA requires driving the
Shut Down (SD) pin to within 0.5 V of VCC to ensure cutoff of the
input PMOS transistor of the input CMOS totem pole.
Note 2:
Negative setup times indicate that the internal data propagation
time is longer than the latching signal propagation time. This is common on logic devices. It means that the TxD data can go away
before the negative Shut Down (SD) edge occurs and not lose the
data. (See application notes for more details).
Note 3:
Shut Down (SD) to transmit enable is the time required for the
transmit bias circuits to stabilize. Applying a transmit pulse before
this time has elapsed will reduce the transmit pulse width.
Note 4:
Transmit VCC Transient Immunity measures the transmitter circuitry
immunity from large VCC and ground return inductive transients
arising from the action of large transmitter di/dt currents on VCC and
ground return trace inductances. This test applies a negative 10 ns
VCC pulse to simulate the effects of transmitter current induce VCC
transients (assuming the LED anode supply and VCC have a shared
inductance) and measures for less than a 10% change in pulse
width or delivered charge on the initial pulse and subsequent pulse.
Mode Switching (see Figure 2.)
Figure 2. Switching Mode
Normally the IRMS6400/IRMT6400 Series initializes in the SIR/
MIR (9.6 Kb/s to 1.152 Mb/s) mode upon power-up. Switching
the module to FIR (4 Mb/s) Mode can be achieved as follows:
tS
SD/Mode
• Bring Shut Down (SD)/Mode pin to a logic “High” status.
• Bring TxD input to a logic “High” status. Wait for ts ≥–40 ns.
• Bring Shut Down (SD)/Mode pin to a logic “Low” status. The
negative transition of this pulse will set the module mode to
(4 Mb/s) data rate by reading the state of TxD.
Bring TxD to a logic “Low” after waiting for th ≥90 ns.
th
TxD
pulse will set the device into 4 Mb/s data rate mode
TxD
Pulse will set the device into SIR/MIR mode
Switching to SIR/MIR (9.6 Kb/s to 1.15 Mb/s) Mode:
• Bring Shut Down (SD)/Mode pin to a logic “High” status.
• Bring TxD input to a logic “Low” status. Wait for ts ≥–40 ns.
• Bring Shut Down (SD)/Mode pin to a logic “Low” status. The
negative transition of this pulse will set the module mode to
115 Kb/s data rate by reading the state of TxD.
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
IRMS6400/IRMT6400
4
March 21, 2000-19
Figure 3. Shutdown Current vs. Ambient Temperature
Figure 6. RxD Pulse Width vs. Ambient Temperature
1.1
0.7
Pulse Width (r.u.)
Shutdown Current (µΑ)
1.05
0.6
0.5
0.4
0.3
0.2
V =V
SD
4Mbps mode.
O
Typical value at 25 C is 126ns.
0.95
0.9
=2.7V.
LED
O
0.85
Typical value at 25 C is 30nA.
0.1
1
0
0.8
-40
-20
0
20
40
60
80
100
-40
-20
0
O
40
60
80
100
O
Ambient Temperature ( C)
Ambient Temperature ( C)
Figure 7. RxD Pulse Rise and Fall Time vs. Temperature
Figure 4. Standby Current vs. Temperature
16
4
3.5
2.7V
3.0V
3.3V
4.0V
5.0V
12
Fall Time
10-90% Time (ns)
3
Rise Time
14
V CC
Standby Current (mA)
20
2.5
10
8
4Mbps data rate. VCC=2.7V
6
4
2
2
0
1.5
-40
-20
0
20
40
60
80
-40
100
-20
0
O
60
80
800
1.05
700
1
115Kbps mode.
Typical value at 25OC is 1.63us.
0.9
0.85
600
500
R
LED
400
0Ω
1.06Ω
1.80Ω
2.77Ω
3.99Ω
5.17Ω
300
0.8
-40
-20
0
20
40
60
100
Figure 8. LED Peak Current vs. VLED
1.1
Peak LED Current (mA)
Pulse Width (r.u.)
40
Ambient Temperature ( C)
Figure 5. RxD Pulse Width vs. Ambient Temperature
0.95
20
O
Ambient Temperature ( C)
80
200
100
2.5
Ambient Temperature ( OC)
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
3
3.5
4
V
LED
4.5
5
5.5
(V)
IRMS6400/IRMT6400
5
March 21, 2000-19
Figure 9. LED Current vs. Ambient Temperature
Figure 12. IR Intensity vs. Ambient Temperature
1.2
1.2
1
1
4Mbps mode, V
=2.7V.
LED
IR Intensity (r.u.)
LED Current (r.u.)
O
Typical peak current at 25 C is450mA.
0.8
0.6
0.4
0.2
0.8
4Mbps mode, VLED=2.7V.
O
Typical peak intensity at 25 C is 200mW/sr.
0.6
0.4
0.2
0
0
-40
-20
0
20
40
60
80
100
-40
-20
0
20
40
60
80
100
O
O
Ambient Temperature ( C)
Ambient Temperature ( C)
Figure 13. LED Intensity vs. VLED
Figure 10. Peak Intensity vs. LED peak Current
400
240
220
300
Intensity (mW/sr)
On-Axis LED Peak Intensity (mW/sr)
260
200
200
RLED
180
0Ω
1.06Ω
1.80Ω
2.77Ω
3.99Ω
5.17Ω
160
140
100
120
300
400
500
I
LED
600
700
2.5
3
3.5
(mA)
4
V
Figure 11. LED Intensity vs RLED
LED
4.5
5
5.5
(V)
Figure 14. Farfield Receiver Sensitivity Pattern (FIR)
18
260
16
240
Horizontal
Vertical
14
Intensity (mW/sr)
2
Sensitivity (uW/cm )
220
200
V
180
LED
2.7V
3.0V
3.3V
3.5V
4.0V
4.5V
5.0V
5.5V
160
140
12
10
8
6
4
2
120
0
1
2
R
LED
3
(Ohm)
4
-45
5
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
-30
-15
0
15
30
45
Angle (Degrees)
IRMS6400/IRMT6400
6
March 21, 2000-19
Figure 15. Reciever Sensitivity vs. Temperature (115 Kb/s)
Figure 18. RxD Pulse Rise and Fall Time vs. Temperature
1.4
1.3
TR
1.2
1.2
V CC=3.3V
TF
1.1
V CC=5.5V
T R and TF (r.u.)
Receiver Sensivity (r.u.)
VCC=2.7V
1
1
4Mbps data rate. VCC=2.7V.
Typical value at 25O C is 20ns.
0.9
0.8
2
115Kbps data rate. Typical value at 25OC & VCC=2.7V is 2.0 uW/cm
0.8
0.6
0.7
-40
-20
0
20
40
60
80
100
-40
-20
0
20
40
60
80
100
O
O
Ambient Temperature ( C)
Ambient Temperature ( C)
Figure 16. Receiver Sensitivity vs. Temperature
2.5
Receiver Sensivity (r.u.)
2
V
1.5
V
CC
CC
=2.7V
=3.3V
V CC=5.5V
1
4Mbps data rate. Typical value at 25O C & VCC=2.7V is 5.0 uW/cm 2
0.5
0
-40
-20
0
20
40
60
80
100
O
Ambient Temperature ( C)
Figure 17. Infrared Reflow Soldering Profile
300
Maximum 240(+5/–0) °C
Temperature (°C)
250
210°C
200
150
30 s minimum 30 s maximum
100
50
60 s minimum
0
0
50
Note: Peak temperature is 240 (+5 –0)°C
for less than 10 seconds.
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
100
150
Time (sec)
IRMS6400/IRMT6400
7
March 21, 2000-19
Interface Diagrams
Figure 19. Super I/O (PC87338VLJ) to IRMS6400/
IRMT6400
VCC
Figure 21. Super I/O (PC87338VLJ) to IRMS6400/IRMT6400 with
independent VLED power supply
VLED
VCC
0.1 µF
22 µF
R0
R0
1
6
LED VCC
Anode
50
VCC
IR TxD
3
65
50
VCC
IR TxD 65
TxD
IRMX6400
C4=22 µF
C3=0.1 µF
1
6
VCC LED
Anode
C1=0.1 µF C2=10 µF
3 TxD
IRMX6400
PC87338VLJ
PC87338VLJ
IR RxD
GND
IR SLO
VSS
42
4
67
IR RxD
RxD
SD GND
5
8
68
GND
Figure 20. Ultra I/O controller with fast IR
(FDC37C93xFR) to IRMS6400/IRMT6400
VCC
0.1 µF
22 µF
R0
1
6
LED VCC
Anode
125
VCC
VSS
42
IR TxD
99
3
TxD
IR RxD
GND
GND IR MODE
130
98
19
4
IR SLO 68
4
RxD
SD
5
GND
8
Table 7. Recommended RO values for different VLED
Parameter
Values
Unit
VLED power supply 2.4
2.7
3.0
3.5
4.0
4.5
5.0
V
Resistor
0
0
1.2
2.7
3.9
5.1
Ω
0
Table 8. Slimline IRMS64XX Truth Table
Inputs
Outputs
SD
VCC
TxD
Detector
RxD
LED
High
2.4 to 5.5 V
X=don’t
care state
X=don’t
care state
500 kΩ
pull-up
Off
Low
2.4 to 5.5 V
High
Undefined
On
High
Off
Low
Off
IRMX6400
FDC37C93XFR
67
RxD
2.4 to 5.5 V
SD GND
5
8
2.4 to 5.5 V
<0.4 µW/cm
(115 Kb/s)
<1.0 µW/cm2
(1 & 4 Mb/s)
2.4 to 5.5 V
2.4 to 5.5 V
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
Low
2
Low
<4.0 µW/cm2
(115 Kb/s)
<10.0 µW/cm2
(1 & 4 Mb/s)
IRMS6400/IRMT6400
8
March 21, 2000-19
Ordering Information
Figure 23. Reel Dimensions in Inches (mm)
Part
Number
Description PCB Mounting
Orientation
IRMS6400
Integrated
Packaged in
Transceiver Component Carrier
—Side View Reel (1000/reel) for
Side View Mounting
on PCB
Integrated
Transceiver
—Top View
Packaged in
Component Carrier
Reel (1000/reel) for
Top View Mounting
on PCB
0.512+0.020
0.79
– 0 .0 0 8
(20.2) Min.
13.0 +0.5
– 0.2
X
IRMT6400
Matte finish
these areas
12.97
(330.0)
Ref.
4.01
(102.0)
Ref.
0.079±0.020
(2.0 ± 0.5)
Detail A
Tape Leader and Trailer is 400 mm minimum.
W1 (Measured at hub)
W2 (Measured at hub)
See detail A
16.4 mm(+2 mm/-0 mm)
22.4 mm (Max)
Figure 22. Tape Dimensions in Inches (mm)
.315±.004
(8.00±.10)
.059+.004
(1.50+.10)
.079±.004
(2.00±.10)
.157±.004
(4.00±0.10)
.069±.004
(1.75±.010)
4° Max.
.295±.004
(7.50±0.10)
.401±.004
Bo
(10.19±.10)
.630 +.012
–. 0 0 4
16.0 +.30
–.10
Pin 1
IRMT6400 (top view)
1.50+.25
(.059+.010)
.199±.004
(5.06 .10) Ko
.0140±.0005
(.356±.013)
Feed direction
8° Max.
.167±.004
(4.23±.10)
.315±.004
(8.00±.10)
.059+.004
(1.50+.10)
Ao
.079±.004
(2.00±.10)
.157±.004
(4.00±0.10)
.069±.004
(1.75±.010)
.295±.004
(7.50±0.10)
.630 +.012
–. 0 0 4
16.0 +.30
–.10
4° Max.
.216
(5.48)
.400±.004
Bo
(10.16±.10)
Pin 1
IRMS6400 (side view)
1.50+.25
(.059+.010)
.156
(3.97)
Feed direction
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
.0130±.0005
(.330±.013)
.167±.004
(4.23 .10) Ko
8° Max.
.185±.004 Ao
(4.70±.10)
IRMS6400/IRMT6400
9
March 21, 2000-19
Figure 24. IRMS6400/IRMT6400 detail drawings with optional side view or top view mounting
Dimensions in inches (mm)—All dimensions have tolerances of ±0.004” (±0.1 mm)
.197
(5.00)
.333 (7.71)
1 2 3 4 5 6 7 8
1" Draft
pick and place
.165
(4.20)
.079
(2.00)
.053
(1.35)
.167 .051
(4.23) (1.30)
.004
(.10)
.028
(.70)
Typ.
.190
(4.83)
.039
(1.00)
Typ.
Recommended
PCB footprint
TOP VIEW
.065
(1.65)
.134
(3.40)
.67
(1.70)
Front pick and place
CL
E
D
.079
(2.00)
.012
(.28)
5° 4X
5° 4X
.069
(1.74)
.157
(4.00)
.051
(1.30)
Pin 1
.030
(0.75)
.008
(.20)
90° to 93°
Coplaner .0059
(0.15)
.053
(1.35)
.016
(0.40)
Typ.
.116
(2.95)
.106
(2.70)
CL
.014
(.36)
.388 (9.86)
Max.
Pin 1
1° Draft
(2 Plcs)
.027
(0.69)
.020
.039 (0.51)
(1.00)
6400RYYWW
5° 4X
.138
(3.50)
.378 (9.60)
For high EMI environment application the IRMS6400 and IRMT6400
modules are available with a metal can shield. The metal shielded
modules are designated as IRMS6409 and IRMT6409 respectively.
© Infineon Technologies, Corp., Optoelectronic Division
(formerly Siemens Microelectronics, Inc.)
Printed in the United States of America.
All rights reserved.
The information provided is believed to be accurate and reliable.
Infineon reserves the right to make changes to the product described
without notice. No liability is assumed as a result of its use nor for any
infringement of the rights of others.
This document may contain preliminary information and is subject to
change by Infineon without notice. Some of the parametric data
expressed in this preliminary data sheet is considered to be functional
by design. Infineon assumes no responsibility or liability for any use of
the information contained herein. Nothing in this document shall operate as an express or implied license or indemnity under the intellectual
property rights of Infineon or third parties.
The products described in this document are not intended for use in
implantation or other direct life support applications where malfunction
may result in the direct physical harm or injury to persons.
NO WARRANTIES OF ANY KIND, INCLUDING, BUT NOT LIMITED TO,
THE IMPLIED WARRANTIES OF MERCHANTABILITY OF FITNESS FOR
A PARTICULAR PURPOSE, ARE OFFERED IN THIS DOCUMENT.
 2001 Infineon Technologies Corp. • Optoelectronics Division • San Jose, CA
www.infineon.com/opto • 1-888-Infineon (1-888-463-4636)
IRMS6400/IRMT6400
10
March 21, 2000-19