ELMOS E909.07 Transimpedance amplifier with high sensitivity Datasheet

E909.07
TRANSIMPEDANCE AMPLIFIER WITH HIGH SENSITIVITY
PRODUCTION DATA - MAR 25, 2014
Features
General Description
ÿ Increases proximity detection range of E909.05/E909.06 by a factor of 5 (*)
ÿ Improves signal to noise ratio by a factor of 3
ÿ Optical receiver with high sensitivity
(limiting output): total transimpedance typ. 422MΩ
ÿ Integrated op-amp for buffering,
gain or additional active filtering
ÿ Very low phase shift in input overdrive
ÿ High ambient light suppression up to photo
currents of 10mA
ÿ Signal bandwidth up to 500kHz
ÿ No current consumption in standby mode
ÿ Automotive qualified according to AEC-Q100
The optical receiver device consists of a first stage transimpedance amplifier (TIA) with differential input, limiting amplifiers with integrated high pass filter characteristics and differential outputs OUTP_LA / OUTN_LA
and a secondary linear output OUT.
A very high sensitivity equivalent to a transimpedance
resistance of typ. 422MΩ is achieved at the limiting
outputs. By using a limiting amplifier no phase shift occurs if the input is overdriven. Ambient light equivalent
to a constant photo current up to 10mA is suppressed
with an integrated gyrator.
Together with the HALIOS® chip set E909.05/E909.06
motion detectors a detection range of several meters
can be realized. By switching the output to high impedance state several optical receivers can be multiplexed to the input of a HALIOS® multi-purpose sensor
IC E909.05/E909.06.
(*) in systems with highly focused IR beams and optimized
optical sensor surfaces
Applications
ÿ Optical receivers
ÿ Transimpedance amplifiers
ÿ Multiplex function for channel expander of
the chip set E909.05/E909.06
Ordering Information
Ordering No.: Temp. RangeAmb
E90907A52C
RVDD
CVDD
GVDD
CGHS
GHS
AVDD_LA
DP CINP
INN
INP
AVDD
IO_CTRL
Gyrator
AMP
-
-
+
+
E909.06
HALIOS®
Sensor IC
OUT
GAIN_CTRL
A
CGLS
GLS
QFN20L4
AVDD
C
CINN
-40°C to +105°C
Package
OUTP_LA
AVDD/2
OUTN_LA
Gyrator
Limiting
Amplifier
AN
KA
ON_LA
GPIO_1
ON
GPIO_2
E909.07
GGND
AGND
AGND_LA
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Data Sheet
1/13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
1 Package and Pinout
1.1
No
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
Pin Description
Name
INN
INP
A
GLS
GHS
GVDD
GGND
AMP
GAIN_CTRL
ON_LA
OUTP_LA
OUTN_LA
ON
OUT
AVDD_LA
AGND_LA
IO_CTRL
AVDD
AGND
C
EP
Type
A_I
A_I
A_IO
A_IO
A_IO
S
S
A_IO
D_I
D_I
A_O
A_O
D_I
A_O
S
S
D_I
S
S
A_IO
S
Description
Negative input of transimpedance amplifier (TIA)
Positive input of transimpedance amplifier (TIA)
Anode of photodiode connected to high side gyrator
Low pass frequency control (to GGND)
High pass frequency control (to GVDD)
Supply gyrator
Ground gyrator
Output of TIA or input of limiting amplifier (LA) controlled by IO_CTRL
Controls gain of LA, integrated pull down
Enabling output of LA , active Hi, integrated pull-down
Positive output limiting amplifier
Negative output limiting amplifier
Activation signal for amplifier-IC, active Hi, integrated pull-down
Output of OPAMP
Supply limiting amplifier (LA)
Ground limiting amplifier (LA)
Controls the input of the limiting amplifier, integrated pull down
Supply transimpedance amplifier (TIA) and inverting amplifier
Analogue ground
Cathode of photodiode connected to low side gyrator
Exposed Die Pad
Table 1: Pin Description
Explanation of Types:
A = Analogue, D = Digital, S = Supply, I = Input, O = Output, B = Bidirectional, HV = High Voltage
When connecting the supply pins the requirements of the entire system has to be taken into account.
For highest sensitive it is recommended to use a separate RC filter for every supply input.
The ground pins GGND, AGND_LA and AGND must be soldered together in any application!
Pin EP, IO_CTRL and GAIN_CTRL must be soldered to Ground or VDD. See Chapter 5.7
Elmos Semiconductor AG reserves the right to change the detail specifications as may be required to permit improvements in the design of its products.
Elmos Semiconductor AG
Data Sheet
Page 2 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
1.2
Package Reference
The device is available in a Pb free, RoHS compliant, 20-lead Quad Flat No Lead QFN20L4 package
with 16mm² (0.024 square inch) according to JEDEC standard MO-220- K ; Variant: VGGD-5.
1.3
Package Pinout
Fig. 2: Package Pinout E909.07 (Top View)
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Data Sheet
Page 3 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
2 Block Diagram
GVDD
GHS
IO_CTRL
GAIN_CTRL
AVDD
AVDD_LA
Gyrator
C
INN
OUT
INP
Transimpedance
Amplifier
Linear Amplifier
AMP
AVDD
2
OUTP_LA
A
OUTN_LA
Limiting Amplifier
GLS
ON_LA
Gyrator
ON
GGND
AGND
AGND_LA
Fig. 3: Block Diagram E909.07
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Elmos Semiconductor AG
Data Sheet
Page 4 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
3 Operating Conditions
3.1
•
•
•
Absolute Maximum Ratings
Operating the device at or beyond these limits may cause permanent damage.
All voltages are referred to ground (0V).
Currents flowing into the circuit have positive values.
No.
Description
1 Negative supply voltage
2
Positive supply voltage
3
5
Voltage digital I/O pins:
ON, ON_LA, IO_CTRL, GAIN_CTRL
Input current at digital pins:
ON_LA, IO_CTRL, GAIN_CTRL
Voltage at analogue pins
6
7
8
Input current at analogue pins
Junction temperature
Ambient temperature
4
9 Storage temperature
10 Power dissipation
Condition
Symbol
AGND,
GGND,
AGND_LA
AVDD,
GVDD,
AVDD_LA
V(DPIN)
I(DPIN)
V(APIN)
packaged
devices
I(APIN)
TJ
TA
TA ≤ 85°C
TSTG
PTOT
Min
0
Max
0
Unit
V
-0,3
+3,6
V
-0,3 AVDD
+ 0,3
-10
10
-0,3 AVDD
+ 0,3
-100 100
-40 +125
-40 +105
-40
+150
150
V
mA
V
mA
°C
°C
°C
mW
Table 2: Absolute Maximum Ratings
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Data Sheet
Page 5 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
3.2
Recommended Operating Conditions
•
Parameters are guaranteed within the range of recommended operating conditions unless otherwise
specified.
• All voltages are referred to
• ground (0V).
• Currents flowing into the circuit have positive values.
No.
Description
Condition
Symbol
Min
Typ
Max Unit
1 Positive supply voltage
AVDD, GVDD 3.0
3.3
3.5
V
10
µF
2 VDD filter and buffer capacitor Low-ESR type
CVDD
3 Input coupling capacitors
CINN = CINP
CINN, CINP
0.22 0.47
10
nF
4 Gyrator coupling capacitors
CGLS = CGHS
CGLS, CGHS
10
47
220
nF
5 Capacitive load at output OUT
CLOAD, OUT
100
pF
6 Capacitive load at output AMP
CLOAD, AMP
100
pF
7 Capacitive load at Pin
CLOAD, OUTx_LA
100
pF
OUTP_LA, OUTN_LA
8 Junction Temperature
normal operation
TJ
-40
+105
°C
9 Thermal resistance, junction to QFN20L4
RT,J-A
45
°C/W
ambient
10 VDD Filter resistor
RVDD
10
20
Ω
11 Capacitance of photo diode at
CDIODE
70
250
pF
input C / A
Table 3: Recommended Operating Conditions
4 Detailed Electrical Specification
4.1
Supply
No.
Description
1 Supply current 1), 2)
2
Average supply current 1), 3), 4)
3
Sleep Mode supply current 1), 2)
Condition
ON = AVDD,
ON_LA = AVDD,
IC = IA = 0mA,
ON = AVDD,
ON_LA = AVDD,
IC = IA = 0mA,
ON = 0V,
ON_LA = 0V,
Symbol
IVDD
IVDD,AV
Min
Typ
3.5
Max
5.0
0.23
IVDD,SLEEP
Unit
mA
mA
1
µA
Table 4: Electrical Parameters Supply
1) Average current from photodiode PD negligible
2) Total supply current to AVDD, AVDD_LA and GVDD
IVDD = IAVDD + IAVDD_LA + IGVDD
3) Power Consumption Calculation
Sample Rate: 10ms
Settling time TSW : 500µs
Measurement time: 250µs
Duty cycle: (500µs + 250µs)/10ms ~ 1/13
IVDD,AV = 5mA * duty cycle ~ 385µA
4) Not tested in production test
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Elmos Semiconductor AG
Data Sheet
Page 6 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
4.2
Transimpedance Amplifier
No.
Description
1 Internal feedback
resistance of TIA
2 Input impedance INP
3 Maximum output voltage
(TIA drive capability)
4 Minimum output voltage
(TIA drive capability)
5 Common Mode Rejection Rate
∆VOUT_TIA_cm / ∆VOUT_TIA_dm
6 Internal feedback capacitor of
transimpedance amplifier 1)
7 -3dB Corner frequency TIA
Condition
Measured from
INN to AMP
Symbol
RTIA
Min
75
Typ
100
Max
125
Unit
kΩ
RINP
75
2.8
100
125
kΩ
V
0.5
V
IAMP = -500µA
AVDD=3.3V
IAMP = +500µA
VAMP, max
@22kHz
CMRR
80
dB
Cf
2.25
pF
fCS
600
kHz
VAMP, min
Table 5: Electrical Parameters Transimpedance Amplifier
4.3
Gyrator
No.
Description
1 Voltage drop at low-side
gyrator input (A)
2 Voltage drop at high-side
gyrator input (C)
3 Max. photo current
Condition
IA = 10mA
Symbol
VA - VGGIND
Min
0.75
Typ
1.0
Max
1.25
Unit
V
IC = -10mA
VGVDD - VC
0.75
1.0
1.25
V
IPhoto
10
mA
Table 6: Electrical Parameter Gyrator
4.4
Linear Amplifier
No.
Description
1 Gain linear amplifier
2 Maximum output voltage
3
4
Minimum output voltage
-3dB Corner frequency
Condition
ILIN = -500µA
AVDD = 3.3V
ILIN = +500µA
Symbol
G0, lin
VLIN,max
Min
Typ
-10
Max
Unit
V/V
V
1.0
V
kHz
2.3
VLIN,min
fCS
600
Table 7: Electrical Parameters Linear Amplifier
1) Not tested in production test
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Data Sheet
Page 7 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
4.5
High pass filter and limiting amplifier
No.
Description
1 Differential gain
AVOUT_LA= (OUTP_LA OUTN_LA) / AMP
2 Differential gain
AVOUT_LA= (OUTP_LA OUTN_LA) / AMP
3 Maximum output voltage 2)
4
Minimum output voltage 2)
5
Single ended output resistance
6
-3dB Corner frequency high
pass filter1)
Overall gain (TIA +LA) 1)
Condition
GAIN_CTRL = 0
Symbol
AVOUTL0
GAIN_CTRL = 1
AVOUTL1
65
V/V
IOUTP_LA = -10µA
VOUTP_LA,max
V
IOUTP_LA = -10µA
VOUTP_LA,min
ROUTN_LA
AVDD 0.1
AVDD 1.1
1.5
kΩ
fG
15
kHz
G
RTIA*
AVOUTL0
MΩ
1) 2)
7
GAIN_CTRL=0
IO_CTRL = 0
Min
Typ
Max
(AVOUTL1)2)
Unit
V/V
V
Table 8: Electrical Parameter High pass filter and limiting amplifier
4.6
Digital Control Inputs
No.
Description
Condition
1 Input low level (Pin ON,
ON_LA)
2 Input high level (Pin ON,
ON_LA)
Settling time after switching on ON_LA="0"
3 the limiting amplifier1)
"1"
4 Settling time after switching
from sleep to operating mode1)
5 Pull down resistor 1)
Symbol
VIL
Min
Typ
VIH
AVDD0.8
Max
0.8
Unit
V
V
TSON
1
µs
TSW
500
µs
RPD
800
1600
kΩ
Table 9: Electrical Parameters Digital Control Inputs
1) Not tested in production test
2) For proper operation, the output pins OUTN_LA & OUTP_LA must be decoupled with
capacitors close to the E909.07. The load at these output pins shall be a load against ground.
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Data Sheet
Page 8 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
5 Functional Description
5.1
Brief Functional Description
The E909.07 is transimpedance amplifier with high amplification. The differential inputs INN, INP and
the differential limiting outputs OUTP_LA, OUTN_LA are forming the main signal path. Within the
application field of optical receiver systems it uses a photodiode as input signal source. The differential
outputs are designed for use in HALIOS® optical detector systems. The total transimpedance figure in
this path is 200MΩ minimum.
Together with the HALIOS® chip set E909.05/ E909.06 motion detectors with a detection range of
several meters can be realized. By switching the output to high impedance state several optical
receivers for multiple input channels can be multiplexed to one input of a HALIOS® sensor IC
E909.05/E909.06, which enables a very economical construction of multi sensor systems with multiple
optical detector nodes. These can be operated at minimum power consumption by use of the SLEEPmode feature of the E909.07 (controlled by pin ON)
5.2
Supply
The input GVDD, AVDD should be low pass filtered to increase ambient light suppression and EMC
robustness.
5.3
Transimpedance Amplifier
The current input signal from an external differential source connected between INN and INP - typically
a photodiode - is amplified in a first stage transimpedance amplifier (TIA) with a typical transimpedance
figure of 100kΩ. The input photodiode has to be AC-coupled to the inputs by capacitors (CINN , CINP).
The output of this TIA-stage is accessible at terminal AMP.
In order to achieve a good suppression of common mode disturbances at the pins C and A, the AC
coupling capacitors CINN, CINP should have a very good matching.
5.4
Gyrator
Gyrator input stages at nodes C (cathode) and A (anode) are used to define the input operating point of
the input photo diode properly. These gyrators are designed for a maximum DC current of 10mA (photo
current) which corresponds to a very high level of ambient light applied to the photo diode. When the
device is switched off (ON = 0) the gyrator is also switched off.
5.5
Linear Amplifier
Additionally to the limiting amplifier output an inverting amplifier output with an amplification factor of typ.
-10 (20dB) is available and can be routed into the signal path. This results in a total transimpedance of
typ. 2MΩ at OUT with respect to the input of the TIA.
5.6
High Pass Filter and Limiting Amplifier
The limiting amplifier consists of six differential amplifier stages. At the input and after the third stage a
high pass filter is placed. Thus the frequency behaviour between the limiting amplifier input IN_LA and
the outputs OUTP_LA, OUTN_LA can be described with a second order high pass filter. These stages
provide symmetrical outputs at OUTP_LA, OUTN_LA which are inverted with respect to each other.
The differential gain (in the linear range) from the input of limiting amplifier (AMP) to the output
(OUTP_LA - OUTN_LA) has a typ. value of +4225. In case of input overdrive excessive phase shift is
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Elmos Semiconductor AG
Data Sheet
Page 9 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
avoided by the limiting amplifiers.
The outputs OUTP_LA, OUTN_LA are source follower outputs, which buffer the last differential stage of
the limiting amplifier. The external load at these outputs should not be smaller than 10k, to avoid
reduction of the output swing. The maximum output voltage swing has a typical value of 1V. The limiting
outputs can be switched to high impedance by use of control input ON_LA. This allows output
multiplexing of several amplifier devices, e.g. in multi-sensor systems.
Using the input ON_LA during multiplex mode to switch between the channels of several E909.07
switching times of 1µs can be realized.
5.7
Digital Control Inputs
Four control inputs are provided:
•
ON_LA enables the limiting amplifier and activates the outputs OUTP_LA, OUTN_LA by closing the
switch between the limiting amplifier and the output pins when pulled to high level. An internal pull
down keeps the outputs in OFF mode (high impedance) when the pin is left open. If ON_LA is 0 the
outputs are in high-impedance state.
•
Input ON is used to switch the device from OPERATING mode to SLEEP mode. The device is
active, when ON is pulled high to supply voltage AVDD. With ON = 0, the all components in the
devices are switched off and the current consumption drops to almost zero. An internal pull-down will
hold the device in SLEEP mode when the pin is left open.
•
Input GAIN_CTRL allows to reduce the amplification factor of the limiting amplifier by bypassing one
of the two amplification stages.
• With GAIN_CTRL = 0 both stages are active, the amplification factor has its maximum value.
• With GAIN_CTRL = 1 one amplifier stage is bypassed thus reducing the amplification factor by a
factor of 2.
•
Input IO_CTRL allows to disconnect the TIA output from the pin AMP. Then it is possible to control
the limiting amplifier with an external signal. In all cases, the TIA is connected to the linear amplifier.
• IO_CTRL = 0: The output of the transimpedance amplifier (TIA) is connected to the input of the
limiting amplifier. The TIA output signal is available on the pin AMP which is of type output.
• IO_CTRL = 1: The output of the transimpedance amplifier is disconnected from the input of the
limiting amplifier. Pin AMP is the input of the limiting amplifier.
PIN
ON_LA
ON
GAIN_CTRL
IO_CTRL
Status
0
1
0
1
0
1
0
1
Description
Outputs OUTP_LA, OUTN,LA are inactive (high resistance state)
SLEEP Mode
Operating Mode
Both amplification stages are active, the amplification factor has its
maximum value
The second amplification stage is bypassed
TIA Output connected to input of limiting amplifier
TIA Output disconnected to input of limiting amplifier. Limiting amplifier
could be controlled by external signal (AMP)
Table 10: Table of Digital Control Inputs
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Data Sheet
Page 10 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
6 ESD, Latch up and EMC
6.1
Electro Static Discharge (ESD)
Standard
Model
Capacitance
Resistance
Minimum withstand Voltage
Supply and interface pins
(OUTP_LA, OUTN_LA, GGND, AGND_LA, AGND,
GVDD, AVDD_LA, AVDD)
AEC-Q100-002
Human Body Model
100 pF
1,5 kΩ
+/- 2 kV
+/- 4 kV
Table 11: ESD on IC Level, Human Body Model (HBM)
Standard
Model
Resistance
Minimum withstand Voltage
Pulse rise time (10%-90%)
AEC-Q100-011
Charged Device Model
1Ω
+/- 500 V
<400 ps
Table 12: ESD on IC Level, Charged Device Model (CDM)
6.2
Latch-up
Latch-up performance is validated according JEDEC standard JESD 78 in its valid revision.
6.3
EMC
The contents of this chapter were not specified yet!
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Data Sheet
Page 11 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
7 Package Information
The E909.07 is available in a Pb free, RoHs compliant QFN20L4 plastic package, for this exposed pad
size is no variant within JEDEC MO-220 K available. The package is classified to Moisture Sensitivity
Level 3 (MSL 3) according to JEDEC J-STD-020 with a soldering peak temperature of (260+5)°C.
Description
Symbo
l
mm
inch
min
typ
max
min
typ
max
Package height
A
0.80
0.90
1.00
0.031
0.035
0.039
Stand off
Thickness of terminal leads, including lead
finish
Width of terminal leads
A1
0.00
0.02
0.05
0.000
0.002
A3
--
0.20 REF
--
--
0.00079
0.0079
b
0.18
0.25
0.30
0.0071
0.0098
0.012
D/E
--
4.00 BSC
--
--
0.157 BSC
--
D2 / E2
2.50
2.65
2.80
0.098
0.104
0.110
Package length / width
Length / width of exposed pad
REF
--
Lead pitch
e
--
0.50 BSC
--
--
0.020 BSC
--
Length of terminal for soldering to substrate
L
0.35
0.40
0.45
0.014
0.016
0.018
Number of terminal positions
N
20
20
Note: the mm values are valid, the inch values contains rounding errors
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Data Sheet
Page 12 of 13
QM-No.: 25DS0047E.04
Transimpedance Amplifier with High Sensitivity
E909.07
PRODUCTION DATA – MAR 25, 2014
WARNING – Life Support Applications Policy
Elmos Semiconductor AG is continually working to improve the quality and reliability of its products. Nevertheless,
semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical
stress. It is the responsibility of the buyer, when utilizing Elmos Semiconductor AG products, to observe standards of safety, and
to avoid situations in which malfunction or failure of an Elmos Semiconductor AG Product could cause loss of human life, body
injury or damage to property. In the development of your design, please ensure that Elmos Semiconductor AG products are
used within specified operating ranges as set forth in the most recent product specifications.
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Information furnished by Elmos Semiconductor AG is believed to be accurate and reliable. However, no responsibility is
assumed by Elmos Semiconductor AG for its use, nor for any infringements of patents or other rights of third parties, which may
result from its use. No license is granted by implication or otherwise under any patent or patent rights of Elmos Semiconductor
AG. Elmos Semiconductor AG reserves the right to make changes to this document or the products contained therein without
prior notice, to improve performance, reliability, or manufacturability .
Application Disclaimer
Circuit diagrams may contain components not manufactured by Elmos Semiconductor AG, which are included as means of
illustrating typical applications. Consequently, complete information sufficient for construction purposes is not necessarily given.
The information in the application examples has been carefully checked and is believed to be entirely reliable. However, no
responsibility is assumed for inaccuracies. Furthermore, such information does not convey to the purchaser of the
semiconductor devices described any license under the patent rights of Elmos Semiconductor AG or others.
Contact Information
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: +492317549100
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