AMSCO AS1545-BQFT

Da t as heet
AS1545
Dual, 12-Bit, 1MSPS, SAR ADC
1 General Description
2 Key Features
The AS1545 is a dual, 12-bit, 6-channel, 1 MSPS, high
speed, successive approximation (SAR) analog-todigital converters (ADCs). The AS1545 is designed to
operate with a single +2.7V to +5.25V supply and a
sampling rate of up to 1 MSPS.
The device contains two ADCs, each preceded by a 6channel multiplexer and a high-bandwidth track/hold
amplifier. Data access is made via standard control
inputs in support of wide range of microprocessors and
DSPs.
The device requires very low supply-current at the
1MSPS maximum sampling speed, and features flexible
power-down modes to reduce power consumption at
slower throughput rate.
The AS1545 contains an internal 2.5V reference and
integrated reference buffer that can be over driven when
an external reference is required.
Superior AC characteristics, low power consumption,
and highly reliable packaging makes the AS1545 perfect
for portable battery-powered remote sensors and dataacquisition devices.
!
Sampling Rate: 1MSPS per ADC
!
Dual 12-bit serial interface
!
Software Configurable Analog Input Types:
!
- 12-Channel Single-Ended
- 6-Channel Pseudo-Differential
- 6-Channel Fully Differential
Internal +2.5V Reference or External: 1V to VDD
!
Rail to Rail Common Mode Input Range
!
Low-Power Consumption
!
- 15mW max. at 1MSPS with 2.7V supplies
- 37mW max. at 1MSPS with 5.25V supplies
Dual conversion with read at 20 MHz SCLK
!
Single-Supply Operation: +2.7V to +5.25V
!
Motor Control Registers: Difference of Inputs,
Quadrature Signal Phases, Direction and Step
Down Counter
!
32-lead TQFN Package
3 Applications
The AS1545 is available in a 32-lead TQFN package.
The device is ideal for motor control like encoder feedback or current sense, motion control such as robotics,
sonar, or for any other radio frequency identification.
Figure 1. AS1545 - Block Diagram
REF_SELECT
REF
BUF
MUX
T/H
DVDD
System
Control
Registers
AIN 0
AIN 1
AIN 2
AIN 3
AVDD
REFA
12-Bit
SAR and A/D
Conversion
Control
OutPut
Drivers
AIN 4
AIN 5
DOUTA
SCLK
CSN
RANGE
SGL/DIFF
A0
A1
A2
Control Logic
and
System Control
Registers
BIN 0
BIN 1
VDRIVE
BIN 2
BIN 3
MUX
12-Bit
SAR and A/D
Conversion
Control
T/H
OutPut
Drivers
DOUTB
BIN 4
BIN 5
AS1545
BUF
AGND
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AGND
AGND
REFB
Revision 1.01
DGND
DGND
1 - 34
AS1545
Datasheet
Contents
1
2
3
4
5
6
7
8
9
General Description ................................................................................................................................................
Key Features ...........................................................................................................................................................
Applications .............................................................................................................................................................
Pinout ......................................................................................................................................................................
1
1
1
3
Pin Assignment .................................................................................................................................................... 3
Pin Description .................................................................................................................................................... 3
Absolute Maximum Ratings .................................................................................................................................... 5
Electrical Characteristics ......................................................................................................................................... 6
Timing Characteristics ..................................................................................................................................... 9
Typical Operating Characteristics ......................................................................................................................... 10
Terminology ........................................................................................................................................................... 15
Detailed Description .............................................................................................................................................. 18
Analog Input .......................................................................................................................................................
Acquisition Time ............................................................................................................................................
Analog Input Composition .............................................................................................................................
Analog Input Modes ......................................................................................................................................
Single-Ended Mode .......................................................................................................................................
Fully Differential Mode ..................................................................................................................................
Pseudo Differential Mode ..............................................................................................................................
Analog-to-Digital Conversion .............................................................................................................................
Output Coding ...............................................................................................................................................
Transfer Functions ........................................................................................................................................
Digital Inputs ......................................................................................................................................................
VDRIVE Functionality.....................................................................................................................................
10 Application Information .......................................................................................................................................
18
18
19
20
21
21
22
23
23
23
24
24
25
Operation Modes ............................................................................................................................................... 25
Full Power-Up Mode ..................................................................................................................................... 25
Full Power-Down Mode ................................................................................................................................. 25
Partial Power-Down Mode ............................................................................................................................ 26
Power-Up Times ........................................................................................................................................... 27
Power vs. Throughput Rate .......................................................................................................................... 28
Serial Interface ................................................................................................................................................... 28
Difference calculator and quadrature signals calculator ................................................................................ 29
Direction of the rotor based on DIR bit .......................................................................................................... 30
11 Application Hints .................................................................................................................................................. 31
Grounding and Layout ................................................................................................................................... 31
PCB Design Guidelines for TQFN ................................................................................................................. 31
12 Package Drawings and Markings ........................................................................................................................ 32
13 Ordering Information ........................................................................................................................................... 33
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Revision 1.01
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AS1545
Datasheet - P i n o u t
4 Pinout
Pin Assignment
VDRIVE
DOUTA
DGND
DOUTB
CSN
A0
32
31 30
29
28 27 26
25
SCLK
DVDD
Figure 2. Pin Assignments (Top View)
1
24
A1
REF_SELECT 2
23
A2
22
SGL/DIFF
DGND
AVDD
3
AS1545
REFA
4
AGND
5
20
REFB
AGND
6
19
AGND
BIN 5
18
BIN 0
17
BIN 1
BIN 2
13 14 15 16
BIN 3
11 12
BIN 4
10
AIN 5
9
AIN 4
33 Exp. Pad
AIN 3
7
8
AIN 2
AIN 0
AIN 1
21 RANGE
Pin Description
Table 1. Pin Description
Pin Number
Pin Name
1, 29
DGND
2
REF_SELECT
3
AVDD
Description
Digital Ground. Ground reference point for the digital portion of the
AS1545.
Reference select pin. Internal/External Reference Selection. Logic input. If
this pin is tied to DGND, the on-chip 2.5V reference is used as the reference
source for both ADC A and ADC B. In addition, Pin REFA and Pin REFB
must be tied to decoupling capacitors. If the REF SELECT pin is tied to a
logic high, an external reference can be supplied to the AS1545 through the
REFA or REFB pins.
Analog Supply Voltage. 2.7V to 5.25V.
4, 20
REFA, REFB
Reference Input/Output. These pins are connected to the internal
reference through a series resistor and is the reference source for the
AS1545. The nominal reference voltage is 2.5V and appears at the pin. This
pin can be over-driven by an external reference or can be taken as high as
AVDD. Decoupling capacitors (4.7 uF recommended) are connected to
these pins to decouple the reference buffer for each respective ADC.
5
AGND
Analog Ground. Decouple point for AVDD. Ground reference for track/hold,
reference, and DAC circuits.
6, 19
AGND
Analog Ground. Decouple point for VREF capacitors and analog input
filters. Pin 6 is the decoupling point for REFA, pin 19 for REFB. Ground
reference for track/hold, reference, and DAC circuits.
7 to 12
AIN0 to AIN5
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Analog Inputs of ADC A. These may be programmed as six single-ended
channels, three pseudo-differential or three true-differential analog input
channel pairs.
Revision 1.01
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AS1545
Datasheet - P i n o u t
Table 1. Pin Description
Pin Number
Pin Name
Description
BIN0 to BIN5
Analog Inputs of ADC B. These may be programmed as six single-ended
channels, three pseudo-differential or three true-differential analog input
channel pairs. (see Table 5 on page 20).
21
RANGE
Analog Input Range Selection. Logic input. The polarity on this pin
determines the input range of the analog input channels. If this pin is tied to
a logic low, the analog input range is 0V to VREF. If this pin is tied to a logic
high when CSN goes low, the analog input range is 2 × VREF.
22
SGL/DIFF
23 to 25
A2 to A0
Multiplexer Select. Logic inputs. These inputs are used to select the pair of
channels to be simultaneously converted, such as Channel 1 of both ADC A
and ADC B, Channel 2 of both ADC A and ADC B, and so on.
26
CSN
Chip Select. Active low logic input. This input provides the dual function of
initiating conversions on the AS1545 and framing the serial data transfer.
27
SCLK
Serial Clock Input. A serial clock input provides the SCLK for accessing the
data from the AS1545. This clock is also used as the clock source for the
conversion process.
DOUTB, DOUTA
Serial Data Outputs. The data output is supplied to each pin as a serial
data stream. The bits are clocked out on the falling edge of the SCLK input
and 15 SCLKs are required to access the data. The data simultaneously
appears on both pins from the simultaneous conversions of both ADCs. The
data stream consists of three leading zeros followed by the 12 bits of
conversion data. The data is provided MSB first. If CSN is held low for 16
SCLK cycles rather than 15, then single trailing zero appears after the 12bits
of data. If CSN is held low for a further 16 SCLK cycles on either DOUTA or
DOUTB, futher data is clocked out according to the timing diagram.
VDRIVE
Logic Power Supply Input. The voltage supplied at this pin determines at
what voltage the interface operates. This pin should be decoupled to DGND.
The voltage at this pin may be different than that at AVDD and DVDD but
should never exceed either by more than 0.3V.
32
DVDD
Digital Supply Voltage. 2.7V to 5.25V. This is the supply voltage for all
digital circuitry on the AS1545. The DVDD and AVDD voltages should ideally
be at the same potential and must not be more than 0.3V apart even on a
transient basis. This supply should be decoupled to DGND.
33
Exp. Pad
13 to 18
28, 30
31
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Logic Input. This pin selects whether the analog inputs are configured as
differential pairs or single ended. A logic low selects differential operation
while a logic high selects single-ended operation.
Exposed Pad. This pin can be not connected or connected AGND. The
exposed pad must not be connected to VDD.
Revision 1.01
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AS1545
Datasheet - A b s o l u t e M a x i m u m R a t i n g s
5 Absolute Maximum Ratings
Stresses beyond those listed in Table 2 may cause permanent damage to the device. These are stress ratings only,
and functional operation of the device at these or any other conditions beyond those indicated in Electrical
Characteristics on page 6 is not implied. Exposure to absolute maximum rating conditions for extended periods may
affect device reliability.
Table 2. Absolute Maximum Ratings
Parameter
Min
Max
Units
VDD to AGND
-0.3
+7
V
DVDD to DGND
-0.3
+7
V
VDRIVE to DGND
-0.3
DVDD
V
VDRIVE to AGND
-0.3
AVDD
V
AVDD to DVDD
-0.3
+0.3
V
AGND to DGND
-0.3
+0.3
V
Analog Input Voltage to AGND
-0.3
AVDD + 0.3
V
Digital Input Voltage to DGND
-0.3
+7
V
Digital Output Voltage to DGND
-0.3
VDRIVE + 0.3
V
REFA, REFB to AGND
-0.3
AVDD + 0.3
V
±10
mA
Input Current to All Pins Except
AVDD or DVDD
Electro-Static Discharge
2
kV
Operating Temperature Range
-40
+85
ºC
Storage Temperature Range
-65
+150
ºC
Package Body Temperature
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+260
Revision 1.01
ºC
Comments
The reflow peak soldering temperature
(body temperature) specified is in
accordance with IPC/JEDEC J-STD-020D
“Moisture/Reflow Sensitivity Classification
for Non-Hermetic Solid State Surface Mount
Devices”.
The lead finish for Pb-free leaded packages
is matte tin (100% Sn).
5 - 34
AS1545
Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s
6 Electrical Characteristics
AVDD = DVDD = 2.7V to 5.25V, VDRIVE = 2.7 V to AVDD/DVDD, fSCLK = 20 MHz, fSAMPLE = 1 MSPS, TAMB = -40 to
+85°C, external reference = 2.5V, RANGE = 0, Typical values at 5.25V and 25°C with external reference; Unless otherwise specified.
Table 3. Electrical Characteristics
Symbol
Parameter
Condition
Min
Typ
70
72
71
72.5
Max
Unit
Dynamic Specifications 50kHz sinewave input
SINAD
Signal to Noise + Distortion
Ratio
SNR
Signal-to-Noise Ratio
THD
Total Harmonic Distortion
SFDR
Spurious-Free Dynamic
Range
SINAD
Signal to Noise + Distortion
SNR
Signal-to-Noise Ratio
THD
Total Harmonic Distortion
SFDR
Spurious-Free Dynamic
Range
IMD
Intermodulation Distortion
Fully Differential Mode
Single Ended or Pseudo
Differential Mode
-81
-77
-83
-75
68
72
69
72.5
-81
-73
-83
-75
Second Order Terms
-75
Third Order Terms
-100
Channel-to-Channel Isolation
dB
dB
dB
-90
Sample and Hold
Aperture Delay
13
Aperture Jitter
30
Aperture Delay Matching
Full Power Bandwidth
ns
ps
200
3 dB, VDD = 5V
39
3 dB, VDD = 3V
35
0.1 dB, VDD = 5V
3.1
0.1 dB, VDD = 3V
2.9
Fully Differential Mode
±0.4
±0.99
Single-Ended and Pseudo
Differential Modes
±0.4
±0.99
Differential mode
±0.25
±0.99
Single-Ended and Pseudo
Differential Modes
±0.25
±0.99
±0.5
±6
ps
MHz
MHz
DC Accuracy
Resolution
Integral Nonlinearity
Differential Nonlinearity
12
Bits
LSB
LSB
Straight Binary Output Coding
Offset Error
Offset Error Match
Gain Error
Single-Ended and PseudoDifferential Mode
Gain Error Match
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±0.5
±0.75
±0.5
Revision 1.01
±2.5
LSB
LSB
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AS1545
Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s
Table 3. Electrical Characteristics (Continued)
Symbol
Parameter
Condition
Min
Typ
Max
Unit
Twos Complement Output Coding
Positive Gain Error
±2
Positive Gain Error Match
Zero Code Error
Zero Code Error Match
±0.5
±0.5
Fully Differential Mode
±5
±0.5
Negative Gain Error
±2
Negative Gain Error Match
±0.5
LSB
LSB
LSB
Analog Input
VINx
Single Ended Input Voltage
Ranges
VINx - VINy
Pseudo Differential Input
Voltage Ranges
VINx &
VINy
Differential Input Voltage
Ranges
VCM
Common Mode Voltage
Bit RANGE = 0
0
VREF
Bit RANGE = 1
0
2xVREF
Bit RANGE = 0
VCM
VCM+VREF
Bit RANGE = 1
VCM
VCM+
2xVREF
Bit RANGE = 0
VCMVREF/2
VCM+
VREF/2
Bit RANGE = 1
VCMVREF
VCM+
VREF
0
VDD
V
±1
µA
VDD
V
Leakage Current
Absolute Analog Input Voltage
Input Capacitance
0
V
V
V
Track Mode
15
pF
Hold Mode
8
pF
Reference Input/Output
REFIN
Input Voltage Range
1
REFOUT
Output Reference Voltage
2.475
ILEAK
Leakage Current
REFOUT
TEMPCO
2.5
VDD
V
2.525
V
±1
µA
Input Capacitance
30
pF
REFA, REFB Output
Impedance
5
Ω
Reference Temperature
Coefficient
30
ppm/ºC
Logic Inputs
VIH
Input High Voltage
VIL
Input Low Voltage
IIN
Input Current
CIN
Input Capacitance
VDD < 5V
0.7x
VDRIVE
VDD > 5V
2.8
VIN = 0 V or VDRIVE
V
-1
0.4
V
+1
µA
5
pF
Logic Outputs
VOH
Output High Voltage
ISOURCE = 200µA
VOL
Output Low Voltage
ISINK = 200µA
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Revision 1.01
VDRIVE
- 0.2
V
0.4
V
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AS1545
Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s
Table 3. Electrical Characteristics (Continued)
Symbol
Parameter
Condition
Floating State Leakage
Current
DOUT = GND or VDD
Min
Floating State Output
Capacitance
Output Coding
Typ
Max
Unit
±1
µA
7
pF
Straight binary
(Single-Ended &
Pseudo-Differential)
Two’s complement
(Fully Differential)
Conversion Rate
tCONV
Conversion Time
tACQ
Track/Hold Acquisition Time
Exclusive of tACQ
15tSCLK
Full-scale step input; VDD = 5V
90
Full-scale step input; VDD = 3V
110
Throughput Rate
ns
1
MSPS
2.7
5.25
V
2.7
AVDD/
DVDD
V
Power Requirements
VDD
Positive Supply Voltage
VDRIVE
Interface Supply Voltage
Normal Mode (Static)
Operational, fS = 1 MSPS
IDDA+IDDD
Partial Power-Down Mode
AVDD = DVDD
VDD = 5.25V, internal Ref. on
4
5
mA
VDD = 5.25V, internal Ref. on
6.5
7
mA
VDD = 2.7V, internal Ref. on
5.2
5.5
mA
500
µA
1
µA
VDD = 5.25V, internal Ref. on,
Static
Full Power-Down Mode
PD
Operational, fS = 1 MSPS
VDD = 5.25V, internal Ref. on
36.75
mW
Partial Power-Down
VDD = 5.25V, internal Ref. on
2.6
mW
5.25
µW
Full Power-Down
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Revision 1.01
8 - 34
AS1545
Datasheet - E l e c t r i c a l C h a r a c t e r i s t i c s
Timing Characteristics
AVDD = DVDD = 2.7V to 5.25V, VDRIVE = 2.7V to AVDD/DVDD, internal/external reference = 2.5V, TA = -40 to +85°C
(unless otherwise specified).
Table 4. Timing Characteristics
1
Parameter
Symbol
Master Clock Frequency
fSCLK
Conversion Time
tCONVERT
Conditions
Min
Typ
Max
Units
20
MHz
tSCLK = 1/fSCLK
15 x
tSCLK
ns
fSCLK = 20 MHz
750
1
Quiet Time
tQUIET
Minimum time between end of serial
read and next falling edge of CSN
30
ns
CSN Fall to SCLK Fall Setup
Time
tCSS
VIL of CSN to VIL of SCLK
10
ns
CSN Fall to DOUT Enable
tCSDOE
VIL of CSN to Corner of DOUT
15
VDD = 2.7V
40
VDD = 5.25V
10
2
tDOV
SCLK Fall to DOUT Valid
SCLK Fall to DOUT Hold
3
tDOH
VDD = 2.7V
10
VDD = 5.25V
5
ns
ns
ns
SCLK Low Pulse Width
tCL
VIL to VIL of SCLK
0.4
tSCLK
0.6
tSCLK
SCLK High Pulse Width
tCH
VIH to VIH of SCLK
0.4
tSCLK
0.6
tSCLK
CSN Rise to DOUT Disable
tCSDOD
VIH of CSN to corner of DOUT to Tristate
CSN Minimum Pulse Width
tCSPW
VIH to VIH of CSN
30
SCLK Fall to DOUT Disable
tDOD
VIH of SCLK to corner of DOUT to
Tristate
5
20
ns
ns
50
ns
1. Based on simulation and characterised samples.
2. VIL of SCLK to VOH of DOUT (rising edge) / VOL of DOUT (falling edge)
3. VIL of SCLK to VOL of DOUT (rising edge) / VOH of DOUT (falling edge)
Figure 3. Timing Diagram
CSN
tCSPW
tCSS
SCLK
tCH
1
2
3
4
B
5
14
tCL
tDOH
tCSDOE
DOUTA
0
0
DB11
0
DOUTB THREESTATE
3 LEADING ZEROES
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tCSDOD
tDOV
DB10
DB9
Revision 1.01
DB2
DB1
DB0
tQUIET
THREE-STATE
9 - 34
AS1545
Datasheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
7 Typical Operating Characteristics
VDD = 5.25V, VREF = 2.5V, fSCLK = 20MHz (50% duty), fSAMPLE = 1MSPS, CREF = 4.7µF, RANGE = 0, SGL/DIFF = 1,
TAMB = +25ºC (unless otherwise specified).
Figure 4. Integral Nonlinearity vs. Digital Output Code;
Figure 5. Diff. Nonlinearity vs. Digital Output Code;
1
1
External Reference
0.8
0.8
0.6
0.6
0.4
0.4
DNL (LSB) .
INL (LSB) .
External Reference
0.2
0
-0.2
0.2
0
-0.2
-0.4
-0.4
-0.6
-0.6
-0.8
-0.8
-1
-1
0
1024
2048
3072
4096
0
1024
Digital Output Code
2048
Figure 6. Integral Nonlinearity vs. Digital Output Code;
1
Internal Reference
Internal Reference
0.8
0.8
0.6
0.6
0.4
0.4
DNL (LSB) .
INL (LSB) .
4096
Figure 7. Diff. Nonlinearity vs. Digital Output Code;
1
0.2
0
-0.2
0.2
0
-0.2
-0.4
-0.4
-0.6
-0.6
-0.8
-0.8
-1
-1
0
1024
2048
3072
4096
0
1024
Digital Output Code
20
10
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
FFT (dBc) .
100
200
300
400
20
10
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
-110
-120
500
Input Signal Frequency (kHz)
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3072
4096
Figure 9. FFT @ 50kHz, Internal Reference;
fSAMPLE = 1Msps
NFFT = 65536
SNR=72.8dB
THD = -84.6dB
SFDR = 88.2dB
SINAD = 72.5dB
0
2048
Digital Output Code
Figure 8. FFT @ 50kHz, External Reference;
FFT (dBc) .
3072
Digital Output Code
fSAMPLE = 1Msps
NFFT = 65536
SNR=72.2dB
THD = -84.7dB
SFDR = 87.9dB
SINAD = 71.9dB
0
100
200
300
400
500
Input Signal Frequency (kHz)
Revision 1.01
10 - 34
AS1545
Datasheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
Figure 10. Supply Current vs. Sampling Rate;
Figure 11. Supply Current vs. Supply Voltage;
10
10
Vdd=5V
9
1M SPS
9
.
8
.
8
Supply Current (mA)
7
Supply Current (mA)
Vdd=3V
7
6
5
4
3
2
1
st atic
6
5
4
3
2
1
0
0
0
200
400
600
800
1000
2.7
3
3.3 3.6
Sampling Rate (ksps)
Figure 12. Supply Current vs. Temperature;
.
Full Power-Down Current (nA)
.
Supply Current (mA)
9
6
5
4
3
2
1
0
-45 -30 -15
8
7
6
5
4
3
2
1
0
0
15
30
45
60
75
90
2.7
3
3.3 3.6
Temperature (°C)
5.1 5.4
510
.
Vdd=5V
Vdd=3V
Part. Power-Down Current (µA)
.
4.5 4.8
Figure 15. Partitial Power-Down Current vs. Temp.;
20
Full Power-Down Current (nA)
3.9 4.2
Supply Voltage (V)
Figure 14. Full Power-Down Current vs. Temperature;
18
5.1 5.4
10
Vdd=5V, 1M SPS
Vdd=5V, stat ic
Vdd=3V, 1M SPS
Vdd=3V, st atic
9
7
4.5 4.8
Figure 13. Full Power-Down Current vs. VIN;
10
8
3.9 4.2
Supply Voltage (V)
16
14
12
10
8
6
4
2
0
-45 -30 -15
0
15
30
45
60
75
90
Vdd=5V
490
470
450
430
410
390
370
-45 -30 -15
Temperature (°C)
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Vdd=3V
0
15
30
45
60
75
90
Temperature (°C)
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Datasheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
Figure 16. Part. Power-Down vs. Temperature;
Figure 17. Dynamic Performance vs. Supply Voltage;
500
.
450
Dynamic Performance (dB)
Part. Power-Down Current (µA)
.
90
400
350
300
Int. Ref = OFF
250
Int. Ref = ON
200
150
100
50
85
80
75
70
SINAD
SNR
65
THD
SFDR
0
60
2.7
3
3.3 3.6 3.9 4.2 4.5 4.8 5.1 5.4
2.7
Supply Voltage (V)
3
3.3 3.6
3.9 4.2
4.5 4.8
5.1 5.4
Supply Voltage (V)
Figure 18. Gain & Offset Error vs. Supply Voltage;
Figure 19. SINAD vs. Input Frequency, Single-Ended;
74
3
Off set Error
2
72
1
SINAD (dB) .
Offset/Gain Error (LSB)
.
Gain Error
0
-1
70
68
Rin=10Ohm
Rin=50Ohm
Rin=100Ohm
Rin=1kOhm
66
-2
-3
64
2.7
3
3.3
3.6
3.9 4.2
4.5
4.8 5.1
5.4
10
Supply Voltage (V)
100
1000
Input Frequency (kHz)
Figure 20. SINAD vs. Input Frequency, Single-Ended;
Figure 21. SINAD vs. Input Frequency, Differential;
74
75
72
SINAD (dB) .
SINAD (dB) .
70
65
68
66
64
Vdd=5.25V
Vdd=4.5V
Vdd=3.6V
Vdd=2.7V
60
70
Vdd=5.25V
Vdd=4.5V
Vdd=3.6V
Vdd=2.7V
62
55
60
10
100
1000
10
Input Frequency (kHz)
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100
1000
Input Frequency (kHz)
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Datasheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
Figure 22. ENOB vs. ReferenceVoltage;
Figure 23. THD vs. Input Frequency, Single-Ended;
12
-65
-70
THD (dB) .
ENOB (bit) .
11.8
Rin=10Ohm
Rin=50Ohm
Rin=100Ohm
Rin=1kOhm
11.6
11.4
11.2
-75
-80
-85
Vdd=5V
Vdd=3V
11
-90
1
1.5
2
2.5
3
3.5
4
4.5
5
10
Reference Voltage (V)
Figure 24. THD vs. Input Frequency, Single-Ended;
1000
Figure 25. THD vs Input Frequency, Differential;
-50
-60
Vdd=2.7V
Vdd=3.6V
Vdd=4.5V
Vdd=5.25V
-55
Vdd=2.7V
Vdd=3.6V
Vdd=4.5V
Vdd=5.25V
-65
THD (dB) .
-60
THD (dB) .
100
Input Frequency (kHz)
-65
-70
-75
-70
-75
-80
-80
-85
-85
-90
-90
10
100
1000
10
Input Frequency (kHz)
1000
Figure 27. ENOB vs. Input Frequency, Differential;
12
12
11.6
11.6
ENOB (bit) .
ENOB (bit) .
Figure 26. ENOB vs. Input Frequency, Single-Ended;
11.2
10.8
Vdd=5.25V
Vdd=4.5V
Vdd=3.6V
Vdd=2.7V
10.4
100
Input Frequency (kHz)
11.2
10.8
Vdd=5.25V
Vdd=4.5V
Vdd=3.6V
Vdd=2.7V
10.4
10
10
10
100
1000
Input Frequency (kHz)
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10
100
1000
Input Frequency (kHz)
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Datasheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
Figure 28. SNR vs. Input Frequency, Single-Ended;
Figure 29. SNR vs. Input Frequency, Differential;
75
74
72
70
SNR (dB) .
SINAD (dB) .
70
65
66
64
Vdd=5.25V
Vdd=4.5V
Vdd=3.6V
Vdd=2.7V
60
68
Vdd=5.25V
Vdd=4.5V
Vdd=3.6V
Vdd=2.7V
62
55
60
10
100
1000
10
100
Input Frequency (kHz)
Figure 31. INL/DNL vs. Reference Voltage, VDD = 5V;
1
1
0.8
0.8
0.6
0.6
INL/DNL (LSB) .
INL/DNL (LSB) .
Figure 30. INL/DNL vs. Reference Voltage, VDD = 3V;
0.4
0.2
0
-0.2
-0.4
INLmax
-0.6
0.4
0.2
0
-0.2
-0.4
INLmax
-0.6
INLmin
DNLmax
-0.8
1000
Input Frequency (kHz)
INLmin
DNLmax
-0.8
DNLmin
DNLmin
-1
-1
1
1.5
2
2.5
3
Reference Voltage (V)
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1
1.5
2
2.5
3
3.5
4
4.5
5
Reference Voltage (V)
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Datasheet - Te r m i n o l o g y
8 Terminology
Acquisition Time
The Acquisition time is the time needed by the ADC to accurately acquire the analog input voltage in the internal
sampling capacitor. During this time the ADC is in track mode.
Conversion Time
The Conversion Time is the time that the ADC needs to convert an acquired analog input into a corresponding digital
code. A Successive Approximation Register ADC usually needs a number of clocks dependant on the resolution.
During this time the ADC is in hold mode.
Throughput / Sample Rate
The Throughput or Sample Rate is the number of conversions performed by an ADC per second. It is usually specified
in Samples Per Second (SPS). The Throughput or Sample Rate is the reciprocal of the sum of Acquisition Time and
Conversion Time.
Aperture Delay
The Aperture Delay defines the time between the falling edge of CSN and the actual Sampling Instant. The Aperture
Delay Matching defines the maximum deviation of Aperture Delays across all 6 channels of one ADC.
Aperture Jitter
The Aperture Jitter is the deviation of the actual Sampling Instant. This deviation is totally random and the standard
deviation of the distribution is calculated with one sigma.
Differential Nonlinearity (DNL)
The Differential Nonlinearity is the deviation between the actual code widths to the ideal code widths of 1 LSB,
comparing all contiguous codes in the ADC. The ADC is specified according to its maximum and minimum DNL values
across all codes. A DNL value equal to -1 indicates a missing code in the transfer function.
Integral Nonlinearity (INL)
The Integral Nonlinearity measures the deviation from the actual transfer function to the best straight line that
minimizes the INL worst case values.
Offset Error
The Offset Error defines the absolute deviation of the first code transition (0x000h) to (0x001h) from the ideal input
voltage (AGND + 0.5 LSB) in Single Ended and Pseudo Differential Mode (binary output coding).
VIN
VREF
Offset Error = --------------- × 4096 – AVG ( MeasuredCodes )
Offset Error Match
The Offset Error Match defines the maximum deviation of the Offset Errors across all 6 channels of VIN in Single
Ended and Pseudo Differential Mode (binary output coding).
Gain Error
The Gain Error defines the absolute deviation of the last code transition (0xFFEh) to (0xFFFh) from the ideal input
voltage (VREF – 1.5 LSB) in Single Ended and Pseudo Differential Mode. The Offset Error is compensated.
VIN
VREF
Gain Error = OffsetError – AVG ( MeasuredCodes ) – --------------- × 4096
Gain Error Match
The Gain Error Match defines the maximum deviation of the Gain Errors across all 6 channels of VIN in Single Ended
and Pseudo Differential Mode (binary output coding).
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Datasheet - Te r m i n o l o g y
Zero Code Error
The Zero Code Error is the deviation of the midscale transition (all 0xFFFh to all 0x000h in 2’s complement output
coding) from the ideal input voltage (VIN+ - VIN- = 0V) in Fully Differential Mode.
VINP – VINN
VREF
Zero Code Error = ----------------------------------- × 4096 + 2048 – AVG ( MeasuredCodes )
Zero Code Error Match
The Zero Code Error Match defines the maximum deviation of the Zero Code Errors across all 6 channels of VIN in
Fully Differential Mode (2’s complement output coding).
Positive Gain Error
The Positive Gain Error is the deviation last code transition (0x7FEh) to (0x7FFh) in 2’s complement output coding
from the ideal input voltage (VIN+ - VIN- = +VREF - 0.5LSB @ Range=1 and +VREF/2 - 0.5LSB @ Range=0) in Fully
Differential Mode.
⎧ VINP – VINN
VREF
⎩
⎫
Positive Gain Error =Zero Code Error – ⎨ ----------------------------------- × 4096 + 2048 – AVG ( MeasuredCodes ) ⎬
⎭
Negative Gain Error
The Negative Gain Error is the deviation first code transition (0x800h) to (0xFFFh) in 2’s complement output coding
from the ideal input voltage (VIN+ - VIN- = -VREF + 0.5LSB @ Range=1 and -VREF/2 + 0.5LSB @ Range=0) in Fully
Differential Mode.
⎧ VINP – VINN
VREF
⎩
⎫
Negative Gain Error = ⎨ ----------------------------------- × 4096 + 2048 – AVG ( MeasuredCodes ) ⎬ – ZeroCodeError
⎭
Positive / Negative Gain Error Match
The Positive / Negative Gain Error Match defines the maximum deviation of the Positive / Negative Gain Errors across
all 6 channels of VIN in Fully Differential Mode (2’s complement output coding).
Signal-to-Noise Plus Distortion (SINAD)
The Signal to Noise Plus Distortion Ratio defines the ratio between the RMS value of the fundamental (input signal)
and the equivalent RMS value of all other spectral components below one-half the sampling frequency, including
harmonics but excluding DC. SINAD will be equal to SNR in an distortion free ADC.
Effective Number of Bits (ENOB)
The Effective Number of Bits indicates the actual resolution of the converter. The ENOB can be calculated from the
Signal to Noise Plus Distortion Ratio (SINAD).
SINAD – 1,76
6,02
ENOB = ----------------------------------
Signal-to-Noise Ratio (SNR)
The Signal to Noise Ratio defines the ratio between the RMS value of the fundamental (input signal) to the RMS value
of the sum of all other spectral components below one-half of the sampling frequency, excluding harmonics and DC.
The theoretical SNR for an ideal N bit ADC is limited by the quantization error and is described by the formula:
SNR = 6.02*N +1.76 (dB)
Therefore, for a 12-bit ADC, the maximum SNR is 74dB.
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Datasheet - Te r m i n o l o g y
Total Harmonic Distortion (THD)
The Total Harmonic Distortion is the ratio between the RMS value of the fundamental (input signal) to the RMS value of
the first five harmonics.
2
2
2
2
V2 + V3 + V4 + V5 + V6
V1
2
THD(dBc) = 20*log -----------------------------------------------------------------------Where:
V1 is the RMS power of the input frequency (fundamental)
V2 to V6 are the RMS values of the first five harmonics
Spurious Free Dynamic Range (SFDR)
The Spurious Free Dynamic Range defines the ratio between the RMS value of the fundamental to the RMS value of
the largest peak off all spectral components below one-half of the sampling frequency, including harmonics but
excluding DC.
Channel to Channel Isolation
The Channel to Channel Isolation (Crosstalk) defines the coupling of energy from one channel into the other channel in
the ADC. It is measured by applying a 40kHz sine wave to all unselected channels and the attenuation to a 50kHz
input sine wave is determined.
Intermodulation Distortion (IMD)
The Intermodulation Distortion measures the creations of additional spectral components that are caused by
nonlinearities when applying a two tone sine wave on the input of the ADC. IMD is the ration of the RMS power in
either the second or the third intermodulation products to the sum of both input frequencies.
nd
2
order intermodulation products (IM2): f1+f2, f2-f1
rd
3 order intermodulation products (IM3): 2*f1-f2, 2*f2-f1, 2*f1+f2, 2*f2+f1
Full Power Bandwidth / Full Linear Bandwidth
The Full Power Bandwidth defines the frequency at which the reconstructed input signal amplitude drops 3dB from the
actual amplitude of the input signal, when applying a full scale signal.
The Full Linear Bandwidth defines the frequency at which the reconstructed input signal amplitude drops 0.1dB from
the actual amplitude of the input signal, when applying a full scale signal.
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AS1545
Datasheet - D e t a i l e d D e s c r i p t i o n
9 Detailed Description
The AS1545 is a dual, 6-channel (six single-ended, three pseudo-differential or three fully-differential for each
multiplexer), 12-bit, 1 MSPS, high speed, successive approximation (SAR) analog-to-digital converter (ADC). The
AS1545 is designed to operate with a single +2.7V to +5.25V supply and a sampling rate of up to 1 MSPS. The serial
interface provides easy interfacing to microprocessors.
The AS1545 feature two on-chip, differential track-and-hold amplifiers, two successive approximation ADCs, and a
serial interface with two separate data output pins on a single die. The AS1545 is available in a 32-lead TQFN
package, offering the user considerable space-saving advantage.
The AS1545 can convert analog input signals in the range [0V to VREFIN] or [0V to 2 x VREFIN] in single-ended or
pseudo-differential mode or [-VREFIN/2 to +VREFIN/2] or [-VREFIN to +VREFIN] in fully differential mode. The AS1545 has
an on-chip 2.5V reference that can be overdriven when an external reference is preferred. If the internal reference is to
be used then the output needs to be buffered first. The AS1545 also features power-down options to allow power
saving between conversions. The power-down feature is implemented via the standard serial interface.
Analog Input
The AS1545 consists of successive approximation ADCs, each around two capacitive DACs and 12 analog inputs.
Each on-board ADC has six analog inputs that can be configured as six single-ended channels, three pseudo
differential channels, or three fully differential channels. Figure 32 and Figure 33 shows one of these ADCs in
acquisition and conversion phase, respectively. The ADC consists of a control logic, a SAR, and two capacitive DACs.
Figure 32. ADC Acquisition
CH0
CH1
CH2
CH3
CH4
CH5
CAPACITIVE
DAC
B
AIN+
COMPARATOR
CS RIN
+
A SW1 11pF
CONTROL
LOGIC
SW3
A
CS
SW2
AIN-
RIN
-
11pF
B
Analog Input
Multiplexer
CAPACITIVE
DAC
CSWITCH includes all parasitics
VREF
Acquisition Time
During data acquisition time (tACQ) SW3 is closed, SW1 and SW2 are in track position, the comparator is held in a
balanced condition, and the sampling capacitor arrays acquire the differential signal on the input. At the raising edge of
the CSN signal, SW3 opens and SW1 and SW2 go into hold position, causing the comparator to become unbalanced.
Both inputs are disconnected once the conversion begins. The control logic and the charge redistribution DACs are
used to add and subtract fixed amounts of charge from the sampling capacitor arrays to bring the comparator back into
a balanced condition. When the comparator is rebalanced, the conversion is complete. The control logic generates the
ADC output code. The output impedances of the sources driving the AIN+ and AIN- pins must be matched. Otherwise,
the two inputs will have different settling times, resulting in errors.
Figure 33. ADC Conversion Phase
CH0
CH1
CH2
CH3
CH4
CH5
CAPACITIVE
DAC
B
AIN+
COMPARATOR
CS RIN
+
A SW1 11pF
CONTROL
LOGIC
SW3
A
SW2
AIN-
CS RIN
-
11pF
B
Analog Input
Multiplexer
CAPACITIVE
DAC
VREF
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CSWITCH includes all parasitics
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AS1545
Datasheet - D e t a i l e d D e s c r i p t i o n
Figure 34. Typical Application
10µF
10µF
1µF
1µF
100nF
AVDD
+
100nF
DVDD
DOUTA
SCLK
CSN
RANGE
SGL/DIFF
DOUTB
VDRIVE
AIN 0
10nF
10Ω
AIN 1
-
+
10Ω
10nF
10Ω
BIN 0
10nF
BIN 1
10Ω
10nF
µC
AS1545
REFB
REFA
REFSEL
1µF
100nF
4.7µF
4.7µF
A0 A1 A2
Analog Input Composition
The equivalent circuit of analog input structure of the AS1545 in differential/pseudo differential modes is shown in the
Figure 35. In single-ended mode, AIN- is internally tied to AGND. The four diodes provide ESD protection for the
analog inputs. These diodes can conduct up to 10mA without causing irreversible damage to the part.
Note: Make sure that the analog input signals never exceed the supply rails by more than 300mV. This causes the
diodes to become forward-biased and starts conducting into the substrate.
The C1 capacitors in Figure 35 are of 4pF and can be attributed to pin capacitance. The value of these resistors is
typically about 100Ω. The C2 capacitors are the ADC’s sampling capacitors with a capacitance of 20pF typically.
For ac applications, removing high frequency components from the analog input signal is recommended by the use of
an RC low-pass filter on the relevant analog input pins with optimum values of 10Ω and 10nF. In applications where
harmonic distortion and signal-to-noise ratio are critical, the analog input should be driven from a low impedance
source. Large source impedances significantly affect the ac performance of the ADC and may necessitate the use of
an input buffer amplifier. The choice of the op amp is a function of the particular application.
Figure 35. Equivalent Analog Input Circuit
VDD
VDD
D
R1
D
C2
R1
C2
AIN-
AIN+
C1
4pF
C1
D
Open for conversion,
closed for tracking.
4pF
D
Open for conversion,
closed for tracking.
When no amplifier is used to drive the analog input, the source impedance should be limited to low values. The
maximum source impedance depends on the amount of THD that can be tolerated. The THD increases as the source
impedance increases and performance degrades.
Figure 23 on page 13 shows a graph of the THD vs. the analog input signal frequency for various supplies in singleended mode, while Figure 25 shows the THD vs. the analog input signal frequency for various supplies in differential
mode.
Figure 22 on page 13 shows a graph of the THD vs. the analog input frequency for different source impedances.
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Datasheet - D e t a i l e d D e s c r i p t i o n
Analog Input Modes
Table 5. Address Map
Address Map
SGL/
DIFF
A2
A1
A0
1
0
0
1
0
1
ADC A
ADC B
Comments
AIN+
AIN-
BIN+
BIN-
0
AIN0
GND
BIN0
GND
Single Ended
0
1
AIN1
GND
BIN1
GND
Single Ended
0
1
0
AIN2
GND
BIN2
GND
Single Ended
1
0
1
1
AIN3
GND
BIN3
GND
Single Ended
1
1
0
0
AIN4
GND
BIN4
GND
Single Ended
1
1
0
1
AIN5
GND
BIN5
GND
Single Ended
0
0
0
0
AIN0
AIN1
BIN0
BIN1
Fully Differential
0
0
0
1
AIN0
AIN1
BIN0
BIN1
Pseudo Differential
0
0
1
0
AIN2
AIN3
BIN2
BIN3
Fully Differential
0
0
1
1
AIN2
AIN3
BIN2
BIN3
Pseudo Differential
0
1
0
0
AIN4
AIN5
BIN4
BIN5
Fully Differential
0
1
0
1
AIN4
AIN5
BIN4
BIN5
Pseudo Differential
0
1
1
0
AIN0
AIN1
BIN0
BIN1
Pseudo Differential
Difference – A/B Phases –
Counter
Table 6. Input Range
SGL/DIFF
Range
Ain+ - AinRange
Coding
Example
1
0
0 to VREF
Straight
AIN+ - AIN- = 1.766 V
Output Decimal = 2894
Output Binary = 1011 0100 1110
1
1
0 to 2VREF
Straight
AIN+ - AIN- = 1.766V
Output Decimal = 1447
Output Binary = 0101 1010 0111
0
0
0 to VREF
Straight
AIN+ - AIN- = 1.666 V
Output Decimal = 2703
Output Binary = 1010 1010 1010
0
1
0 to 2VREF
Straight
AIN+ - AIN- = 1.666 V
Output Decimal = 1365
Output Binary = 0101 0101 0101
0
0
-VREF/2 to +VREF/2
2’s comp
AIN+ - AIN- = 1.666 V
Output Decimal = 4095
Output Binary = 0111 1111 1111 (its 2’s comp)
0
1
-VREF to +VREF
2’s comp
AIN+ - AIN- = 1.666 V
Output Decimal= 3413
Output Binary= 0101 0101 0101 (its 2’s comp)
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AS1545
Datasheet - D e t a i l e d D e s c r i p t i o n
Single-Ended Mode
The AS1545 consists of 12 single-ended analog input channels with range that can be programmed to be either 0 to
VREF or 0 to 2 × VREF.
Note: In applications where the signal source has high impedance, it is recommended to buffer the analog input
before applying it to the ADC.
If the sampling analog input is bipolar, the internal reference of the ADC can be used to externally bias up this signal to
make it correctly formatted for the ADC. Figure 36 shows the connecting diagram when operating the ADC in singleended mode.
Figure 36. Single-Ended Mode Connection Diagram
+2.5V
+1.25V
0V
-1.25V
R
VIN
0V
R
AIN0 to BIN5
3R
10Ω
+
10nF
REFA/
REFB
R
+
4.7µF
-
Figure 37. Definition of Single-Ended Input
VIN
RANGE = 0
VIN
0 < AIN < VDD
RANGE = 1
0 < AIN < VDD
VREF
2VREF
t
t
Fully Differential Mode
The AS1545 consists of six differential analog input pairs. Figure 38 defines the fully differential analog input of the
AS1545. The amplitude of the differential signal is the difference between the signals applied to the AIN+ and AIN- pins
in each differential pair (AIN+ - AIN-). These pins should be simultaneously driven by two signals each of amplitude
VREF/2 (or VREF, depending on the range required) that are 180º out of phase. If RANGE = 1 is selected the amplitude
of the differential signal is ±VREF regardless of the common mode (CM).
The common mode is the average of the two signals and is therefore the voltage on which the two inputs are centered.
(VIN+ + VIN-)/2
(EQ 1)
Althought fully differential operation with phase between inputs of 180° is recommanded, non true differential signals
can also be applied.
Note: It is important to note that the absolute voltage of the analog inputs goes from AGND to VDD.
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AS1545
Datasheet - D e t a i l e d D e s c r i p t i o n
Figure 38. Definition of Fully Differential Input
RANGE = 0
VIN
AIN+
0 < VCM < VDD
0 < AIN-, AIN+ < VDD
RANGE = 1
VIN
AIN+
±VREF/2
VCM
0 < VCM < VDD
0 < AIN-, AIN+ < VDD
±VREF
VCM
AIN-
AINt
t
Pseudo Differential Mode
The AS1545 consists of six pseudo differential pairs. In pseudo differential mode, AIN+ is connected to the signal
source with an amplitude of VREF or 2 × VREF (depending on the range selected) to make use of the full dynamic range
of the part. A dc input is applied to the AIN- pin. The voltage applied to this input provides an offset from ground or a
pseudo ground for the AIN+ input. The benefit of pseudo differential inputs is that they separate the analog input signal
ground from the ADC’s ground allowing dc common-mode voltages to be cancelled. Figure 39 shows a connection
diagram for pseudo differential mode.
Figure 39. Pseudo Differential Mode Connection Diagram
+
VREF p-p
VIN+
AS1545
VIN-
REFA/
REFB
-
DC Input Voltage
4.7µF
Figure 40. Definition of Pseudo Differential Input
RANGE = 0
VIN
AIN- + VREF
0 < AIN-, AIN+ < VDD
RANGE = 1
VIN
AIN+
AIN- + 2VREF
2VREF
VREF
AIN-
AINt
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0 < AIN-, AIN+ < VDD
AIN+
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AS1545
Datasheet - D e t a i l e d D e s c r i p t i o n
Analog-to-Digital Conversion
The analog inputs of the AS1545 can be configured as single-ended pseudo-differential or fully differential via the SGL/
DIFF logic pin, as shown in Figure 41. If this pin is coupled to a logic low, the analog input channels to each on-chip
ADC are set up as three fully differential pairs or 3 pseudo-differential inputs. If this pin is at logic high, the analog input
channels to each on-chip ADC are set up as six single-ended analog inputs. The required logic level on this pin needs
to be established prior to the acquisition time and remain unchanged during the conversion time until the track-andhold has returned to track. The track-and-hold returns to track on the 13th rising edge of SCLK after the CSN falling
edge (see Figure 51). If the level on this pin is changed, it is recognized by the AS1545; therefore, keep the same logic
level during acquisition and conversion to avoid corrupting the conversion in progress.
The channels used for simultaneous conversions are selected via the multiplexer address input pins, A0 to A2. The
logic states of these pins also need to be established prior to the acquisition time; however, they may change during
the conversion time, provided that the mode is not changed. If the mode is changed from fully differential to pseudodifferential, for example, then the acquisition time would start again from this point. The selected input channels are
decoded as shown in Table 5 on page 20.
The analog input range of the AS1545 can be selected as [0V to VREF or -VREF/2 to +VREF/2] or [0V to 2×VREF or
-VREF to +VREF] via the RANGE and MODE pin (see Table 5 on page 20). This selection is made in a similar fashion to
that of the SGL/DIFF pin by setting the logic state of the RANGE pin a time tACQ prior to the falling edge of CSN. The
logic level on this pin can be altered after the third falling edge of SCLK. If this pin is tied to a logic low, the analog input
range selected is [0V to VREF or -VREF/2 to +VREF/2]. If this pin is tied to a logic high, the analog input range selected is
[0V to 2×VREF or -VREF to +VREF].
Figure 41. Selecting Differential or Singe-Ended Configuration
A
CSN
B
tACQ
1
SCLK
14
1
14
SGL/
DIFF
Output Coding
The AS1545 output coding is set to either twos complement or straight binary, depending on which analog input
configuration is selected for a conversion. Output coding scheme for each possible analog input configuration is show
in the Table 7.
Table 7. AS1545 Output Coding
MODE
Output Coding
Differential
Twos complement
Single-Ended
Straight binary
Pseudo-Differential
Straight binary
Transfer Functions
The designed code transitions occur at successive integer LSB values (1 LSB, 2 LSB, and so on). In single-ended
mode, the LSB size is VREF/4096 when the 0V to VREF range is used, and the LSB size is 2 × VREF/4096 when the 0V
to 2 × VREF range is used. In differential mode, the LSB size is 2 × VREF/4096 when the 0V to VREF. The ideal transfer
characteristic for the AS1545 when straight binary coding is output is shown (with the 2 × VREF range) in Figure 42 &
Figure 43 on page 24, and Figure 44 & Figure 45 on page 24 shows the twos complement.
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AS1545
Datasheet - D e t a i l e d D e s c r i p t i o n
Figure 42. Straight Binary Transfer Function for
Single-Ended, RANGE = 0
Full Scale = VREF
Zero Scale = 0
1LSB = VREF/4096
11...111
Figure 43. Straight Binary Transfer Function for
Single-Ended, RANGE = 1
Full Scale
(FS)
Transition
Full Scale = +2VREF
Zero Scale = 0
1LSB = VREF/4096
11...111
11....101
11....101
Output Code
11...110
Output Code
11...110
00...011
00...011
00...010
00...010
00...001
00...001
00...000
00...000
0
1
2
3
FS - 3/2LSB
0
1
Input Voltage VINx (LSB)
011....111
011....111
011...110
000...010
000...010
Output Code
011...110
000...001
000...000
FS - 3/2LSB
111...111
Full Scale = +VREF
Zero Scale = -VREF
1LSB = VREF/4096
000...001
000...000
111...111
111...110
111...110
111...101
111...101
100...001
100...001
100...000
100...000
ZS
3
Figure 45. Two’s Complement Transfer Function for
Differential, RANGE = 1
Full Scale = VREF/2
Zero Scale = -VREF/2
1LSB = VREF/4096
-FS
2
Input Voltage VINx - VINy (LSB)
Figure 44. Two’s Complement Transfer Function for
Differential, RANGE = 0
Output Code
Full Scale
(FS)
Transition
+FS - 1LSB
Input Voltage VINx (LSB)
-FS
ZS
+FS - 1LSB
Input Voltage VINx - VINy (LSB)
Digital Inputs
VDRIVE Functionality
The AS1545 also has a VDRIVE feature to control the voltage at which the serial interface operates and allows the ADC
to easily interface to both 3V and 5V processors. For example, if the AS1545 was operated with a VDD of 5V, the
VDRIVE pin could be powered from a 3V supply, allowing a large dynamic range with low voltage digital processors.
Therefore, the AS1545 could be used with the 2 × VREF input range, with a VDD of 5V while still being able to interface
to 3V digital parts.
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AS1545
Datasheet - A p p l i c a t i o n I n f o r m a t i o n
10 Application Information
Operation Modes
The operation mode of the AS1545 is selected by controlling the (logic) state of the CSN signal during a conversion
process. There are three possible modes of operation: Full Power-UP mode, Full Power-Down mode, and Partial
Power-Down mode. After a conversion is initiated, the point at which CSN is pulled high determines which power-down
mode, if any, the device enters. Similarly, in power-down mode, CSN can control whether the device returns to Full
Power-Up mode or remains in power-down. These modes of operation provides flexible power management and can
be selected to optimize the power dissipation/throughput rate ratio for differing application requirements.
Full Power-Up Mode
In this mode the AS1545 is fully powered all the time without any power-up time. This mode is suitable for applications
that need the fastest throughput rates. Figure 46 shows the general diagram of the operation of the AS1545 in this
mode. On the falling edge of CSN conversion is initiated. To ensure that the part remains fully powered up at all times,
CSN must remain low until at least 10 SCLK falling edges have elapsed after the falling edge of CSN. The conversion
is terminated and DOUTA and DOUTB go back into three-state, if CSN is brought high any time after the 10th SCLK
falling edge but before the 15th SCLK falling edge. During this process the part remains powered up.
Figure 46. Full Power-Up Mode Operation
CSN
1
10
15
SCLK
DOUTA
DOUTB
3 LEADING ZEROS + CONVERSION RESULT 12bits
Fiveteen serial clock cycles are required to complete the conversion and access the conversion result. The DOUT line
does not return to three-state after 15 SCLK cycles have elapsed, but instead does so when CSN is brought high
again. If CSN is left low for another SCLK cycle (for example, if only a 16 SCLK burst is available), one trailing zeros
are clocked out after the data. If CSN is left low for a further 16 SCLK cycles, the result from the other ADC on board is
also accessed on the same DOUT line, as shown in Figure 52 (see Serial Interface on page 28)
Once 32 SCLK cycles have elapsed, the DOUT line returns to three-state on the 32nd SCLK falling edge. If CSN is
brought high prior to this, the DOUT line returns to three-state at that point. Once a data transfer is complete and DOUTA
and DOUTB have returned to three-state, another conversion can be initiated after the quiet time, tQUIET, has elapsed
by bringing CSN low again (assuming the required acquisition time is allowed).
Full Power-Down Mode
This mode is intended for applications where throughput rates are slower. In this mode the AS1545 will stay power
down until the falling edge of CSN. The device continues to power-up when the CSN is held low till the falling edge of
the 10th SCLK.
When the AS1545 is in full power-down, all analog circuitry is powered down. Full power-down is entered in a similar
way as partial power-down, except the timing sequence shown in Figure 50 must be executed twice. The conversion
process must be interrupted in a similar fashion by bringing CSN high anywhere after the second falling edge of SCLK
and before the 10th falling edge of SCLK. The device enters partial power-down at this point. To reach full powerdown, the next conversion cycle must be interrupted in the same way, as shown in Figure 48. Once CSN is brought
high in this window of SCLKs, the part completely powers down.
Note: It is important to note, that the full power-down mode can only be established if both digital outputs, DOUTA and
DOUTB are not left floating. Therefore a pulldown or pullup of >1GΩ is required.
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AS1545
Datasheet - A p p l i c a t i o n I n f o r m a t i o n
Figure 47. Exiting Partial Power-Down Mode
The part is fully powered-up
The part begins to power-up
tpower-up1
CSN
1
SCLK
DOUTA
DOUTB
1
15
10
15
VALID DATA
INVALID DATA
Figure 48. Entering Full Power-Down Mode
The part enters fully powered down
The part enters partial power down
The part begins to power-up
CSN
SCLK
1
10
2
DOUTA
DOUTB
15
1 2
15
10
Three-State
Three-State
INVALID DATA
INVALID DATA
Figure 49. Exiting Full Power-Down Mode
The part is fully powered-up
The part begins to power-up
tpower-up1
CSN
SCLK
DOUTA
DOUTB
1
10
15
1
15
VALID DATA
INVALID DATA
Note: It is not necessary to complete the 15 SCLKs once CSN is brought high to enter a power-down mode.
The required power-up time must elapse before a conversion can be initiated, as shown in Figure 49.
Partial Power-Down Mode
This mode is intended for use in applications where slower throughput rates are required. Either the ADC is powered
down between each conversion, or a series of conversions may be performed at a high throughput rate, and the ADC
is then powered down for a relatively long duration between these bursts of several conversions. When the AS1545 is
in partial power-down, all analog circuitry is powered down except for the on-chip reference and reference buffer.
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AS1545
Datasheet - A p p l i c a t i o n I n f o r m a t i o n
To enter partial power-down mode, the conversion process must be interrupted by bringing CSN high anywhere after
the second falling edge of SCLK and before the 10th falling edge of SCLK, as shown in Figure 50. Once CSN is
brought high in this window of SCLKs, the part enters partial power-down, the conversion that was initiated by the
falling edge of CSN is terminated, and DOUTA and DOUTB go back into three-state. If CSN is brought high before the
second SCLK falling edge, the part remains in normal mode and does not power down. This avoids accidental powerdown due to glitches on the CSN line.
Figure 50. Partial Power-Down Mode
CSN
1
2
10
15
SCLK
DOUTA
DOUTB
THREE-STATE
To exit this mode of operation and power up the AS1545 again, a dummy conversion is performed. On the falling edge
of CSN, the device begins to power up and continues to power up as long as CSN is held low until after the falling edge
of the 10th SCLK. The device is fully powered up after approximately 1 µs has elapsed, and valid data results from the
next conversion, as shown in Figure 47. If CSN is brought high before the second falling edge of SCLK, the AS1545
again goes into partial power-down. This avoids accidental power-up due to glitches on the CSN line. Although the
device may begin to power up on the falling edge of CSN, it powers down again on the rising edge of CSN. If the
AS1545 is already in partial power-down mode and CSN is brought high between the second and 10th falling edges of
SCLK, the device enters full power-down mode.
Power-Up Times
As described in detail, the AS1545 has two power-down modes, partial power-down and full power-down. This section
deals with the power-up time required when coming out of either of these modes. It should be noted that the power-up
times, as explained in this section, apply with the recommended capacitors in place on the DCAPA and DCAPB pins.
The power-up time is always 1µs, independent of the mode currently in.
Note: It is important to note that, when using the internal reference, charging the external reference capacitance typically needs around 250µs but can take up to 1ms.
When power supplies are first applied to the AS1545, the ADC may power up in either of the power-down modes or
normal mode. Because of this, it is best to allow a dummy cycle to elapse to ensure the part is fully powered up before
attempting a valid conversion. Likewise, if it is intended to keep the part in the partial power-down mode immediately
after the supplies are applied, then two dummy cycles must be initiated. The first dummy cycle must hold CSN low until
after the 10th SCLK falling edge (see Figure 46); in the second cycle, CSN must be brought high before the 10th SCLK
edge but after the second SCLK falling edge (see Figure 50). Alternatively, if it is intended to place the part in full
power-down mode when the supplies are applied, then three dummy cycles must be initiated. The first dummy cycle
must hold CSN low until after the 10th SCLK falling edge (see Figure 46); the second and third dummy cycles place
the part in full power-down (see Figure 48).
Once supplies are applied to the AS1545, enough time must be allowed for any external reference to power up and
charge the various reference buffer decoupling capacitors to their final values.
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AS1545
Datasheet - A p p l i c a t i o n I n f o r m a t i o n
Power vs. Throughput Rate
The power consumption of the AS1545 varies with throughput rate. When using very slow throughput rates and as fast
an SCLK frequency as possible, the various power-down options can be used to make significant power savings.
However, the AS1545 quiescent current is low enough that even without using the power-down options, there is a
noticeable variation in power consumption with sampling rate. This is true whether a fixed SCLK value is used or if it is
scaled with the sampling rate. Figure 10 on page 11 shows plots of power vs. the throughput rate when operating in
normal mode for a fixed maximum SCLK frequency, and an SCLK frequency that scales with the sampling rate with
VDD = 3V and VDD = 5V, respectively. In all cases, the internal reference was used.
Serial Interface
The timing diagram for serial interfacing to the AS1545 is shown in Figure 51. The serial clock provides the conversion
clock and controls the transfer of information from the AS1545 during conversion.
The CSN signal initiates the data transfer and conversion process. The falling edge of CSN puts the track-and-hold
into hold mode, at which point the analog input is sampled and the bus is taken out of three-state. The conversion is
also initiated at this point and requires a minimum of 15 SCLKs to complete. Once 13 SCLK falling edges have
elapsed, the track-and-hold goes back into track on the next SCLK rising edge, as shown in Figure 51 at Point B. If a
16-SCLK transfer is used, then two trailing zeros will appear after the final LSB. On the rising edge of CSN, the
conversion is terminated and DOUTA and DOUTB go back into three-state. If CSN is not brought high but is instead held
low for a further 15 SCLK cycles on DOUTA, the data from Conversion B is output on DOUTA (followed by 1 trailing
zero).
Likewise, if CSN is held low for a further 15 SCLK cycles on DOUTB, the data from Conversion A is output on DOUTB.
This is illustrated in Figure 52 where the case for DOUTA is shown. In this case, the DOUT line in use goes back into
three-state on the 32nd SCLK falling edge or the rising edge of CSN, whichever occurs first.
A minimum of 15 serial clock cycles are required to perform the conversion process and to access data from one
conversion on either data line of the AS1545. CSN going low provides the 3 leading zeros to be read in by the
microcontroller or DSP. The remaining data is then clocked out by subsequent SCLK falling edges. Therefore, the first
falling clock edge on the serial clock has the leading zero provided and also clocks out the second leading zero. The
12-bit result then follows after a third leading zero with the final bit in the data transfer valid on the 15th falling edge,
having being clocked out on the previous (14th) falling edge. It may also be possible to read in data on each SCLK
rising edge depending on the SCLK frequency or the supply voltage. The secondrising edge of SCLK after the CSN
falling edge would have the third leading zero provided, and the 14th rising SCLK edge would have DB0 provided.
If a falling edge of SCLK is coincident with the falling edge of CSN, then this falling edge of SCLK is not acknowledged
by the AS1545, and the next falling edge of SCLK will be the first registered after the falling edge of CSN.
Figure 51. Timing Diagram
CSN
tCSPW
tCSS
SCLK
tCH
1
2
3
4
B
5
14
tCL
tDOH
tCSDOE
DOUTA
0
0
DB11
0
DOUTB THREESTATE
3 LEADING ZEROES
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tCSDOD
tDOV
DB10
DB9
Revision 1.01
DB2
DB1
DB0
tQUIET
THREE-STATE
28 - 34
AS1545
Datasheet - A p p l i c a t i o n I n f o r m a t i o n
Figure 52. Reading Data from Both ADCs on One DOUT Line with 32 SCLKs
CSN
tCSS
tCH
1
SCLK
2
3
tDOV
tCSDOE
DOUTA
THREESTATE
0
0
5
tCL
4
0
15
16
DB11A DB10A
0
0
1 TRAILING
ZERO
3 LEADING
ZEROES
32
tDOD
18
17
tDOH
0
0
DB11B
DB0B
0
THREESTATE
1 TRAILING ZERO
3 LEADING ZEROES
Figure 53. 32 SCLKs Data transfer for all modes in DOUTA, DOUTB
CSN
DOUTA
000
SDATA_A
0
00
0+SDATA_B
0
DOUTA*
000
SDATA_A
0
00
Counter + DIR + A + B
0
DOUTB
000
SDATA_A
0
00
DIF
0
16bit
16bit
* only applicable when SGL/DIFF = 0 ; Α2=1, Α1=1, Α0=0
Difference calculator and quadrature signals calculator
The AS1545 internally calculates the difference between the output codes of ADC A and ADC B. There are several
requirements that need to be taken into account in order to work with the difference calculator. First off, the output data
of both ADCs needs to be in straight binary coding. This means that the difference calculator will only give the correct
results in single ended and pseudo differential modes. Also, it is important to note that in order to read the data from
the difference calculator we must read all 32 bits of data of the ADC, therefore reducing the overall sampling rate of the
ADC by half.
The difference calculator will always give you a 13 bit two’s complement result. The first bit is the sign of the operation
and the next 12 bits are the data. For simplicity in the design, an systematic error of 1 LSB can be expected from the
difference calculator.
Below we have an detailed example describing the operation of the difference calculator.
Let’s assume that VINA = 1.667V VINB = 2V VREF = 2.5V and we are working in single ended mode.
DOUT_A = 1010 1010 1010 or 2730 in decimal
DOUT_B = 1100 1100 1100 or 3276 in decimal
The difference should be 2730-3276=-546 in decimal
In 2’s complement -546 is 1 1101 1101 1110 in binary. This is a 1 for the minus sign plus 4096-546=3550 in decimal
which corresponds to 1101 1101 1110 in binary
As stated before, there is a -1LSB error in the operation so the actual output should be -547 in decimal which
corresponds to 1 1101 1101 1101 in binary which is the result that the difference calculator clocks out.
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AS1545
Datasheet - A p p l i c a t i o n I n f o r m a t i o n
On top of the difference calculator, the ADC also provide us with information regarding input signals in quadrature (90
degrees phase difference) like the ones we would get from a position calculation system of a motor control.
In order for this mode to work, we must have SGL/DIFF=0, A2=1. A1=1. A0=0, according to what is specified in the
channel addresses table. Also, it is important to note that in order to read the data from the quadrature inputs
calculator we must read all 32 bits of data of the ADC, therefore reducing the overall sampling rate of the ADC by half.
The ADC provides us with the following information:
- Phase A and Phase B bits, dividing the period into four quadrants
- DIR bit, which indicates the direction of the rotation of the rotor
- Counter, this is a 10 bit word that, in the case of using a step down in the rotor indicates the number of times the
step down has spun. The counter increases twice per period if DIR is equal zero and decreases twice per period if
DIR equals one.
Figure 54. A to B phase
Code 4095
Cos
Sinus
Code 2048
Code 0
Direction = 0
Phase A
Phase B
Direction = 1
Direction of the rotor based on the DIR bit
If the rotor is rotating as the above picture, the direction bit is low.
If the rotor is rotating in the opposite direction to the above picture, the direction bit is high.
Note: This mode works only for SGL/DIFF=0, A2=1. A1=1. A0=0.
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AS1545
Datasheet - A p p l i c a t i o n H i n t s
11 Application Hints
Grounding and Layout
The analog and digital supplies to the AS1545 are independent and separately pinned out to minimize coupling
between the analog and digital sections of the device. The printed circuit board (PCB) that houses the AS1545 should
be designed so that the analog and digital sections are separated and confined to certain areas of the board. This
design facilitates the use of ground planes that can be easily separated.
To provide optimum shielding for ground planes, a minimum etch technique is generally best. All three AGND pins of
the AS1545 should be sunk in the AGND plane. Digital and analog ground planes should be joined in only one place. If
the AS1545 is in a system where multiple devices require an AGND to DGND connection, the connection should still
be made at one point only, a star ground point that should be established as close as possible to the ground pins on
the AS1545.
Avoid running digital lines under the device as this couples noise onto the die. However, the analog ground plane
should be allowed to run under the AS1545 to avoid noise coupling. The power supply lines to the AS1545 should use
as large a trace as possible to provide low impedance paths and reduce the effects of glitches on the power supply
line.
To avoid radiating noise to other sections of the board, fast switching signals, such as clocks, should be shielded with
digital ground, and clock signals should never run near the analog inputs. Avoid crossover of digital and analog
signals. To reduce the effects of feedthrough within the board, traces on opposite sides of the board should run at right
angles to each other. A microstrip technique is the best method but is not always possible with a double-sided board.
In this technique, the component side of the board is dedicated to ground planes, while signals are placed on the
solder side.
Good decoupling is also important. All analog supplies should be decoupled with 10 µF ceramic capacitors in parallel
with 0.1 µF capacitors to GND. To achieve the best results from these decoupling components, they must be placed as
close as possible to the device, ideally right up against the device. The 0.1 µF capacitors should have low effective
series resistance (ESR) and effective series inductance (ESI), such as the common ceramic types or surface-mount
types. These low ESR and ESI capacitors provide a low impedance path to ground at high frequencies to handle
transient currents due to internal logic switching.
PCB Design Guidelines for TQFN
The lands on the TQFNpackage are rectangular. The PCB pad for these should be 0.1 mm longer than the package
land length, and 0.05 mm wider than the package land width, thereby having a portion of the pad exposed. To ensure
that the solder joint size is maximized, the land should be centered on the pad.
The bottom of the chip scale package has a thermal pad. The thermal pad on the PCB should be at least as large as
the exposed pad. On the PCB, there should be a clearance of at least 0.25 mm between the thermal pad and the inner
edges of the pad pattern to ensure that shorting is avoided.
To improve thermal performance of the package, use thermal via on the PCB incorporating them in the thermal pad at
1.2 mm pitch grid. The via diameter should be between 0.3 mm and 0.33 mm, and the via barrel should be plated with
1 oz. copper to plug the via. The user should connect the PCB thermal pad to AGND.
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AS1545
Datasheet - P a c k a g e D r a w i n g s a n d M a r k i n g s
12 Package Drawings and Markings
-A-
Figure 55. 32-lead TQFN Package
D
INDEX AREA
D2
D2/2
D/2
-B-
aaa C 2x
-B-
E2
E
e
E2/2
E/2
(D/2 xE/2)
SEE
DETAIL B
N N-1
aaa C 2x
TOP VIEW
-A-
bbb
ddd
C A B
C
BTM VIEW
A
SEATING
PLANE
-C-
Terminal Tip
SIDE VIEW
A3
e/2
SEE
DETAIL B
A1
0.08 C
e
b
ccc C
L1
Datum A or B
INDEX AREA
(D/2 xE/2)
EVEN TERMINAL SIDE
Table 8. 32-lead TQFN Package Dimensions
Symbol
Min
Nom
Max
Note
Symbol
Min
Nom
Max
Note
A
0.70
0.75
0.80
1,2
b
0.18
0.25
0.30
1,2,5
A1
0.00
0.02
0.05
1,2
L
0.30
0.40
0.50
L1
0.03
0.15
1,2
N
32
1,2,5
K
0.20
1,2
ND
8
1,2,5
NE
8
1,2,5
e
0.5
1,2,5
D2
3.30
3.45
3.55
1,2,5
aaa
0.10
1,2
E2
3.30
3.45
3.55
1,2,5
bbb
0.10
1,2
D BSC
5.00
1,2,5
ccc
0.10
1,2
E BSC
5.00
1,2,5
ddd
0.05
1,2
Notes:
1. Figure 55 is shown for illustration only.
2. All dimensions are in millimeters; angles in degrees.
3. Dimensioning and tolerancing conform to ASME Y14.5 M-1994.
4. N is the total number of terminals.
5. The terminal #1 identifier and terminal numbering convention shall conform to JEDEC 95-1, SPP-012. Details of terminal #1 identifier are optional, but must be located within the zone indicated. The terminal #1 identifier may be either
a mold or marked feature.
6. Dimension b applies to metallized terminal and is measured between 0.15mm and 0.30mm from the terminal tip.
7. ND refers to the maximum number of terminals on side D.
8. Unilateral coplanarity zone applies to the exposed heat sink slug as well as the terminals
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AS1545
Datasheet - O r d e r i n g I n f o r m a t i o n
13 Ordering Information
The device is available as the standard products shown in Table 9.
Table 9. Ordering Information
Ordering Code
Description
Marking
Delivery Form
Package
AS1545-BQFT
Dual, 12-Bit, 1MSPS, SAR ADC
AS1545
T&R
32-lead TQFN
Note: All products are RoHS compliant and Pb-free.
Buy our products or get free samples online at ICdirect: http://www.austriamicrosystems.com/ICdirect
For further information and requests, please contact us mailto:[email protected]
or find your local distributor at http://www.austriamicrosystems.com/distributor
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AS1545
Datasheet
Copyrights
Copyright © 1997-2009, austriamicrosystems AG, Tobelbaderstrasse 30, 8141 Unterpremstaetten, Austria-Europe.
Trademarks Registered ®. All rights reserved. The material herein may not be reproduced, adapted, merged,
translated, stored, or used without the prior written consent of the copyright owner.
All products and companies mentioned are trademarks or registered trademarks of their respective companies.
Disclaimer
Devices sold by austriamicrosystems AG are covered by the warranty and patent indemnification provisions appearing
in its Term of Sale. austriamicrosystems AG makes no warranty, express, statutory, implied, or by description regarding
the information set forth herein or regarding the freedom of the described devices from patent infringement.
austriamicrosystems AG reserves the right to change specifications and prices at any time and without notice.
Therefore, prior to designing this product into a system, it is necessary to check with austriamicrosystems AG for
current information. This product is intended for use in normal commercial applications. Applications requiring
extended temperature range, unusual environmental requirements, or high reliability applications, such as military,
medical life-support or life-sustaining equipment are specifically not recommended without additional processing by
austriamicrosystems AG for each application. For shipments of less than 100 parts the manufacturing flow might show
deviations from the standard production flow, such as test flow or test location.
The information furnished here by austriamicrosystems AG is believed to be correct and accurate. However,
austriamicrosystems AG shall not be liable to recipient or any third party for any damages, including but not limited to
personal injury, property damage, loss of profits, loss of use, interruption of business or indirect, special, incidental or
consequential damages, of any kind, in connection with or arising out of the furnishing, performance or use of the
technical data herein. No obligation or liability to recipient or any third party shall arise or flow out of
austriamicrosystems AG rendering of technical or other services.
Contact Information
Headquarters
austriamicrosystems AG
Tobelbaderstrasse 30
A-8141 Unterpremstaetten, Austria
Tel: +43 (0) 3136 500 0
Fax: +43 (0) 3136 525 01
For Sales Offices, Distributors and Representatives, please visit:
http://www.austriamicrosystems.com/contact
www.austriamicrosystems.com
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