TSM1285
Page 1
© 2014 Silicon Laboratories, Inc. All rights reserved.
FEATURES
Alternate Source for MAX1285 and higher-speed
upgrade to MAX1240 and MAX1241
Single-Supply Operation: +2.7V to +3.6V
DNL & INL: ±1LSB (max)
300ksps Sampling Rate
Low Conversion-Mode Supply Current:
2.5mA @ 300ksps
Low Supply Current in Shutdown: 2µA
Internal Track-and-Hold
Internal +2.5V Reference
SPI
®
/QSPI™/MICROWIRE™ 3-Wire Serial-
Interface
1
8-Pin SOIC Package
APPLICATIONS
Process Control and Factory Automation
Data and Low-frequency Signal Acq uisition
Portable Data Logging
Pen Digitizers & Tablet Computers
Medical Instrumentation
Battery-powered Instruments
1
SPI and QSPI are trademarks of Motorola, Inc.
MICROWIRE is a trademark of National
Semiconductor Corporation.
DESCRIPTION
The TSM1285 – a single-supply, single-channel, 12-
bit analog-to-digital converter (ADC) - is an alternate
source for the MAX1285 and a higher-speed upgrade
to the MAX1240 and MAX1240 ADCs. The TSM1285
combines a high-bandwidth track-and-hold (T/H), a
high-speed serial digital interface, an internal +2.5V
reference, and low conversion-mode power
consumption. The TSM1285 operates from a single
+2.7V to+3.6V supply and draws less than 2.5mA at
300ksps.
Connecting directly to any SPI, QSPI, M IC R OWIR E™
microcontrollers and other interface-compatible
computing devices, the TSM1285’s 3-wire serial
interface is easy to use and doesn’t require separate,
external logic. An external serial-interface clock
controls the TSM1285’s conversion process and its
output shift register operation.
In PCB-space-conscious, low-power remote-sensor
and data-acquisition applications, the TSM1285 is an
excellent choice for its low-power, ease-of-use, and
small-package-footprint attributes.
The TSM1285BC is fully specified over the
0°C to +70°C temperature range. TSM1285BE is fully
specified over the -40°C to +85°C temperature range.
Both products are availabl e in a 8-pin SOIC package.
A 300ksps, Single-supply, Low-Power 12-Bit Serial-output ADC
FUNCTIONAL BLOCK DIAGRAM
TSM1285
Page 2 TSM1285 Rev. 1.0
ABSOLUTE MAXIMUM RATINGS
V
DD
to GND.................................................................... -0.3V to +6V
AIN to GND ...................................................... -0.3V to (V
DD
+ 0.3V)
REF to GND ..................................................... -0.3V to (V
DD
+ 0.3V)
Digital Inputs to GND ....................................... -0.3V to (V
DD
+ 0.3V)
DOUT to GND .................................................. -0.3V to (V
DD
+ 0.3V)
DOUT Current ........................................................................ ±25mA
Continuous Power Dissipation (T
A
= +70°C):
8-Pin SOIC (Derate 5.88mW/°C above +70°C) .............. 471mW
Operating Temperature Ranges:
TSM1285BC ........................................................... 0°C to +70°C
TSM1285BE ....................................................... -40°C to +85°C
Storage Temperature Range .................................. -60°C to +150°C
Lead Temperature (Soldering, 10s ) ....................................... +300°C
Soldering Temperature (Reflow) ........................................... +260°C
Electrical and thermal stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These
are stress ratings only and functional operation of the device at these or any other condition beyond those indicated in the operational sections
of the specifications is not implied. Exposure to any absolute maximum rating conditions for extended periods may affect device reliability and
lifetime.
PACKAGE/ORDERING INFORMATION
ORDER NUMBER PART MARKING TEMPERATURE
RANGE CARRIER QUANTITY
TSM1285BCSA+ T1285B 0ºC to 70ºC Tube 97
TSM1285BCSA+T Tape
& Reel 2500
TSM1285BESA+ T1285BE -40ºC to +85ºC Tube 97
TSM1285BESA+T Tape
& Reel 2500
Lead-free Program: Silicon Labs supplies only lead-free packagi ng.
Consult Silicon Labs for products specified with wider operating temperature ranges.
TSM1285
TSM1285 Rev. 1.0 Page 3
ELECTRICAL SPECIFICATIONS
VDD = +2.7V to +3.6V; fSCLK = 4.8MHz, 50% duty cycle, 16 clocks/conversion cycle, 300ksps; 4.7μF capacit or at
REF; TA = -40ºC to +85ºC, unless otherwise noted. T y pical values apply at TA = +25°C.
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
DC ACCURACY (See Note 1)
Resolution 12 Bits
Relative Accuracy INL See Note 2 ±1.0 LSB
Differential Nonlinearity DNL No missing codes over temperature ±1.0 LSB
Offset Error ZE ±6.0 LSB
Gain Error GE See Note 3 ±6.0 LSB
Gain-Error Temperature Coefficient TCGE ±1.6 ppm/°C
DYNAMIC SPECIFICATIONS (fIN = 75kHz sine wave, 2.5VPP, fSAMPLE = 300ksps, fSCLK = 4.8MHz)
Signal-to-Noise
Plus Distortion Ratio SINAD 70 dB
Total Harmonic Distortion THD Including the 5th harmonic -80 dB
Spurious-Free Dynamic Range SFDR 80 dB
Intermodulation Distortion IMD f
A
= 73kHz, fB = 77kHz 76 dB
Full-Power Bandwidth FPBW -3dB point 3 MHz
Full-Linear Bandwidth FLBW SINAD > 68dB 250 kHz
CONVERSION RATE
Conversion Time tCONV See Note 4 3.3 μs
Track/Hold Acquisition Time t
A
CQ 625 ns
Aperture Delay t
A
D 10 ns
Aperture Jitter t
A
J < 50 ps
Serial Clock Frequency tSCLK 0.5 4.8 MHz
Duty Cycle 40 60 %
ANALOG INPUT (AIN)
Input Voltage Range VIN 0 2.5 V
Input Capacitance CIN
A
10 pF
INTERNAL REFERENCE
REF Output Voltage VREF 2.48 2.50 2.52 V
REF Short-Circuit Current T
A
= +25°C 15 mA
REF Output Tempco TCVREF ±15 ppm/°C
Load Regulation See Note 5; 0 to 0.75mA output load 0.1 2.0 mV/mA
Capacitive Bypass at REF 4.7 10 μF
DIGITAL INPUTS (SCLK, CS, SHDN)
Input High Voltage VINH 2.0 V
Input Low Voltage VINL 0.8 V
Input Hysteresis VHYST 0.2 V
Input Leakage IIN V
INL = 0V or VINH = VDD ±1 μA
Input Capacitance CIND 15 pF
DIGITAL OUTP UT (DOU T)
Output Voltage Low VOL I
SINK = 5mA 0.4 V
Output Voltage High VOH I
SOURCE = 0.5mA VDD - 0.5 V
Three-State Leakage Current IL VCS = +3V ±10 μA
Three-State Output Capacitance COUT VCS = +3V 15 pF
POWER SUPPLY
Positive Supply Voltage VDD See Note 6 2.7 3.6 V
Positive Supply Current IDD See Note 7; VDD = +3.6V 2.5 3.5 mA
Shutdown Supply Current ISHDN SCLK = VDD, SHDN = GND 2 10 μA
Power-Supply Rejection PSR VDD = +2.7V to 3.6V, midscale input ±0.5 mV
TSM1285
Page 4 TSM1285 Rev. 1.0
TIMING SPECIFICATIONS
VDD = +2.7V to +3.6V, TA = -40ºC to +85ºC, unless otherwise noted.
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
SCLK Period tCP 208 ns
SCLK Pulse-Width High tCH 83 ns
SCLK Pulse-Width Low tCL 83 ns
CS Fall to SCLK Rise Setup tCSS 45
ns
SCLK Rise to CS Rise Hold tCSH 0
ns
SCLK Rise to CS Fall Ignore tCSO 45
ns
CS Rise to SCLK Rise Ignore tCS1 45
ns
SCLK Rise to DOUT Hold tDOH C
LOAD = 20pF 13 ns
SCLK Rise to DOUT Valid tDOV C
LOAD = 20pF 100 ns
CS Rise to DOUT Disable tDOD C
LOAD = 20pF; Refer to Figure 2 13 85
ns
CS Fall to DOUT Enable tDOE C
LOAD = 20pF; Refer to Figure 1
85 ns
CS Pulse-Width High tCSW 100
ns
Note 1: Tested at VDD = VDD(MIN).
Note 2: Relative accuracy is the deviation of the analog value at any code from its theoretical value after the full-scale range has been
calibrated.
Note 3: Internal reference, offset, and reference errors nulled.
Note 4: Conversion time is defined as the number of clock cycles multiplied by the clock period; clock has 50% duty cycle.
Note 5: External load should not change during conversion for specified accuracy. Guaranteed specification limit of 2mV/mA because of
production test limitations.
Note 6: Electrical characteristics are guaranteed from VDD(MIN) to VDD(MAX). For operations beyond this range, see Typical Operating
Characteristics.
Note 7: TSM1285 tested with 20pF on DOUT and fSCLK = 4.8MHz, 0 to 3V. DOUT = full scale.
TSM1285
TSM1285 Rev. 1.0 Page 5
TYPICAL PERFORMANCE CHARACTERISTICS
V
DD
= +3V
;
f
SCLK
= 4.8MHz
;
C
LOAD
= 20
p
F
;
4.7
F ca
acitor at REF
T
A
= 25ºC
,
unless otherwise noted.
Integral Nonlinearity
INL - LSB
DIGITAL OUTPUT CODE
-0.4
-0.3
-0.2
-0.1
0
0.1
1k 2k
0 3k
Offset Error vs Supply Voltage
POWER SUPPLY VOLTAGE - Volt
OFFSET ERROR - LSB
-0.2
-0.8
-1.4
-1.8 2.7 3.06 3.24 3.42 2.88
TEMPERATURE - ºC
-15 35 60 85 10
-0.5
-1
-2
-1.5
1.2
0.8
0.6
-0.2
0.2
Differential Nonlinearit y
DNL - LSB
DIGITAL OUTPUT CODE
4k 5k 1k 2k
0 3k 4k 5k
0.2
0.3
0.4
-0.25
-0.2
-0.15
-0.1
0
0.2
0.25
-0.05
0.05
0.2
0.15
3.6
OFFSET ERROR - LSB
Offset Error vs Temperature
-40
1
0.5
0
0.6
0.4
0.2
-0.2
0
Gain Error vs Supply Voltage
POWER SUPPLY VOLTAGE - Volt
GAIN ERROR - LSB
Gain Error vs Temperature
TEMPERATURE - ºC
-15 35 60 85 10
GAIN ERROR - LSB
-40
-0.4
-0.6
-1
-1.2
-1.6
2.7 3.06 3.24 3.42 2.88 3.6
1.2
1
0.8
1
0.4
0
-0.4
TSM1285
Page 6 TSM1285 Rev. 1.0
Internal Reference Output vs Supply Voltage
REFERENCE OUTPUT - V
Power Supply Current vs Power Supply Voltage Power Supply Current vs Temperature
SUPPLY CURENT - mA
2.494
2.496
2.498
2.5
2.502
2.506
1.4
1.2
1
0.5
TYPICAL PERFORMANCE CHARACTERISTICS
V
DD
= +3V
;
f
SCLK
= 4.8MHz
;
C
LOAD
= 20
p
F
;
4.7
F ca
acitor at REF
T
A
= 25ºC
,
unless otherwise noted.
POWER SUPPLY VOLTAGE - Volt TEMPERATURE - ºC
-15 35 60 85 10
-40
POWER SUPPLY VOLTAGE - Volt
2.7 3.06 3.24 3.42
2.88 3.6
TEMPERATURE - ºC
-15 35 60 85 10
-40
0.8
0.6
CODE = 1111 1111 1111
R
LOAD
=
C
LOAD
= 10pF
CONVERTING
SCLK = 4.8MHz
STATIC
1.2
1.1
0.9
0.5
0.8
0.6
SUPPLY CURENT - mA
STATIC, V
DD
= 3V
CONVERTING, V
DD
= 3V
2.504
Internal Reference Output vs Temperature
REFERENCE OUTPUT - V
2.498
2.5
2.502
2.504
2.506
2.510
2.508
2.7 3.06 3.24 3.42
2.88 3.6
1.3
1.1
0.7
0.9
1
0.7
TSM1285
TSM1285 Rev. 1.0 Page 7
PIN FUNCTIONS
PIN NAME FUNCTION
1 VDD Power Supply Voltage, +2.7V to +3.6V.
2 AIN Analog Signal Input; Unipolar, 0 to VREF input rang e.
3 SHDN Active-Low Shutdown Input. Toggling SHDN high-to-low powers down the TSM1285 and
reduces the supply current to 2μA (typ).
4 REF
Reference Voltage for Analog-to-Digital Conversion – an internal 2.5V reference output. Bypass
with a good-quality 4.7μF capacitor.
5 GND
Analog and Digital Ground. Connect the TSM1285’s GND pin at one and only one point to the
system analog ground plane.
6 DOUT
Serial-Data Output. DOUT toggles state on SCLK’s rising edge and is high impedance when CS
is logic high.
7 CS Active-Low Chip Select. The CS signal initiates the conversion process on its falling edge. When
the CS input is logic high, DOUT is high impedance.
8 SCLK
Serial-Clock Input. The SCLK signal controls the conversion process and transfers output data
at rates up to 4.8MHz.
Figure 1: Output Loading Circuits for DOUT Ena ble Time (t
DOE
).
Figure 2: Output Loading Circuits for DOUT Disable Time (t
DOD
).
TSM1285
Page 8 TSM1285 Rev. 1.0
DESCRIPTION OF OPERATION
Converter Operation
The TSM1285 uses an input track-and-hold (T/H ) and
a successive-approximation register (SAR) circuitry to
convert an analog input signal to a digital 12-bit
output. No external-hold capacitor is needed for the
track/hold circuit. Figure 3 illustrates the TSM1285 in
its simplest configuration. The TSM1285 converts
input signals within the 0V to V
REF
range in 3.3μs
including the track-and-hold’s acquisition time. The
serial interface requires only three digital lines (SCLK,
CS, and DOUT) and provides an easy interface to
microprocessors (μPs) and microcontrollers (μCs).
The TSM1285 has two operating modes: normal and
shutdown. Toggling (or driving) the SHDN pin low
shuts down the ADCs and reduces supply current
below 1 μA when V
DD
3.6V. Open-circuiting or
toggling (or driving) the SHDN pin high or places the
ADCs into operational mode. Toggling the CS pin to
logic low initiates a conversion where the conversion
result is available at DOUT in unipolar serial format.
The serial data stream consists of three leading zeros
followed by the data bits with the MSB first. All
transitions on the DOUT pin occur within 20ns after
the low-to-high transition of SCLK. Serial interface
timing details of the TSM1285 are illustrated in
Figures 8 and 9.
Analog Input
Figure 4 illustrates the sampling architecture of the
analog-to-digital converter’s comparator. The full-
scale input voltage is set by the TSM1285’s internal
2.5-V reference.
Track-and-Hold Operation
During track mode, the analog signal is acquired and
stored on the internal hold capacitor. During hold
mode, the track/hold switches SW1 and SW2 are
opened thereby maintaining a constant input level to
the converter’s SAR subcircuit.
During the acquisition phase with SW1 and SW2 on
TRACK, the input capacitor, C
HOLD
, is charged to the
analog input (AIN). Toggling the CS pin low causes
the acquisition process to stop. At this instant,
track/hold switches SW1 and SW2 are moved to
HOLD position and the input side of C
HOLD
is then
switched to GND. Unbalancing Node ZERO at the
comparator’s input, the retained charge on C
HOLD
represents a sample of the input signal applied to the
converter.
In hold mode and to restore Node ZERO to 0V within
the limits of the converter’s 12- bit resolution, the
output of the capacitive digital-to-analog converter
(the CDAC) is adjusted during the remainder of the
conversion cycle. In other words, the stored charge
on C
HOLD
is transferred to the binary-weighted CDAC
where it is converted into a digital representation of
the analog input signal. At end of the conversion
Figure 3: TSM1285 Typical Application
Circuit.
Figure 4: TSM1285 Equivalent Input Circuit
Details.
TSM1285
TSM1285 Rev. 1.0 Page 9
process, the input side of CHOLD is switched back to
AIN so as to be charged to the input signal again.
An ADC’s acquisition time is function of how fast its
input capacitance can be charged. If an input signal’s
driving-point source impedance is high, the
acquisition time is lengthened and more time must be
allowed between conversions. The acquisition time
(tACQ) is the maximum time the ADC requires to
acquire the signal and is also the minimum time
needed for the signal to be acquired. The TSM1285’s
acquisition time is calculated from the following
expression:
tACQ = 9 x (RS + RIN) x 10pF
where RIN = 100 (the TSM1285’s internal track/hold
switch resistance), RS = the input signal’s source
impedance, and tACQ is never less than 625ns.
Because of the input structure of the TSM1285,
sources with output impedances of 1k or less do not
affect significantly the AC performance of the
TSM1285. The TSM1285 can still be used in
applications where the source impedance is higher so
long as a 0.01μF capacitor is connected between the
analog input and GND. Limiting the ADC’s input
signal bandwidth, the use of an external, input
capacitor forms an RC filter with the input’s source
impedance.
Input Bandwidth Conside rations
Since the TSM1285’s input track-and-hold circuit
exhibits a 10 MHz small-signal bandwidth, it is
possible to measure periodic signals and to digitize
high-speed transient events with signal bandwidths
higher than the TSM1285’s sampling rate by using
undersampling techniques. To avoid the aliasing of
high-frequency signals into the frequency band of
interest, the use of external anti-alias filter circuits
(discrete or integrated) is recommended. The time
constant of the external anti-alias filter should be set
so as not to interfere with the desired signal
bandwidth.
Analog Input Protection
The TSM1285 incorporates internal protection diodes
that clamp the analog input between VDD and GND.
These internal protection diodes allow the AIN pin to
swing from GND - 0.3V to VDD + 0.3V without causing
damage to the TSM1285. However, for accurate
conversions near full scale, the input signal must not
exceed VDD by more than 50mV or be lower than
GND by 50mV.
If the analog inputs can exceed 50mV beyond the
supplies, then the current in the forward-biased
protection diodes should be limited to less than
2mA since large fault currents can affect
conversion results.
Internal Reference Considerations
The TSM1285 has an internal voltage reference that
is factory-trimmed to 2.5V. The internal reference
output is connected to the REF pin and is also
connected to the ADC’s internal CDAC. The REF
output can be used as a reference voltage source for
other components external to the ADC and can
source up to 750μA. To maintain conversion
accuracy to within 1 LSB, a 4.7μF capacitor from the
REF pin to GND is recommended. While larger-
valued capacitors can be used to further reduce
reference wide-band noise, larger capacitor values
can increase the TSM1285’s wake-up time when
exiting from shutdown mode (see the “Using SHDN to
Reduce Operating Supply Current” section for more
information). When in shutdown (that is, when
SHDN = 0), the TSM1285’s internal 2.5-V reference
is disabled.
Serial Digital Interface
Initialization after Power-Up and Starting a
Conversion
If the SHDN pin is not driven low upon an initial, cold-
start condition, it may take up to 2.5ms for a fully-
discharged 4.7μF reference bypass capacitor to
provide adequate charge for specified conversion
accuracy. As a result, conversions should not be
initiated during this reference capacitor charge-up
delay. To initiate a conversion, the CS pin is toggled
(or driven) low. At the CS’s falling edge, the
TSM1285’s internal track-and-hold is placed in hold
mode and a conversion is initiated. Data can then be
transferred out of the ADC using an external serial
clock.
TSM1285
Page 10 TSM1285 Rev. 1.0
Figure 6: TSM1285 Shutdown Operation.
Using the ADC’s SHDN to Reduce Operating
Supply Current
Power consumption can be reduced significantly by
turning off the TSM1285 in between conversions.
Figure 5 illustrates the TSM1285’s average supply
current versus conversion rate. The wake-up delay
time (t
WAKE
) is the time from when the SHDN pin is
deasserted to the time when a conversion may be
initiated (Refer to Figure 6). This delay time depends
on how long the ADC was in shutdown (Refer to
Figure 7) because the external 4.7μF reference
bypass capacitor is discharged slowly when
SHDN = 0.
Timing and Control Details
The CS and SCLK digital inputs control the
TSM1285’s conversion-start and data-read
operations. The ADC’s serial-interface operations are
illustrated in Figures 8 and 9.
A CS high-to-low transition initiates the conversion
sequence - the input track-and-hold samples the input
signal level, the ADC begins to convert, and the
DOUT pin changes state from high impedance to
logic low. The external SCLK signal is used to drive
the conversion process and is also used to transfer
the converted data out of the ADC as each bit of
conversion is determi ned.
The SCLK signal transfers data after a low-to-high
transition of the third (3
rd
) SCLK pulse. After each
subsequent SCLK rising edge, transitions on the
DOUT pin occur in 20ns. The third rising clock edge
produces the MSB of the conversion at DOUT,
followed by the remaining bits. Since there are twelve
data bits and three leading zeros, at least fifteen
rising clock edges are needed to transfer the entire
data stream. Extra SCLK pulses occurring after the
conversion result has been completely transferred out
and, before to a new, low-to-high transition on CS,
produce a string trailing zeros at DOUT. In addition,
the extra SCLK pulses have no effect on converter
operation.
Minimum conversion cycle time can be accomplished
by: (a) toggling the CS pin high after reading the
conversion result’s LSB; and (b), after the specified
minimum time defined by t
CS
has elapsed, toggling
the CS pin low again to initiate the next conversion.
Output Data Coding and Transfer Fun ction
Conversion results at the TSM1285’s DOUT pin are
straight binary data. Figure 10 illustrates the nominal
transfer function where code transitions occur halfway
between successive integer LSB values. If
V
REF
= +2.500V, then 1 LSB = 610μV or 2.500V/4096.
CONVERSION RATE - ksps
SUPPLY CURENT - mA
V
DD
= 3V
DOUT = FS
R
L
=
C
L
= 10pF
100
10
1
0.1 0.1 1 100 1k
10
1k
Figure 5: TS M1285 Supply Current vs Conversion Rate
TSM1285
TSM1285 Rev. 1.0 Page 11
Figure 8: TSM1285 Serial Interface Tim i ng Sequence
Figure 9: TSM1285 Serial Interface Timing Specifications in Detail.
APPLICATIONS INFORMATION
Connection to Industry-Stand ard Serial Interfaces
The TSM1285’s serial interface is fully compatible
with SPI/QSPI and MICROWIRE standard serial
interfaces (Refer to Figure 11). For serial interface
operation with these standards, the CPU’s serial
interface should be set to master mode so the CPU
then generates the serial clock. Second, the CPU’s
serial clock should be configured to operate up to
4.8MHz. The process to configure the serial clock and
data transfer operation is as follows:
1) Using a general-p urpose I/O line from the CPU, the
CS pin is driven low to start a conversion. DOUT
transitions from high impedance to logic low. The
SCLK polarity should be low to start the conversion
process corre ctly .
2) Next, SCLK is activated for a minimum of 15 SCLK
cycles where the first two SCLKs produce zeros at
the DOUT pin. Data at DOUT is formatted MSB first
and DOUT transitions occur 20ns after the third (3
rd
)
SCLK low-to-high transition. Once the low-to-high
SCLK transition has occurred, data is valid at DOUT
TIME IN SHUTDOWN MODE - sec
REFERENCE POWER-UP DELAY TIME - ms
C
REF
= 4.7µF
2
1
0.5
0 0.1m 10m 1 10
100m
2.5
1.5
1m
Figure 7: T S M1285 Reference Power-Up Delay
vs Duration in Shutdown Mode
TSM1285
Page 12 TSM1285 Rev. 1.0
according to the t
DOV
(SCLK Rise to DOUT Valid)
timing specification. Valid output data can then be
transferred into µP or µCs on SCLK low-to-high
transitions.
3) At or after the 15th SCLK low-to-high transition, the
CS pin can be toggled high to halt the transfer
process. If the CS pin remains low and the SCLK is
still active, trailing zeros are transferred out after the
LSB.
4) Once the CS pin is held at logic high for at least
t
CS
, a new conversion cycle is started when the CS
pin is toggled low. If a conversion is aborted by
toggling the CS pin high before the current
conversion has completed, a new conversion cycle
can only be started after a the ADC has acquired the
signal (t
ACQ
).
The CS pin must be held low and SCLK active until
all data bits are transferred out of the ADC. As shown
in Figure 8, data can be transferred in two 8-bit bytes
or continuously. The bytes contain the result of the
conversion padded with three leading 0s in the first 8-
bit byte and 1 trailing 0 in the second 8-bit byte.
SPI and MICROWIRE Interface Details
When using an SPI or MICROWIRE interface, setting
[CPOL:CPHA] = [0:0] configures the microcontroller’s
serial clock and sampling edge for the TSM1285. The
conversion commences on a high-to-low transition of
the CS pin. The DOUT pin transitions from a high-
impedance state to a logic low, indicating a
conversion is in progress. Two consecutive 1-byte
data reads are required to transfer the full 12-bit
result from the ADC. DOUT output data transitions
occur on the SCLK’s low-to-high transition and are
transferred into the downstream microcontroller on
the SCLK’s low-to-high transition.
The first byte contains three leading 0s and then five
bits of the conversion result. The second byte
contains the remaining seven bits of the conversion
result and one trailing zero. Refer to Figure 11 for the
circuit connections and to Figure 12 for all timing
details.
QSPI Details
Using a QSPI microcontroller, setting
[CPOL:CPHA] = [0:1] configures the microcontroller’s
serial clock and sampling edge for the TSM1285.
Unlike the SPI, which requires two 1-byte reads to
transfer all 12 bits of data from the ADC, the QSPI
allows a minimum number of clock cycles necessary
to transfer data from the ADC to the microcontroller.
Thus, the TSM1285 requires 15 SCLK clock cycles
from the microcontroller to transfer the 12 bits of data
with no trailing zeros. As shown in Figure 13, the
conversion results contain two leading 0s followed by
the MSB-first-formatted, 12-bit data stream.
Figure 10: ADC Unipolar Transfer Function
for Straight Binary Digital Data.
Figure 11: TSM1285 Circuit Connections to
Industry-Standard Serial
Interfaces.
TSM1285
TSM1285 Rev. 1.0 Page 13
Figure 12: SPI/MICROWIRE-TSM1285 Serial Interface Timing Details with [CPOL:CPHA] = [0:0].
Figure 13: QSPI-TSM1285 Serial Interface Timing Details with [CPOL:CPHA] = [0:1].
PCB Layout, Ground Plane Management, and
Capacitive Bypassing
For best performance, printed circuit boards should
always be used and wire-wrap boards are not
recommended. Good PC board layout techniques
ensure that digital and analog signal lines are kept
separate from each other, analog and digital
(especially clock) lines are not routed parallel to one
another, and high-speed digital lines are not routed
underneath the ADC package.
A recommended system ground connection is
illustrated in Figure 14. A single-point analog ground
(star ground point) should be created at the ADC’s
GND and separate from the logic ground. All analog
grounds as well as the ADC’s GND pin should be
connected to the star ground. No other digital system
ground should be connected to this ground. For
lowest-noise operation, the ground return to the star
ground’s power supply should be low impedance and
as short as possible.
High-frequency noise on the V
DD
power supply may
affect the ADC’s high-speed comparator. Therefore, it
is necessary to bypass the V
DD
supply pin to the star
ground with 0.1μF and 1μF capacitors in parallel and
placed close to the ADC’s Pin 1. Component lead
lengths should be very short for optimal supply-noise
rejection. If the power supply is very noisy, an
optional 10- resistor can be used in conjunction with
the bypass capacitors to form a low-pass filter as
shown in Figure 14.
Figure 14: Recommended Power Supply
Bypassing and Star Ground
Configuration.
TSM1285
Page 14 Silicon Laboratories, Inc. TSM1285 Rev. 1.0
400 West Cesar Chavez, Austin, TX 78701
+1 (512) 416-8500 www.silabs.com
PACKAGE OUTLINE DRAWING
8-Pin SOIC Package Outline Drawing
(N.B., Drawings are not to scale)
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