Datasheet SPT7910SCJ, SPT7910SCU Datasheet (SPT)

SPT7910

12-BIT, 10 MSPS, ECL, A/D CONVERTER

FEATURES

• Monolithic

• 12-Bit 10 MSPS Converter

• 67 dB SNR @ 500 kHz Input

• On-Chip Track/Hold

• Bipolar ±2.0 V Analog Input

• Low Power (1.4 W Typical)

• 5 pF Input Capacitance

• ECL Outputs

GENERAL DESCRIPTION

The SPT7910 analog-to-digital converter is industry's first
12-bit monolithic analog-to-digital converter capable of sample
rates greater than 10 MSPS. On board input buffer and track/
hold function assures excellent dynamic performance with­out the need for external components. Drive requirement
problems are minimized with an input capacitance of only
5 pF.

Inputs and outputs are ECL to provide a higher level of noise
immunity in high speed system applications. An overrange

APPLICATIONS

• Radar Receivers

• Professional Video

• Instrumentation

• Medical Imaging

• Electronic Warfare

• Digital Communications

• Digital Spectrum Analyzers

• Electro-Optics

output signal is provided to indicate overflow conditions.
Output data format is straight binary. Power dissipation is
very low at only 1.4 watts with power supply voltages of +5.0
and -5.2 volts. The SPT7910 also provides a wide input
voltage range of ±2.0 volts.

The SPT7910 is available in a 32-lead ceramic sidebrazed
DIP package and in die form. A commercial temperature
range of 0 to +70 °C is currently offered.

BLOCK DIAGRAM

V

IN

INPUT

BUFFER

ANALOG GAIN

COMPRESSION

PROCESSOR

Signal Processing Technologies, Inc.

4-BIT FLASH

CONVERTER

TRACK AND HOLD

AMPLIFIERS

ASYNCHRONOUS

SAR

4

CORRECTION,

OUTPUT ECL

8

4755 Forge Road, Colorado Springs, Colorado 80907, USA

Phone: (719) 528-2300 FAX: (719) 528-2370

ERROR

DECODING

AND

DRIVERS

DIGITAL

OUTPUT

12

ABSOLUTE MAXIMUM RATINGS (Beyond which damage may occur)1 25 °C

Supply Voltages

VCC............................................................... -0.3 to +6 V

Output

Digital Outputs .............................................. 0 to -30 mA

VEE............................................................... +0.3 to -6 V

Temperature

Input Voltages

Analog Input............................................... VFB≤VIN≤V

VFT, VFB. ................................................... +3.0 V, -3.0 V

Reference Ladder Current .....................................12 mA

FT

Operating Temperature ................................... 0 to 70 °C

Junction Temperature ........................................... 175 °C

Lead Temperature, (soldering 10 seconds).......... 300 °C

Storage Temperature................................-65 to +150 °C

Note: 1. Operation at any Absolute Maximum Rating is not implied. See Electrical Specifications for proper nominal

applied conditions in typical applications.

ELECTRICAL SPECIFICATIONS

TA=T
unless otherwise specified.

PARAMETERS CONDITIONS LEVEL MIN TYP MAX UNITS

Resolution 12 Bits
DC Accuracy (+25 °C)

Analog Input

Reference Input

Timing Characteristics

Dynamic Performance

to T

MIN

Integral Nonlinearity ± Full Scale V ±2.0 LSB
Differential Nonlinearity 250 kHz Sample Rate V ±0.8 LSB
No Missing Codes VI Guaranteed

Input Voltage Range VI ±2.0 V
Input Bias Current VI 30 60 µA
Input Resistance VIN=0 V VI 100 300 kΩ
Input Capacitance V 5 pF
Input Bandwidth 3 dB Small Signal V 120 MHz
+FS Error V ±5.0 LSB

-FS Error V ±5.0 LSB

Reference Ladder Resistance VI 500 800 Ω
Reference Ladder Tempco V 0.8 Ω/°C

Maximum Conversion Rate VI 10 MHz
Overvoltage Recovery Time V 20 ns
Pipeline Delay (Latency) IV 1 Clock Cycle
Output Delay V 5 ns
Aperture Delay Time V 1 ns
Aperture Jitter Time V 5 ps-RMS

Effective Number of Bits
fIN=500 kHz 10.2 Bits
fIN=1.0 MHz 10.0 Bits
fIN=3.58 MHz 9.5 Bits

, VCC=+5.0 V, VEE=-5.2 V, DVCC=+5.0 V, VIN=±2.0 V, VSB=-2.0 V, VST=+2.0 V, f

MAX

TEST TEST SPT7910

10 MHz, 50% clock duty cycle,

CLK=

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SPT7910

2 3/11/97

ELECTRICAL SPECIFICATIONS

TA=T

MIN

to T

, VCC=+5.0 V, VEE=-5.2 V, DVCC=+5.0 V, VIN=±2.0 V, VSB=-2.0 V, VST=+2.0 V, f

MAX

10 MHz, 50% clock duty cycle,

CLK=

unless otherwise specified.

TEST TEST SPT7910

PARAMETERS CONDITIONS LEVEL MIN TYP MAX UNITS

Dynamic Performance

Signal-To-Noise Ratio
(without Harmonics)
f

=500 kHz +25 °C I 64 67 dB

IN

to T

T

MIN

=1 MHz +25 °C I 64 66 dB

f

IN

T

MIN

=3.58 MHz +25 °C I 62 64 dB

f

IN

T

MIN

Harmonic Distortion

1

to T

to T

MAX

MAX

MAX

IV 58 61 dB

IV 58 60 dB

IV 58 60 dB

fIN=500 kHz +25 °C I 63 66 dB

to T

T

MIN

=1.0 MHz +25 °C I 63 65 dB

f

IN

T

MIN

=3.58 MHz +25 °C I 59 61 dB

f

IN

T

MIN

to T

to T

MAX

MAX

MAX

IV 59 62 dB

IV 59 61 dB

IV 57 59 dB

Signal-to-Noise and Distortion

=500 kHz +25 °C I 60 63 dB

f

IN

T

to T

MIN

=1.0 MHz +25 °C I 60 62 dB

f

IN

T

MIN

=3.58 MHz +25 °C I 57 59 dB

f

IN

T

MIN

Spurious Free Dynamic Range
Differential Phase
Differential Gain

3

3

2

+25 °C V 74 dB
+25 °C V 0.2 Degree
+25 °C V 0.7 %

to T

to T

MAX

MAX

MAX

IV 55 58 dB

IV 55 57 dB

IV 54 56 dB

Digital Inputs

Logic 1 Voltage VI -1.1 V
Logic 0 Voltage VI -1.5 V
Maximum Input Current Low VI -500 ±200 +750 µA
Maximum Input Current High VI -500 ±300 +750 µA
Pulse Width Low (CLK) IV 30 ns
Pulse Width High (CLK) IV 30 300 ns

Digital Outputs

Logic 1 Voltage 50 Ω to -2 V VI -1.1 -0.8 V
Logic 0 Voltage 50 Ω to -2 V VI -1.8 -1.5 V

Power Supply Requirements

Voltages V

Currents I

-V

-I

CC

EE

CC

EE

IV +4.75 +5.25 V
IV -4.95 -5.45 V
VI 150 190 mA

VI 125 160 mA
Power Dissipation Outputs Open VI 1.4 1.8 W
Power Supply Rejection Ratio (5 V±0.25 V, -5.2 V ±0.25 V) V 1.0 LSB

Typical thermal impedances (unsoldered, in free air): 32L sidebrazed DIP. θja = 50 °C/W.

1

64 distortion BINS from 4096 pt FFT.

2

fIN = 1 MHz.

3

fIN = 3.58 and 4.35 MHz.

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SPT7910

A

A

A

A

TEST LEVEL CODES

TEST LEVEL

TEST PROCEDURE

All electrical characteristics are subject to the
following conditions:

All parameters having min/max specifications
are guaranteed. The Test Level column indi­cates the specific device testing actually per­formed during production and Quality Assur­ance inspection. Any blank section in the data
column indicates that the specification is not
tested at the specified condition.

Figure 1A: Timing Diagram

N

tt

pwH pwL

CLK

III
IV

VI

I

II

V

N+1

100% production tested at the specified temperature.
100% production tested at TA=25 °C, and sample

tested at the specified temperatures.
QA sample tested only at the specified temperatures.
Parameter is guaranteed (but not tested) by design

and characterization data.
Parameter is a typical value for information purposes

only.
100% production tested at TA = 25 °C. Parameter is

guaranteed over specified temperature range.

N+2

CLK

OUTPUT
DATA

Figure 1B: Single Event Clock

CLK

CLK

OUTPUT
DATA

Table I - Timing Parameters

PARAMETERS DESCRIPTION MIN TYP MAX UNITS

t

d

t

pwH

t

pwL

t

d

N-2 N-1

CLK to Data Valid Prop Delay - 5 ns
CLK High Pulse Width 30 - 300 ns
CLK Low Pulse Width 30 - - ns

DATA VALID

N

t

d

DATA VALID

N+1

DATA VALID

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SPECIFICATION DEFINITIONS

APERTURE DELAY

Aperture delay represents the point in time, relative to the
rising edge of the CLOCK input, that the analog input is
sampled.

APERTURE JITTER

The variations in aperture delay for successive samples.

DIFFERENTIAL GAIN (DG)

A signal consisting of a sine wave superimposed on various
DC levels is applied to the input. Differential gain is the
maximum variation in the sampled sine wave amplitudes at
these DC levels.

DIFFERENTIAL PHASE (DP)

A signal consisting of a sine wave superimposed on various
DC levels that is applied to the input. Differential phase is the
maximum variation in the sampled sine wave phases at these
DC levels.

EFFECTIVE NUMBER OF BITS (ENOB)

SINAD = 6.02N + 1.76, where N is equal to the effective
number of bits.

DIFFERENTIAL NONLINEARITY (DNL)

Error in the width of each code from its theoretical value.
(Theoretical = VFS/2N)

INTEGRAL NONLINEARITY (INL)

Linearity error refers to the deviation of each individual code
(normalized) from a straight line drawn from -Fs through +Fs.
The deviation is measured from the edge of each particular
code to the true straight line.

OUTPUT DELAY

Time between the clock's triggering edge and output data
valid.

OVERVOLTAGE RECOVERY TIME

The time required for the ADC to recover to full accuracy after
an analog input signal 125% of full scale is reduced to 50%
of the full-scale value.

SIGNAL-TO-NOISE RATIO (SNR)

The ratio of the fundamental sinusoid power to the total noise
power. Harmonics are excluded.

SINAD - 1.76

N =

+/- FULL-SCALE ERROR (GAIN ERROR)

Difference between measured full scale response
[(+Fs) - (-Fs)] and the theoretical response (+4 V -2 LSBs)
where the +FS (full scale) input voltage is defined as the
output transition between 1-10 and 1-11 and the -FS input
voltage is defined as the output transition between 0-00 and
0-01.

INPUT BANDWIDTH

Small signal (50 mV) bandwidth (3 dB) of analog input stage.

6.02

SIGNAL-TO-NOISE AND DISTORTION (SINAD)

The ratio of the fundamental sinusoid power to the total noise
and distortion power.

TOTAL HARMONIC DISTORTION (THD)

The ratio of the total power of the first 64 harmonics to the
power of the measured sinusoidal signal.

SPURIOUS FREE DYNAMIC RANGE (SFDR)

The ratio of the fundamental sinusoidal amplitude to the
single largest harmonic or spurious signal.

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50

20

30

40

60

70

80

10

-1

10

0

10

1

THD vs Input Frequency

Input Frequency (MHz)

Total Harmonic Distortion (dB)

fs = 10 MSPS

Signal-to-Noise and Distortion (dB)

20

30

40

50

60

70

80

10

-1

10

0

10

1

SINAD vs Input Frequency

Input Frequency (MHz)

fs =10 MSPS

TYPICAL PERFORMANCE CHARACTERISTICS

SNR vs Input Frequency

80

70

60

50

40

Signal-to-Noise Ratio (dB)

30

20

-1

10

SNR, THD, SINAD vs Sample Rate

80

70

60

50

f

in = 1 MHz

40

SNR, THD, SINAD (dB)

30

fs = 10 MSPS

0

10

Input Frequency (MHz)

SNR, THD

SINAD

1

10

20

-1

10

0

-30

-60

Amplitude (dB)

-90

-120
012345

SPT

0

10

Sample Rate (MSPS)

Spectral Response

Frequency (MHz)

f

= 10 MSPS

S

= 1 MHz

f

IN

1

10

SNR, THD, SINAD vs Temperature

75

70

65

SNR

THD

60

f

SNR, THD, SINAD (dB)

55

50

-25 0 +25 +50 +75

s = 10 MSPS

f

in = 1 M Hz

SINAD

Temperature (°C)

6 3/11/97

SPT7910

TYPICAL INTERFACE CIRCUIT

The SPT7910 requires few external components to achieve
the stated operation and performance. Figure 2 shows the
typical interface requirements when using the SPT7910 in
normal circuit operation. The following section provides a
description of the pin functions and outlines critical perfor­mance criteria to consider for achieving the optimal device
performance.

POWER SUPPLIES AND GROUNDING

The SPT7910 requires the use of two supply voltages, V
and VCC. Both supplies should be treated as analog supply
sources. This means the VEE and VCC ground returns of the
device should both be connected to the analog ground plane.
All other -5.2 V requirements of the external digital logic circuit
should be connected to the digital ground plane. Each power
supply pin should be bypassed as closely as possible to the
device with .01 µF and 10 µF capacitors as shown in
figure 2.

The two grounds available on the SPT7910 are AGND and
DGND. DGND is used only for ECL outputs and is to be
referenced to the output pulldown voltage. These grounds
are not tied together internal to the device. The use of ground
planes is recommended to achieve the best performance of

EE

the SPT7910. The AGND and the DGND ground planes
should be separated from each other and only connected
together at the device through an inductance or ferrite bead.
Doing this will minimize the ground noise pickup.

VOLTAGE REFERENCE

The SPT7910 requires the use of two voltage references: V

FT

and VFB. VFT is the force for the top of the voltage reference
ladder (+2.5 V typ), VFB (-2.5 V typ) is the force for the bottom
of the voltage reference ladder. Both voltages are applied
across an internal reference ladder resistance of 800 ohms.
In addition, there are five reference ladder taps (VST,V
V

RT2, VRT3,

reference ladder (+2.0 V), V

and VSB). VST is the sense for the top of the

is the midpoint of the ladder

RT2

RT1,

(0.0 V typ) and VSB is the sense for the bottom of the
reference ladder (-2.0 V). V

RT1

and V

are quarter point

RT3

ladder taps (+1.0 and -1.0 V typical, respectively). The
voltages seen at VST and VSB are the true full scale input
voltages of the device when VFT and VFB are driven to the
recommended voltages (+2.5 V and -2.5 V typical respec­tively). V
scale input voltage of the device. V

and VSB should be used to monitor the actual full

ST

RT1, VRT2

and V

RT3

should not be driven to the expected ideal values as is
commonly done with standard flash converters. When not
being used, a decoupling capacitor of .01 uF connected to
AGND from each tap is recommended to minimize high
frequency noise injection.

Figure 2 - Typical Interface Circuit

CLK-IN

CLK-IN
Analog

Input

Analog

Input

10 µF

+

+5 V

IC1

(REF-03)

2

VIN

GND

.01 µF

*R2 and R3
matched to 0.1%

VOUT

4

6

Tri m

5

+5 V

7

R4

10 kΩ

10 µF

R1

10 kΩ

*

R2

30 kΩ

3

2

+

-

IC2

(OP-07)

-5.2 V

4

1

8

6

.01 µF

10 µF

CLK

CLK

VIN1

VIN2

+

.01 µF

+2.5 V

VFT

VST

.01 µF

VRM

.01 µF

R3

*

30 kΩ

VSB

.01 µF

VFB

-2.5 V

.01 µF

+

NOTE: D1=D2=1N5817 or equivalent. (Used to prevent damage caused by power sequencing.)

VEE

-5.2 V +5 V

2

D12 (OVERRANGE)

DGND

DG

+

D11 (MSB)

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0 (LSB)

10 µF

.01 µF

AG

AGND

( 5 V RTN &

-5.2 V RTN )

4

Decoding Network

DG

AG

L

10 µH

( -2 V RTN )

Coarse

A/D

ANALOG

PRESCALER

R

2R

2R

2R

2R

R

VEE

D2D1

+

10 µF

.01 µF

VCC

T/H AMPLIFIER

BANK

SUCCESSIVE

INTERPOLATION

STAGE # i

SUCCESSIVE

INTERPOLATION

STAGE # N

VCC

+

10 µF

.01 µF

Digital Outputs

13 x 50 Ω

-2 V-5.2 V +5 V

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SPT7910

7 3/11/97

CLK

The analog input range will scale proportionally with respect
to the reference voltage if a different input range is required.
The maximum scaling factor for device operation is ± 20% of
the recommended reference voltages of VFT and VFB. How­ever, because the device is laser trimmed to optimize perfor­mance with VSB and VST equal to -2.0 V and +2.0 V respec­tively, the accuracy of the device will degrade if operated
beyond a ± 2% range.

The following errors are defined:
+FS error = top of ladder offset voltage = ∆(+FS -VST)

-FS error = bottom of ladder offset voltage = ∆(-FS -VSB)
Where the +FS (full scale) input voltage is defined as the input

approximately 1 LSB above the output transition of 1—10
and 1—11 and the -FS input voltage is defined as the input
approximately 1 LSB below the output transition of 0—00 and
0—01.

CLOCK INPUT

The clock inputs (CLK,
differentially with ECL levels. Differential clock driving is
highly recommended to minimize the effects of clock jitter.
The clock may be driven single ended since
biased to -1.3 V.
capacitor to AGND is recommended. As with all high speed
circuits, proper terminations are required to avoid signal
reflections and possible ringing that can cause the device to
trigger at an unwanted time.

The clock input duty cycle should be 50% where possible, but
performance will not be degraded if kept within the range of
40-60%. However, in any case the clock pulse width (tpwH)
must be kept at 300 ns maximum to ensure proper operation
of the internal track and hold amplifier. (See the timing
diagram.) The analog input signal is latched on the rising edge
of the CLK.

may be left open, but a .01 µF bypass

CLK

) are designed to be driven

is internally

CLK

An example of a reference driver circuit recommended is
shown in figure 2. IC1 is REF-03, the +2.5 V reference with a
tolerance of 0.6% or ± 0.015 V. The potentiometer R1 is
10 kΩ and supports a minimum adjustable range of up to
150 mV. IC2 is recommended to be an OP-07 or equivalent
device. R2 and R3 must be matched to within 0.1% with good
TC tracking to maintain a 0.3 LSB matching between VFT and
VFB. If 0.1% matching is not met, then potentiometer R4 can
be used to adjust the VFB voltage to the desired level. R1 and
R4 should be adjusted such that VST and VSB are exactly
+2.0 V and -2.0 V respectively.

ANALOG INPUT

V

and V

IN1

the same point internally. Either one may be used as an
analog input sense and the other for an input force. The inputs
can also be tied together and driven from the same source.
The full scale input range will be 80% of the reference voltage
or ±2 volts with VFB=-2.5 V and VFT=+2.5 V.

The drive requirements for the analog inputs are minimal
when compared to conventional Flash converters due the
SPT7910’s extremely low input capacitance of only 5 pF and
very high input impedance of 300 kΩ. For example, for an
input signal of ± 2 V p-p with an input frequency of 10 MHz,
the peak output current required for the driving circuit is only
628 µA.

are the analog inputs. Both inputs are tied to

IN2

DIGITAL OUTPUTS

The format of the output data (D0-D11) is straight binary.
(See table II.) These outputs are ECL 10K and 10KH
compatible with the output circuit shown in figure 3. The
outputs are latched on the rising edge of CLK with a propa­gation delay of 5 ns. There is a one clock cycle latency
between CLK and the valid output data (see timing diagram).
These digital outputs can drive 50 ohms to ECL levels when
pulled down to -2 V. Output loading pulled down to -5.2 V is
not recommended. The total specified power dissipation of
the device does not include the power used by these loads.
The additional power used by these loads can vary between
10 and 300 mW typically (including the overrange load)
depending on the output codes. If lower power levels are
desired, the output loads can be reduced, but careful consid­eration to the resistive and capacitive loads in relation to the
operating frequency must be considered.

Table II - Output Data Information

ANALOG INPUT OVERRANGE OUTPUT CODE

D12 D11-DO

>+2.0 V + 1/2 LSB 1 1111 1111 1111
+2.0 V -1 LSB O 1111 1111 111Ø

0.0 V O ØØØØ ØØØØ ØØØØ

-2.0 V +1 LSB O OOOO OOOO OOOØ
<-2.0 V O OOOO OOOO OOOO

SPT

(Ø indicates the flickering bit between logic 0 and 1).

SPT7910

8 3/11/97

Figure 3 - Output Circuit

AGND

•

•

•

OVERRANGE OUTPUT

The OVERRANGE OUTPUT (D12) is an indication that the
analog input signal has exceeded the full scale input voltage
by 1 LSB. When this condition occurs, the output will switch
to logic 1. All other data outputs are unaffected by this
operation. This feature makes it possible to include the
SPT7910 into higher resolution systems.

•

DGND

Data Out

EVALUATION BOARD

The EB7910 Evaluation Board is available to aid designers in
demonstrating the full performance of the SPT7910. This
board includes a reference circuit, clock driver circuit, output
data latches and an on-board reconstruction of the digital
data. An application note (AN7910) describing the operation
of this board as well as information on the testing of the
SPT7910 is also available. Contact the factory for price and
availability.

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PACKAGE OUTLINE

32-Lead Sidebrazed

32

1

G

A

E

F

C

B

D

H

I

J

INCHES MILLIMETERS

SYMBOL MIN MAX MIN MAX

A 0.081 0.099 2.06 2.51

B 0.016 0.020 0.41 0.51
C 0.095 0.105 2.41 2.67
D .050 typ 1.27
E 0.040 1.02 5.72
F 0.175 0.225 4.45 41.15
G 1.580 1.620 40.13 15.37
H 0.585 0.605 14.86 0.30

I 0.009 0.012 0.23 15.75

J 0.600 0.620 15.24 15.75

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PIN ASSIGNMENTS

PIN FUNCTIONS

DGND

D0

D1

D2

D3

D4

D5

D6

D7

D8

D9

D10

D11

D12

V

1

2

3

4

5

6

7

8

9

10

11

12

13

14

DIP

32

EE

AGND

31

V

30

CC

V

29

FB

V

28

SB

V

27

RT1

26

V

RT2

V

25

IN1

V

24

IN2

V

23

RT3

22

V

ST

V

21

FT

V

20

CC

AGND

19

NAME FUNCTION

DGND Digital Ground
AGND Analog Ground
D0-D11 ECL Outputs (D0=LSB)
D12 ECL Output Overrange
CLK Clock

CLK

V

EE

V

CC

V

RT1,VRT2,VRT3

V

, V

IN1

IN2

V

FT

V

ST

V

FB

V

SB

Inverted Clock

-5.2 V Supply
+5.0 V supply
Voltage Reference Taps
Inputs (tied together at the die)
Force for Top of Reference Ladder
Sense for Top of Reference Ladder
Force for Bottom of Reference Ladder
Sense for Bottom of Reference Ladder

DGND

CLK

15

16

18

V

EE

CLK

17

ORDERING INFORMATION

PART NUMBER TEMPERATURE RANGE PACKAGE

SPT7910SCJ 0 to +70 °C 32L Sidebrazed DIP
SPT7910SCU +25 °C Die*

*Please see the die specification for guaranteed electrical performance.

Signal Processing Technologies, Inc. reserves the right to change products and specifications without notice. Permission is hereby expressly
granted to copy this literature for informational purposes only. Copying this material for any other use is strictly prohibited.

WARNING - LIFE SUPPORT APPLICATIONS POLICY - SPT products should not be used within Life Support Systems without the specific
written consent of SPT. A Life Support System is a product or system intended to support or sustain life which, if it fails, can be reasonably
expected to result in significant personal injury or death.

Signal Processing Technologies believes that ultrasonic cleaning of its products may damage the wire bonding, leading to device
failure. It is therefore not recommended, and exposure of a device to such a process will void the product warranty.

SPT7910

SPT

11 3/11/97