MOTOROLA MC145159P1

Order this document
by MC145159–1/D
SEMICONDUCTOR TECHNICAL DATA
! !#
# $ " P SUFFIX
PLASTIC DIP
CASE 738
20
Interfaces with Dual–Modulus Prescalers
1
The MC145159–1 has a programmable 14–bit reference counter, as well as
fully programmable divide–by–N/divide–by–A counters. The counters are
programmed serially through a common data input and latched into the
appropriate counter latch, according to the last data bit (control bit) entered.
When combined with a loop filter and VCO, this device can provide all the
remaining functions for a PLL frequency synthesizer operating up to the
device’s frequency limit. For higher VCO frequency operations, a down mixer or
a dual–modulus prescaler can be used between the VCO and the PLL.
•
•
•
•
•
•
•
•
•
Operating Temperature Range: – 40 to 85°C
Low Power Consumption Through Use of CMOS Technology
3.0 to 9.0 V Supply Range
On– or Off–Chip Reference Oscillator Operation
Compatible with the Serial Peripheral Interface (SPI) on CMOS MCUs
÷ R Range = 3 to 16383
÷ N Range = 16 to 1023, ÷ A Range = 0 to 127
High–Gain Analog Phase Detector
See Application Note AN969
20
1
DW SUFFIX
SOG PACKAGE
CASE 751D
VF SUFFIX
SSOP
CASE TBD
ORDERING INFORMATION
MC145159P1
MC145159DW1
MC145159VF1
Plastic DIP
SOG Package
SSOP
PIN ASSIGNMENTS
PLASTIC DIP
AND SOG PACKAGE
SSOP
VSS′
1
20
CR
APDout
2
19
SRout
CH
3
18
ENB
VDD′
4
17
DATA
VSS′
RR
5
16
CLK
CR
RO
6
15
fin
OSCin
7
14
LD
OSCout
8
13
MC
CHARGE
9
12
VSS
10
11
FSO
RO
1
20
RR
OSCin
2
19
VDD′
OSCout
3
18
CH
CHARGE
4
17
APDout
VDD
5
16
FSO
6
15
VSS
7
14
SRout
MC
8
13
ENB
LD
9
12
DATA
fin
10
11
CLK
VDD
REV 1
8/95

Motorola, Inc. 1995
MOTOROLA
MC145159–1
1
BLOCK DIAGRAM
!#"
!#"
÷ ′
′
÷ ÷ !#"
* FSO is not and cannot be used as a digital phase detector output.
MAXIMUM RATINGS* (Voltages Referenced to VSS)
Symbol
VDD
Parameter
DC Supply Voltage
Value
Unit
– 0.5 to + 10
V
Vin, Vout
Input or Output Voltage (DC or Transient)
– 0.5 to VDD + 0.5
V
Iin, Iout
Input or Output Current (DC or Transient),
per Pin
± 10
mA
Supply Current, VDD or VSS Pins
± 30
mA
PD
Power Dissipation, per Package
500
mW
Tstg
Storage Temperature
– 65 to + 150
°C
260
°C
IDD, ISS
TL
Lead Temperature (8–Second Soldering)
This device contains circuitry to protect the
inputs against damage due to high static voltages or electric fields; however, it is advised that
normal precautions be taken to avoid applications of any voltage higher than maximum rated
voltages to this high–impedance circuit. For
proper operation it is recommended that Vin and
Vout be constrained to the range VSS ≤ (Vin or
Vout) ≤ VDD.
Unused inputs must always be tied to an
appropriate logic voltage level (e.g., either VSS
or VDD).
* Maximum Ratings are those values beyond which damage to the device may occur.
MC145159–1
2
MOTOROLA
ELECTRICAL CHARACTERISTICS (Voltages Referenced to VSS except ICR and IAPD which are referenced to VSS′)
– 40°C
Ch
Characteristic
i i
25°C
85°C
S b l
Symbol
VDD
Min
Max
Min
Max
Min
Max
U i
Unit
VDD
—
3
9
3
9
3
9
V
0 Level
VOL
3
5
9
—
—
—
0.05
0.05
0.05
—
—
—
0.05
0.05
0.05
—
—
—
0.05
0.05
0.05
V
1 Level
VOH
3
5
9
2.95
4.95
8.95
—
—
—
2.95
4.95
8.95
—
—
—
2.95
4.95
8.95
—
—
—
0 Level
VOL
3
5
9
—
—
—
0.9
1.5
2.7
—
—
—
0.9
1.5
2.7
—
—
—
0.9
1.5
2.7
1 Level
VOH
3
5
9
2.1
3.5
6.3
—
—
—
2.1
3.5
6.3
—
—
—
2.1
3.5
6.3
—
—
—
∆V
—
—
—
—
1.05
—
—
V
0 Level
VIL
3
5
9
—
—
—
0.9
1.5
2.7
—
—
—
0.9
1.5
2.7
—
—
—
0.9
1.5
2.7
V
1 Level
VIH
3
5
9
2.1
3.5
6.3
—
—
—
2.1
3.5
6.3
—
—
—
2.1
3.5
6.3
—
—
—
3
5
9
—
—
—
0
0
0
—
—
—
0
0
0
—
—
—
0
0
0
3
5
9
3.0
5.0
9.0
—
—
—
3.0
5.0
9.0
—
—
—
3.0
5.0
9.0
—
—
—
3
5
9
– 0.60
– 0.90
– 1.50
—
—
—
– 0.50
– 0.75
– 1.25
—
—
—
– 0.30
– 0.50
– 0.80
—
—
—
IOL
3
5
9
1.30
1.90
3.80
—
—
—
1.10
1.70
3.30
—
—
—
0.66
1.08
2.10
—
—
—
ICR
9
—
—
– 90
– 110
—
—
µA
IAPD
9
—
—
170
350
—
—
µA
3
5
9
– 0.44
– 0.64
– 1.30
—
—
—
– 0.35
– 0.51
– 1.00
—
—
—
– 0.22
– 0.36
– 0.70
—
—
—
IOL
3
5
9
0.44
0.64
1.30
—
—
—
0.35
0.51
1.00
—
—
—
0.22
0.36
0.70
—
—
—
Input Current — Data, CLK, ENB
Iin
9
—
± 0.3
—
± 0.1
—
± 1.0
µA
Input Current — fin, OSCin
Iin
9
±2
± 50
±2
± 25
±2
± 22
µA
Power Supply Voltage Range
Output Voltage
Vin = 0 V or VDD
Iout = 0 µA
(Except OSCout and APDout)
Output Voltage
OSCout
Vin = 0 V or VDD
∆Voltage, VCH – VAPDout, IAPDout ≈ 0 µA
Input Voltage
Vout = 0.5 V or VDD – 0.5 V
(All Outputs Except OSCout)
Input Voltage* — OSCin
VO = 2.1 V or 0.9 V
VO = 3.5 V or 1.5 V
VO = 6.3 V or 2.7 V
VIL
0 Level
1 Level
Output Current — MC
Vout = 2.7 V
Vout = 4.6 V
Vout = 8.5 V
Vout = 0.3 V
Vout = 0.4 V
Vout = 0.5 V
Sink
Output Current, APDout
RO = 240 k, VCH = 0 V, VAPDout = 4.5 V
Vout = 0.3 V
Vout = 0.4 V
Vout = 0.5 V
Input Capacitance
V
IOH
Source
Output Current, CR, VCR = 4.5 V, RR = 240 k
Output Current — Other Outputs
Vout = 2.7 V
Vout = 4.6 V
Vout = 8.5 V
V
VIH
VO = 0.9 V or 2.1 V
VO = 1.5 V or 3.5 V
VO = 2.7 V or 6.3 V
mA
IOH
Source
Sink
V
mA
Cin
—
—
10
—
10
—
10
pF
Three–State Output Capacitance — FSO
Cout
—
—
10
—
10
—
10
pF
Quiescent Current
Vin = 0 V or VDD
Iout = 0 µA
IDD
3
5
9
—
—
—
800
1200
1600
—
—
—
800
1200
1600
—
—
—
1600
2400
3200
µA
Three–State Leakage Current, Vout = 0 V or 9 V
IOZ
9
—
± 0.3
—
± 0.1
—
± 3.0
µA
* dc coupled square wave.
MOTOROLA
MC145159–1
3
SWITCHING CHARACTERISTICS (TA = 25°C, CL = 50 pF)
Figure
No.
Symbol
VDD
Min
Max
Unit
Output Rise Time — MC
4, 9
tTLH
3
5
9
—
—
—
115
60
40
ns
Output Fall Time — MC
4, 9
tTHL
3
5
9
—
—
—
60
34
30
ns
Output Rise and Fall Time — LD and SRout
4, 9
tTLH,
tTHL
3
5
9
—
—
—
140
80
60
ns
Propagation Delay Time — fin to MC
5, 9
tPLH,
tPHL
3
5
9
—
—
—
125
80
50
ns
6
tsu
3
5
9
30
20
18
—
—
—
ns
3
5
9
70
32
25
—
—
—
Characteristic
Setup Times — Data to CLK
CLK to ENB
Hold Time — CLK to Data
6
th
3
5
9
12
12
15
—
—
—
ns
Recovery Time — ENB to CLK
6
trec
3
5
9
5
10
20
—
—
—
ns
Input Rise and Fall Times — CLK, OSCin, fin
7
tr, tf
3
5
9
—
—
—
5
2
0.5
µs
Input Pulse Width — ENB and CLK
8
tw
3
5
9
40
35
25
—
—
—
ns
NOTE: Refer to the graphs and text in application note AN969 for maximum frequency information.
MC145159–1
4
MOTOROLA
COMPONENT PINS
PIN DESCRIPTIONS
INPUT PINS
CR
Ramp Capacitor (PDIP, SOG – Pin 15, SSOP – Pin 20)
OSCin, OSCout
Oscillator Input and Oscillator Output (PDIP, SOG –
Pins 2, 3; SSOP – Pins 7, 8)
The capacitor connected from this pin to VSS′ is charged
linearly, at a rate determined by RR. The voltage on this
capacitor is proportional to the phase difference of the
frequencies present at the internal phase detector inputs. A
polystyrene or mylar capacitor is recommended.
These pins form an on–chip reference oscillator when
connected to terminals of an external parallel–resonant
crystal. Frequency–setting capacitors of appropriate value
must be connected from OSC in to V SS and OSC out to
V SS. OSC in may also serve as input for an externally–generated reference signal. This signal will typically be ac
coupled to OSC in, but for larger amplitude signals (standard
CMOS logic levels), dc coupling may also be used. In the
external reference mode, no connection is required to
OSC out .
RR
Ramp Current Bias Resistor (PDIP, SOG – Pin 20,
SSOP – Pin 5)
A resistor connected from this pin to VSS′ determines the
rate at which the ramp capacitor is charged, thereby affecting
the phase detector gain (see Figure 2).
fin
Frequency Input (PDIP, SOG – Pin 10, SSOP – Pin 15)
CH
Hold Capacitor (PDIP, SOG – Pin 18, SSOP – Pin 3)
Input to the positive edge triggered divide–by–N and divide–by–A counters. fin is typically derived from a dual–
modulus prescaler and is ac coupled. This input has an
inverter biased in the linear region to allow use with ac
coupled signals as low as 500 mV peak–to–peak or direct
coupled signals swinging from VDD to VSS.
The charge stored on the ramp capacitor is transferred to
the capacitor connected from this pin to either VDD′ or VSS′.
The ratio of CR to CH should be large enough to have no
effect on the phase detector gain (CR > 10 CH). A low–leakage capacitor should be used.
DATA
Serial Data Input (PDIP, SOG – Pin 12, SSOP – Pin 17)
Counter and control information is shifted into this input.
The last data bit entered goes into the one–bit control shift
register. A logic 1 allows the reference counter information to
be loaded into its 14–bit latch when ENB goes high. A logic 0
entered as the control bit disables the reference counter
latch. The divide–by–A/divide–by–N counter latch is loaded,
regardless of the contents of the control register, when ENB
goes high. The data entry format is shown in Figure 1.
ENB
Transparent Latch Enable (PDIP, SOG – Pin 13,
SSOP – Pin 18)
A logic high on this input allows data to be entered into the
divide–by–A/divide–by–N latch and, if the control bit is high,
into the reference counter latch. Counter programming is
unaffected when ENB is low. ENB should be kept normally
low and pulsed high to transfer data to the latches.
CLK
Shift Register Clock (PDIP, SOG – Pin 11, SSOP – Pin 16)
A low–to–high transition on this input shifts data from the
serial data input into the shift registers.
RO
Output Bias Current Resistor (PDIP, SOG – Pin 1,
SSOP – Pin 6)
A resistor connected from this pin to VSS′ biases the output
N–Channel transistor, thereby setting a current sink on the
analog phase detector output. This resistor adjusts the
APDout bias current (see Figure 3).
OUTPUT PINS
APDout
Analog Phase Detector Output (PDIP, SOG – Pin 17,
SSOP – Pin 2)
This output produces a voltage that controls an external
VCO. The voltage range of this output (V DD = + 9 V) is from
below + 0.5 V to + 8 V or more. The source impedance of this
output is the equivalent of a source follower with an externally variable source resistor. The source resistor depends
upon the output bias current controlled by the output bias
current resistor, RO. The bias current is adjustable from
0.01 mA to 0.5 mA. The output voltage is not more than
1.05 V below the sampled point on the ramp. With a constant
sample of the ramp voltage at 9 V and the hold capacitor of
50 pF, the instantaneous output ripple is about 5 mV peak–
to–peak.
Figure 1. Data Entry Format
MOTOROLA
MC145159–1
5
CHARGE
Ramp Charge Indicator (PDIP, SOG – Pin 4, SSOP – Pin 9)
This output is high from the time fR goes high to the time
fV goes high (fR and fV are the frequencies at the phase
detector inputs). This high voltage indicates that the ramp
capacitor, CR, is being charged.
FSO
Three–State Frequency Steering Output (PDIP, SOG –
Pin 6, SSOP – Pin 11)
If the counted down input frequency on fin is higher than
the counted down reference frequency of OSCin, this output
goes low. If the counted down VCO frequency is lower than
that of the counted down OSCin, this output goes high.
The repetition rate of the frequency steering output pulses
is approximately equal to the difference of the frequencies
of the two counted down inputs from the VCO and OSCin.
See Application Note AN969 for further information.
LD
Lock Detector Indicator (PDIP, SOG – Pin 9, SSOP –
Pin 14)
This output is high during lock and goes low to indicate a
non–lock condition. The frequency and duration of the non–
lock pulses will be the same as either polarity of the frequency steering output.
and P + 1 represent the dual modulus prescaler divide values
respectively for high and low modulus control levels, N is the
number programmed into the divide–by–N counter, and A is
the number programmed into the divide–by–A counter.
SRout
Shift Register Output (PDIP, SOG – Pin 14, SSOP – Pin 19)
This pin is the non–inverted output of the last stage of the
32–bit serial data shift register. It is not latched by the ENB
line. If unused, SRout should be floated.
POWER SUPPLY
VDD
Positive Power Supply (PDIP, SOG – Pin 5, SSOP – Pin 10)
Positive power supply input for all sections of the device
except the analog phase detector. VDD and VDD′ should be
powered up at the same time to avoid damage to the
MC145159–1. VDD must be tied to the same potential as
VDD′.
VSS
Negative Power Supply (PDIP, SOG – Pin 7, SSOP – Pin 12)
Circuit ground for all sections of the MC145159–1 except
the analog phase detector. VSS must be tied to the same potential as VSS′.
MC
Dual Modulus Prescaler Control (PDIP, SOG – Pin 8,
SSOP – Pin 13)
VSS′
Analog Phase Detector Circuit Ground (PDIP, SOG –
Pin 16, SSOP – Pin 1)
The modulus control level is low at the beginning of a
count cycle and remains low until the divide–by–A counter
has counted down from its programmed value. At that time,
the modulus control goes high and remains high until the divide–by–N counter has counted the rest of the way down
from its programmed value (N – A additional counts since
both divide–by–N and divide–by–A are counting down during
the first portion of the cycle). Modulus control is then set back
low, the counters preset to their respective programmed
values, and the above sequence repeated. This provides for
a total programmable divide value of NT = N P + A, where P
Separate power supply and ground inputs are provided to
help reduce the effects in the analog section of noise coming
from the digital sections of this device and the surrounding
circuitry.
MC145159–1
6
VDD′
Analog Power Supply (PDIP, SOG – Pin 19, SSOP – Pin 4)
Separate power supply and ground inputs are provided to
help reduce the effects in the analog section of noise coming
from the digital sections of this device and the surrounding
circuitry.
MOTOROLA
",
$
$
$
$
′
$
$ $
$
#"#"!#
′$
$
′$
#
" +
+
+
$
µ
Figure 2. Charge Current vs Ramp Resistance
Ω
!!"+3
#"#"
!!" +
Ω
Figure 3. APDout Bias Current vs Output Resistance
DESIGN EQUATION
Kφ =
ICHARGE
2π fRCR
where
Kφ = phase detector gain, ICHARGE is from Figure 2
fR = reference frequency
CR = ramp capacitor (in farads)
SWITCHING WAVEFORMS
$
0
"
0
"
%
(
*-
4 $
!!
#"#"
0
0
Figure 4.
Figure 5.
4 $
"
$
!!
0
/1
0
)
4 $
!"
0
/1
$
!!
! (
*- *-
0
(
4 $
$
!!
0
.'&
4 $
0
.
!"
Figure 7.
$
!!
$#!
"
"
Figure 6.
#"#"
$
#
0
2
4 $
$
!!
Figure 8.
MOTOROLA
*
"!"
* Includes all probe and fixture capacitance.
Figure 9. Test Circuit
MC145159–1
7
DESIGN CONSIDERATIONS
CRYSTAL OSCILLATOR CONSIDERATIONS
The following options may be considered to provide a reference frequency to Motorola’s CMOS frequency synthesizers.
Use of a Hybrid Crystal Oscillator
Commercially available temperature–compensated crystal
oscillators (TCXOs) or crystal–controlled data clock oscillators provide very stable reference frequencies. An oscillator
capable of sinking and sourcing 50 µA at CMOS logic levels
may be direct or dc coupled to OSC in. In general, the highest
frequency capability is obtained utilizing a direct coupled
square wave having a rail–to–rail (V DD to V SS) voltage
swing. If the oscillator does not have CMOS logic levels on
the outputs, capacitive or ac coupling to OSC in may be used.
OSC out , an unbuffered output, should be left floating.
For additional information about TCXOs and data clock
oscillators, please consult the latest version of the eem Electronic Engineers Master Catalog, the Gold Book, or similar
publications.
Design an Off–Chip Reference
The user may design an off–chip crystal oscillator using
ICs specifically developed for crystal oscillator applications,
such as the MC12061 MECL device. The reference signal
from the MECL device is ac coupled to OSC in. For large amplitude signals (standard CMOS logic levels), dc coupling is
used. OSC out, an unbuffered output, should be left floating.
In general, the highest frequency capability is obtained with a
direct–coupled square wave having rail–to–rail voltage
swing.
stray inductance, and start–up stabilization time. Circuit stray
capacitance can also be handled by adding the appropriate
stray value to the values for Cin and Cout. For this approach,
the term Cstray becomes zero in the above expression for CL.
Power is dissipated in the effective series resistance of the
crystal, Re, in Figure 12. The maximum drive level specified
by the crystal manufacturer represents the maximum stress
that a crystal can withstand without damaging or excessive
shift in operating frequency. R1 in Figure 10 limits the drive
level. The use of R1 is not necessary in most cases.
To verify that the maximum dc supply voltage does not
overdrive the crystal, monitor the output frequency as a function of voltage at OSCout. (Care should be taken to minimize
loading.) The frequency should increase very slightly as the
dc supply voltage is increased. An overdriven crystal will
decrease in frequency or become unstable with an increase
in supply voltage. The operating supply voltage must be
reduced or R1 must be increased in value if the overdriven
condition exists. The user should note that the oscillator
start–up time is proportional to the value of R1.
Through the process of supplying crystals for use with
CMOS inverters, many crystal manufacturers have developed expertise in CMOS oscillator design with crystals. Discussions with such manufacturers can prove very helpful.
See Table 1.
FREQUENCY
Rf
OSCin
SYNTHESIZER
R1*
OSCout
Use of the On–Chip Oscillator Circuitry
The on–chip amplifier (a digital inverter) along with an appropriate crystal may be used to provide a reference source
frequency. A fundamental mode crystal, parallel resonant at
the desired operating frequency, should be connected as
shown in Figure 10.
For VDD = 5 V, the crystal should be specified for a loading
capacitance, CL, which does not exceed 32 pF for frequencies to approximately 8 MHz, 20 pF for frequencies in the
area of 8 to 15 MHz, and 10 pF for higher frequencies. These
are guidelines that provide a reasonable compromise between IC capacitance, drive capability, swamping variations
in stray and IC input/output capacitance, and realistic CL values. Assuming R1 = 0 Ω. the shunt load capacitance, CL,
presented across the crystal can be estimated to be:
CL = CinCout + Ca + Cstray + C1 • C2
C1 + C2
Cin + Cout
where
Cin = 5 pF (see Figure 11)
Cout = 6 pF (see Figure 11)
Ca = 1 pF (see Figure 11)
C1 and C2 = external capacitors (see Figure 10)
Cstray = the total equivalent external circuit stray
capacitance appearing across the
crystal terminals
The oscillator can be “trimmed” on–frequency by making a
portion or all of C1 variable. The crystal and associated components must be located as close as possible to the OSCin
and OSC out pins to minimize distortion, stray capacitance,
MC145159–1
8
C1
C2
* May be deleted in certain cases. See text.
Figure 10. Pierce Crystal Oscillator Circuit
Ca
OSCin
OSCout
Cin
Cout
Cstray
Figure 11. Parasitic Capacitances of the
Amplifier and Cstray
RS
1
2
CS
LS
1
2
CO
1
Re
Xe
2
NOTE: Values are supplied by crystal manufacturer
(parallel resonant crystal).
Figure 12. Equivalent Crystal Networks
MOTOROLA
Table 1. Partial List of Crystal Manufacturers
Name
United States Crystal Corp.
Crystek Crystal
Statek Corp.
Address
3605 McCart Ave., Ft. Worth, TX 76110
2351 Crystal Dr., Ft. Myers, FL 33907
512 N. Main St., Orange, CA 92668
Phone
(817) 921–3013
(813) 936–2109
(714) 639–7810
NOTE: Motorola cannot recommend one supplier over another and in no way suggests that this is a complete
listing of crystal manufacturers.
RECOMMENDED READING
Technical Note TN–24, Statek Corp.
Technical Note TN–7, Statek Corp.
E. Hafner, “The Piezoelectric Crystal Unit – Definitions and
Method of Measurement”, Proc. IEEE, Vol. 57, No. 2 Feb.,
1969.
D. Kemper, L. Rosine, “Quartz Crystals for Frequency
Control”, Electro–Technology, June, 1969.
P. J. Ottowitz, “A Guide to Crystal Selection”, Electronic
Design, May, 1966.
D. Babin, “Designing Crystal Oscillators”, Machine Design,
March 7, 1985.
D. Babin, “Guidelines for Crystal Oscillator Design”, Machine Design, April 25, 1985.
÷ ÷ Figure 13. Timing Diagram for Minimum Divide Value (N = 16)
MOTOROLA
MC145159–1
9
PACKAGE DIMENSIONS
P SUFFIX
PLASTIC DIP (DUAL IN–LINE PACKAGE)
CASE 738–03
-A!
20
11
B
1
! ! ! #
C
-T-
L
SEATING
PLANE
N
J 20 PL
D 20 PL
!
!
! " INCHES
MIN
MAX
DIM
A
B
C
D
E
F
G
J
K
L
M
N
M
F
K
G
! 10
E
%
MILLIMETERS
MIN
MAX
°
°
°
°
DW SUFFIX
SOG (SMALL OUTLINE GULL–WING) PACKAGE
CASE 751D–04
–A–
!
20
11
! %
! –B–
10X
$" !"
P
1
!
! "
!"
10
! "
!"
#
!"
!! $
! $" ! !
20X
D
J
!
F
R
C
–T–
18X
MC145159–1
10
G
K
SEATING
PLANE
X 45 _
DIM
A
B
C
D
F
G
J
K
M
P
R
MILLIMETERS
MIN
MAX
INCHES
MIN
MAX
_
_
_
_
M
MOTOROLA
VF SUFFIX
SSOP
CASE TBD
PLACE WHEN GET CASE#
MOTOROLA
MC145159–1
11
Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding
the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit,
and specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters can and do vary in different
applications. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. Motorola does
not convey any license under its patent rights nor the rights of others. Motorola products are not designed, intended, or authorized for use as components in
systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of
the Motorola product could create a situation where personal injury or death may occur. Should Buyer purchase or use Motorola products for any such
unintended or unauthorized application, Buyer shall indemnify and hold Motorola and its officers, employees, subsidiaries, affiliates, and distributors harmless
against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death
associated with such unintended or unauthorized use, even if such claim alleges that Motorola was negligent regarding the design or manufacture of the part.
Motorola and
are registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal Opportunity/Affirmative Action Employer.
How to reach us:
USA/EUROPE: Motorola Literature Distribution;
P.O. Box 20912; Phoenix, Arizona 85036. 1–800–441–2447
JAPAN: Nippon Motorola Ltd.; Tatsumi–SPD–JLDC, Toshikatsu Otsuki,
6F Seibu–Butsuryu–Center, 3–14–2 Tatsumi Koto–Ku, Tokyo 135, Japan. 03–3521–8315
MFAX: [email protected] – TOUCHTONE (602) 244–6609
INTERNET: http://Design–NET.com
HONG KONG: Motorola Semiconductors H.K. Ltd.; 8B Tai Ping Industrial Park,
51 Ting Kok Road, Tai Po, N.T., Hong Kong. 852–26629298
MC145159–1
12
◊
*MC145159-1/D*
MC145159–1/D
MOTOROLA