UT22VP10 Universal RADPAL - Aeroflex Microelectronic Solutions

Standard Products
UT22VP10 Universal RADPALTM
Data Sheet
November 2000
FEATURES
q High speed Universal RADPAL
- tPD: 15.5ns, 20ns, 25ns maximum
-
fMAX1: 33MHz maximum external frequency
-
Supported by industry-standard programmer
Amorphous silicon anti-fuse
q Radiation-hardened process and design; total dose irradiation testing to MIL-STD-883, Method 1019
- Total dose: 1.0E6 rads(Si)
- Upset threshold 50 MeV-cm2/mg (min)
- Latchup immune(LET>109 MeV-cm2/mg)
q QML Q & V compliant
q Asynchronous and synchronous RADPAL operation
- Synchronous PRESET
- Asynchronous RESET
q Packaging options:
- 24-pin 100-mil center DIP (0.300 x 1.2)
- 24-lead flatpack (.45 x .64)
- 28-lead quad-flatpack (.45 x .45)
q Up to 22 input and 10 output drivers may be configured
- CMOS & TTL-compatible input and output levels
- Three-state output drivers
q Standard Military Drawing 5962-94754 available
q Variable product terms, 8 to 16 per output
q 10 user-programmable output macrocells
- Registered or combinatorial operation
- Output driver polarity control selectable
- Two feedback paths available
13
12
11
10
9
8
7
6
5
4
3
2
1
VSS
Reset
PROGRAMMABLE ARRAY LOGIC
(132 X 44)
8
10
12
14
16
16
14
12
10
8
Preset
Macrocell
Macrocell
Macrocell
Macrocell
Macrocell
Macrocell
Macrocell
Macrocell
Macrocell
Macrocell
CP
VDD
14
15
16
17
18
19
20
21
22
23
24
Figure 1. Block Diagram
1
PRODUCT DESCRIPTION
QUAD-FLATPACK PIN CONFIGURATION
The UT22VP10 RADPAL is a fuse programmable logic array
device. The familiar sum-of-products (AND-OR) logic structure is complemented with a programmable macrocell. The
UT22VP10 is available in 24-pin DIP, 24-lead flatpack, and
28-lead quad-flatpack package offerings providing up to 22
inputs and 10 outputs. Amorphous silicon anti-fuse technology
provides the programming of each output. The user specifies
whether each of the potential outputs is registered or combinatorial. Output polarity is also individually selected, allowing for
greater flexibility for output configuration. A unique output enable function allows the user to configure bidirectional I/O on
an individual basis.
The UT22VP10 architecture implements variable sum terms
providing 8 to 16 product terms to outputs. This feature provides
the user with increased logic function flexibility. Other features
include common synchronous preset and asynchronous reset.
These features eliminate the need for performing the initialization function.
The UT22VP10 provides a device with the flexibility to implement logic functions in the 500 to 800 gate complexity. The
flexible architecture supports the implementation of logic functions requiring up to 21 inputs and only a single output or down
to 12 inputs and 10 outputs. Development and programming
support for the UT22VP10 is provided by DATA I/O.
DIP & FLATPACK PIN CONFIGURATION
I
I
4
CK/I VDD VDD I/O0 I/O1
3
2
1
28
27
26
I
5
25
I/O2
I
6
24
I/O3
I
7
23
I/O4
VSS
8
22
VSS
I
9
I
10
I
11
21
12
13
I
I
14
15
VSS VSS
16
I
17
I/O5
20
I/O6
19
I/O7
18
I/O9 I/O8
PIN NAMES
CK/I
Clock/Data Input
I
Data Input
I/O
Data Input/Output
VDD
Power
VSS
Ground
FUNCTION DESCRIPTION
2
CK/I
I
1
2
24
23
VDD
I/O0
I
3
22
I/O1
I
4
21
I/O2
I
I
5
6
20
19
I/O3
I/O4
I
7
18
I/O5
I
8
17
I/O6
I
I
9
10
16
15
I/O7
I/O8
I
VSS
11
14
I/O9
12
13
I
The UT22VP10 RAD PAL implements logic functions as sumof-products expressions in a one-time programmable-AND/
fixed-OR logic array. User-defined functions are created by
programming the connections of input signals into the array.
User-configurable output structures in the form of I/O macrocells further increase logic flexibility.
Table 1. Macrocell Configuration Table1, 2, 3
C2
C1
C0
Output Type
Polarity
Feedback
0
0
0
Registered
Active LOW
Registered
0
0
1
Registered
Active HIGH
Registered
X
1
0
Combinatorial
Active LOW
I/O
X
1
1
Combinatorial
Active HIGH
I/O
1
0
0
Registered
Active LOW
I/O
1
0
1
Registered
Active HIGH
I/O
Notes:
1. 0 equals programmed low or programmed.
2. 1 equals programmed high or unprogrammed.
3. X equals don’t care.
OVERVIEW
The UT22VP10 RAD PAL architecture (see figure 1) has 12 dedicated inputs and 10 I/Os to provide up to 22 inputs and 10
outputs for creating logic functions. At the core of the device
is a one-time programmable anti-fuse AND array that drives a
fixed OR array. With this structure, the UT22VP10 can implement up to 10 sum-of-products logic expressions.
Associated with each of the 10 OR functions is a macrocell
which is independently programmed to one of six different configurations. The one-time programmable macro cells allow
each I/O to create sequential or combinatorial logic functions
with either Active-High or Active-Low polarity.
LOGIC ARRAY
The one-time programmable AND array of the UT22VP10
RADPAL is formed by input lines intersecting product terms.
The input lines and product terms are used as follows:
44 input lines:
• 24 input lines carry the true and complement of the signals
applied to the input pins
• 20 lines carry the true and complement values of feedback
or input signals from the 10 I/Os
132 product terms:
• 120 product terms (arranged in 2 groups of 8, 10, 12, 14, and
16) used to form logic sums
• 10 output enable terms (one for each I/O)
• 1 global synchronous preset term
• 1 global asynchronous reset term
a Don’t Care state exists and that term will always be a logical
one.
PRODUCT TERMS
The UT22VP10 provides 120 product terms that drive the 10
OR functions. The 120 product terms connect to the outputs in
two groups of 8, 10, 12, 14, and 16 to form logical sums.
MACROCELL ARCHITECTURE
The output macrocell provides complete control over the architecture of each output. Configuring each output independently
permits users to tailor the configuration of the UT22VP10 to
meet design requirements.
Each I/O macrocell (see figure 2) consists of a D flip-flop and
two signal-select multiplexers. Three configuration select bits
controlling the multiplexers determine the configuration of
each UT22VP10 macrocell (see table 1). The configuration select bits determine output polarity, output type (registered or
combinatorial) and input feedback type (registered or I/O). See
figure 3 for equivalent circuits for the macrocell configurations.
OUTPUT FUNCTIONS
The signal from the OR array may be fed directly to the output
pin (combinatorial function) or latched in the D flip-flop (registered function). The D flip-flop latches data on the rising edge
of the clock. When the synchronous preset term is satisfied, the
Q output of the D flip-flop output will be set logical one at the
next rising edge of the clock input. Satisfying the asynchronous
clear term sets Q logical zero, regardless of the clock state. If
both terms are satisfied simultaneously, the clear will override
the preset.
At each input-line/product-term intersection there is an antifuse cell which determines whether or not there is a logical
connection at that intersection. A product term which is connected to both the true and complement of an input signal will
always be logical zero, and thus will not effect the OR function
that it drives. When there are no connections on a product term
3
OUTPUT
SELECT
MUX
AR
D
Q
CK
Q
C1
C0
SP
INPUT/
FEEDBACK
MUX
C1 C2
C1
C0
C2
Figure 2. Macrocell
OUTPUT POLARITY
BIDIRECTIONAL I/O
Each macrocell can be configured to implement Active-High
or Active-Low logic. Programmable polarity eliminates the
need for external inverters.
The feedback signal is taken from the I/O pin when the macrocell implements a combinatorial function (C1 = 1) or a registered function (C2 = 1, C 1 = 0). In this case, the pin can be used
as a dedicated input, a dedicated output, or a bidirectional I/O.
OUTPUT ENABLE
The output of each I/O macrocell can be enabled or disabled
under the control a programmable output enable product term.
The output signal is propagated to the I/O pin when the logical
conditions programmed on the output enable term are satisfied.
Otherwise, the output buffer is driven to the high-impedance
state.
POWER-ON RESET
The output enable term allows the I/O pin to function as a dedicated input, dedicated output, or bidirectional I/O. When every
connection is unprogrammed, the output enable product term
permanently enables the output buffer and yields a dedicated
output. If every connection is programmed, the enable term is
logically low and the I/O functions as a dedicated input.
ANTI-FUSE SECURITY
REGISTER FEEDBACK
The feedback signal to the AND array is taken from the Q output
when the I/O macrocell implements a registered function
(C2 = 0, C1 = 0).
4
To ease system initialization, all D flip-flops will power-up to
a reset condition and the Q output will be low. The actual output
of the UT22VP10 will depend on the programmed output polarity. The reset delay time is 5µs maximum. See the Power-up
Reset section for a more descriptive list of POR requirements.
The UT22VP10 provides a security bit that prevents unauthorized reading or copying of designs programmed into the device. The security bit is set by the PLD programmer at the conclusion of the programming cycle. Once the security bit is set
it is no longer possible to verify (read) or program the
UT22VP10. NOTE: UTMC does not recommend using the
UT22VP10 unless the security fuse has been programmed.
The security bit must be blown to ensure proper functionality of the UT22VP10.
AR
D
Q
CK
Q
SP
Registered Feedback, Registered, Active-Low Output (C2 = 0, C 1 = 0, C0 = 0)
AR
D
Q
CK
Q
SP
Registered Feedback, Registered, Active-High Output (C2 = 0, C1 = 0, C0 = 1)
I/O Feedback, Combinatorial, Active-Low Output (C 2 = X, C1 = 1, C0 = 0)
Figure 3. Macrocell Configuration (continued on next page)
5
I/O Feedback, Combinatorial, Active-High Output (C 2 = X, C 1 = 1, C 0 = 1)
AR
D
Q
CK
Q
SP
I/O Feedback, Registered, Active-Low Output (C 2 = 1, C 1 = 0, C 0 = 0)
AR
D
Q
CK
Q
SP
I/O Feedback, Registered, Active-High Output (C 2 = 1, C1 = 0, C 0 = 1)
Figure 3. Macrocell Configuration
6
ABSOLUTE MAXIMUM RATINGS 1
SYMBOL
PARAMETER
LIMIT
UNITS
VDD
Supply voltage
-0.3 to 7.0
V
VI/O2
Input voltage any pin
-0.3 to +7.0
V
TSTG
Storage Temperature range
-65 to +150
°C
TJ
Maximum junction temperature
+175
°C
TS
Lead temperature (soldering 10 seconds)
+300
°C
ΘJC
Thermal resistance junction to case
20
°C/W
II
DC input current
±10
mA
PD3
Maximum power dissipation
1.6
W
IO
Output sink current
12
mA
Notes:
1. Stresses outside the listed absolute maximum ratings may cause permanent damage to the device. This is a stress rating only, functional operation of the
device at these or any other conditions beyond limits indicated in the operational sections is not recommended. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
2. Minimum voltage is -0.6VDD which may undershoot to -2.0VDD for pulses of less than 20ns. Maximum output pin voltage is VDD +0.75VDD which may
overshoot to +7.0V DD for pulses of less than 20ns.
3. (ICC max + IOS) 5.5V.
RECOMMENDED OPERATING CONDITIONS
SYMBOL
PARAMETER
LIMIT
UNITS
VDD1
Supply voltage
4.5 to 5.5
V
VIN
Input voltage any pin
0 to VDD
V
TC
Temperature range
-55 to + 125
°C
Notes:
1. See page 12 for minimum V DD requirements at power-up.
7
DC ELECTRICAL CHARACTERISTICS 1, 7
(VDD2 = 5.0V ±10%; VSS = 0V3, -55°°C < TC < +125°°C)
SYMBOL
PARAMETER
CONDITION
MINIMUM
MAXIMUM
UNIT
VIL
Low-level input voltage
TTL
--
.8
V
VIH
High-level input voltage
TTL
2.2
--
V
VIL
Low-level input voltage
CMOS
--
.3*V DD
V
VIH
High-level input voltage
CMOS
.7*V DD
--
V
VOL
Low-level output voltage
IOL = 12.0mA, VDD = 4.5V (TTL)
.4
V
VOH
High-level output voltage
IOH = -12.0mA, V DD = 4.5V (TTL)
2.4
--
V
VOL
Low-level output voltage
IOL = 200µ
µA, VDD = 4.5V (CMOS)
--
VSS+0.05
V
VOH
High-level output voltage
IOH = -200µ
µA, VDD = 4.5V (CMOS)
VDD-0.05
--
V
IIN
Input leakage current
VIN = VDD and VSS
-10
10
µA
IOZ
Three-state output leakage
current
VO = VDD and VSS, VDD = 5.5V
-10
10
µA
IOS4,5
Short-circuit output current
VDD = 5.5V, V O = VDD
VDD = 5.5V, V O = 0V
-160
160
mA
CIN5,6
Input capacitance
ƒ=1MHz @0V
--
15
pF
CI/O5,6
Bidirectional capacitance
ƒ=1MHz @0V
--
15
pF
IDD5
Supply current: Output
VDD = 5.5V
three-state, worst-case pattern programmed,
ƒ=fMAX1
--
120
mA
IDDQ
Supply current:
Unprogrammed
--
25
mA
VDD = 5.5V
Notes:
1. All specifications valid for radiation dose < 1E6 rads(Si).
2. See page 12 for minimum V DD requirements at power-up.
3. Maximum allowable relative shift equals 50mV.
4. Duration not to exceed 1 second, one output at a time.
5. Tested initially and after any design or process changes that affect that parameter and, therefore, shall be guaranteed to the limit specified.
6. All pins not being tested are to be open.
7. CMOS levels only tested on CMOS devices. TTL levels only tested on TTL devices.
8
AC CHARACTERISTICS READ CYCLE (Post-Radiation) 1,2
(VDD3 = 5.0V ±10%; -55°C < T C < +125°C)
SYMBOL
tPD4,5,6
PARAMETER
22VP10-15.5
MIN
MAX
Input to output propagation delay
22VP10-20
MIN
MAX
22VP10-25
MIN
MAX
UNIT
15.5
20
25
ns
tEA4
Input to output enable delay
23
23
25
ns
tER4
Input to output disable delay
23
23
25
ns
tCO4,6
Clock to output delay
15
15
15
ns
tCO24
Clock to combinatorial output delay via internal
registered feedback
24
24
28
ns
tS4,6
Input or feedback setup time
15
15
18
ns
tH4,6
Input or feedback hold time
2
2
2
ns
External clock period (tCO + tS)
30
30
33
ns
tWH, WL4
Clock width, clock high time, clock low time
12
12
14
ns
fMAX14,6
External maximum frequency (1/(tCO + tS))
33
33
30
MHz
fMAX24,6
Data path maximum frequency (1/(tWH + tWL))
42
42
36
MHz
fMAX34,6
Internal feedback maximum frequency (1/(tCO + tCF))
32
32
32
MHz
tCF4
Register clock to feedback input
13
13
13
ns
tAW4
Asynchronous reset width
20
20
25
ns
tAR4
Asynchronous reset recovery time
20
20
25
ns
tAP4
Input to asynchronous reset
tP4
20
20
25
ns
tSPR4,6
Synchronous preset recovery time
20
20
25
ns
tPR4,6
Power up reset time
1.0
1.0
1.0
µs
Notes:
1. Post-radiation performance guaranteed at 25°C per MIL-STD-883 Method 1019 at 1.0E6 rads(Si).
2. Guaranteed by characterization.
3. See page 12 for minimum VDD requirements for power-up.
4. Tested initially and after any design or process changes that affect.
5. Device 22VP10-15 tested at -55°C, +25°C and +50°C. At 125°C, tested to 20ns limit.
6. Tested on Programmed Test Ring only.
9
INPUT OR
BIDIRECTIONAL
INPUT
INPUT OR
BIDIRECTIONAL
VT
VT
INPUT
tS
tPD
tH
CLOCK
COMBINATIONAL
OUTPUT
VT
VT
tCO
REGISTERED
OUTPUT
VT
tp
Registered Output
Combinatorial Output
tWH
INPUT OR
BIDIRECTIONAL
VT
INPUT
tER
VT
tEA
OUTPUT
VT
tWL
Clock Width
Combinatorial Output
(VOH - 0.5V, V OL + 0.5V)
tAW
INPUT ASSERTING
ASYNCHRONOUS
RESET
INPUT ASSERTING
SYNCHRONOUS
PRESET
VT
t AP
tS
CLOCK
REGISTERED
OUTPUT
VT
VT
REGISTERED
OUTPUT
Asynchronous Reset
Notes:
1. VT = 1.5V.
2. Input pulse amplitude 0V to 3.0V.
3. Input rise and fall times 3ns maximum.
10
tH
tSPR
VT
VT
tCO
tAR
CLOCK
VT
VT
Synchronous Preset
Figure 4. AC Electrical1,2,3
CLK
PRODUCT
TERMS
CLK
Q
D
PRODUCT
TERMS
REGISTER
Q
D
REGISTER
Q
Q
tCF 1
PRODUCT
TERMS
PRODUCT
TERMS
CLK
D
OUTPUT
OUTPUT
Q
REGISTER
Clock to Combinatorial Output (tCO2)
Note:
1. tCF defined as the propagation delay from Q to D register input.
fMAX3; Internal Feedback
1
tCO + tCF
Figure 5. Signal Paths
11
POWER-UP RESET
The power-up reset feature ensures that all flip-flops will be
reset to LOW after the device has been powered up. The output
state will depend on the programmed pattern. This feature is
valuable in simplifying state machine initialization. See figure
6 for a timing diagram. Due to the synchronous operation of the
power-up reset and the wide range of ways V DD can rise to its
steady state, the following five conditions are required to ensure
a valid power-up reset.
4. Following reset, the clock input must not be driven from
LOW to HIGH until all applicable input and feedback setup
times are met.
5. The power-up voltage must meet the minimum V DD requirements described by the following device dependent and temperature dependent equations:
SMD Device types 01, 02, 03, 04, 08
VDD =4.61V -0.0090*(oC)
SMD Device types 05, 06, 07
VDD =4.41 -0.0090* (oC)
1. The voltage supplied to the V DD pin(s) must be equal to 0V
prior to the intended power-up sequence.
2. The voltage on V DD must rise from 0V to 1V at a rate of
0.1V/s or faster.
3. The V DD rise must be continuously increasing with respect
to time, through 3V, and monotonic thereafter.
VDD
CMOS and TTL
CMOS
Note: The minimum VDD requirement above is not applicable
if the UT22VP10 application is purely combinatorial (i.e. no
registered outputs).
VDD
VDD min
tPR
REGISTERED
ACTIVE-LOW
OUTPUT
tS
CLOCK
tWL
Figure 6. Power-Up Reset Waveform
RADIATION HARDNESS
The UT22VP10 RADPAL incorporates special design and layout features which allow operation in high-level radiation environments.
UTMC has developed special low-temperature processing techniques designed to enhance the total-dose radiation hardness of both
the gate oxide and the field oxide while maintaining the circuit density and reliability. For transient radiation hardness and latchup
immunity, UTMC builds radiation-hardened products on epitaxial wafers using an advanced twin-tub CMOS process.
RADIATION HARDNESS DESIGN SPECIFICATIONS1
PARAMETER
CONDITION
MINIMUM
UNIT
+25°C per MIL-STD-883 Method 1019
1.0E6
rads(Si)
LET Threshold
-55°C to +125°C
50
MeV-cm2/mg
Neutron Fluence
1MeV equivalent
1.0E14
n/cm2
Total Dose
Note:
1. The RADPAL will not latchup during radiation exposure under recommended operating conditions.
12
A
0.166
0.110
0.310 ±0.010
E
0.295 ±0.010
14
-C-
4
Q
0.060
0.015
0.010 M C
12
24-LD
6038
b2
0.050 TYP.
11
e
0.100
13
b
0.018 ±0.002
1.100
D
1.200 ± 0.015
5
23
S1
0.005
MIN. TYP.
2
PIN 1 INDEX
GEOMETRY OPT.
24
0.50 R.
(AT SEATING PLANE)
L
0.200
0.125
S2
0.005 MIN.
TOP VIEW
L1
0.150 MIN.
FRONT VIEW
SEE DETAIL A
eA
0.300±0.010
0.025 MAX.
LEAD
CERAMIC
BODY
BRAZE FILLET
0.040 MAX.
DETAIL A
4
C
0.010 +0 .002
- 0.001
(NO SCALE)
SIDE VIEW
Notes:
1. Package material: Opaque ceramic.
2. All exposed metalized areas are finished per MIL-PRF-38535.
3. Letter designations are for cross-reference to MIL-STD-1835.
4. For solder coated leads, increase maximum limit by 0.003 inch as measured at the center
of the flat.
5. Numbering and lettering on the ceramic are not subject to visual marking criteria.
Figure 7. 24-Pin 100-mil Center DIP (0.300 x 1.2)
13
k
0.015
0.008
k
0.015
0.008
PIN NO. 1 ID.
6
5
0.036 M H A-B
S D S
-A-
D
0.640 MAX.
e
26 PLACES
0.05
-B-
S1
4 PLACES
0.000 MIN.
b
0.022
0.015
E1
0.450 MAX.
28 PLACES
0.010
M H
A
0.115
0.045
A-B S D S
5
7
0.420
0.350
C
0.006
7 0.004
-D-
5
0.040
-CQ
0.045
0.026
-HL
0.370 TYP.
0.250
E2
0.180
MIN.
E3
0.030 MIN. TYP.
Notes:
1. All exposed metalized areas are gold plated over electroplated nickel per MIL-PRF-38535.
2. The lid is electrically connected to VSS .
3. Lead finishes are in accordance with MIL-PRF-38535.
4. Dimension letters refer to MIL-STD-1835.
5. Lead position and coplanarity are not measured.
6. ID mark symbol is vendor option.
7. For solder coated leads, increase maximum limit by 0.003 inch as measured at the center of the flat.
Figure 8. 24-Lead Flatpack (0.45 x 0.64)
14
D
O.450 ±0.007 SQ.
A
0.100 MAX.
-A-
A1
0.065 ±0.007
1 28
SEE DETAIL
A. PIN 1 ID
A
0.250
MIN. TYP.
-B-
E
0.450 REF.
-C-
e
0.050
A
C
0.008 ±0.001
4
b
0.018±0.002
TOP VIEW
0.030
M
C
0.009
M
C
A M B M
0.980 SQ. REF.
0.040
4
SIDE VIEW
SQUARE CORNERS.
THIS PAD ONLY.
DETAIL A
PIN 1 ID
7050
BACK SIDE
PIN 1 ID MARK
PACKAGE PART
NUMBER
5
VIEW A-A
Notes:
1. All exposed metalized areas are gold plated over
electroplated nickel per MIL-PRF-38535.
2. Lead finishes are in accordance with MIL-PRF-38535.
3. Dimension letters refer to MIL-STD-1835.
4. Lead position and coplanarity are not measured.
5. Mark is not subject to visual marking criteria.
6. Mark is on lid and its symbol is vendor option.
7. For solder coated leads, increase maximum limit by
0.003 inch as measured at the center of the flat.
Figure 9. 28-Lead Quad-Flatpack (.45 x .45)
15
ORDERING INFORMATION
UT22VP10 Radiation Hardened PAL: SMD
5962
* 94754 *
*
*
*
Lead Finish:
(A) = Solder
(C) = Gold
(X) = Optional
Case Outline:
(L) = 24-lead DIP
(X) = 24-lead pin Flatpack
(Y) = 28-lead pin Quad Flatpack
Class Designator:
(Q) = Class Q
(V) = Class V
Device Type
(01) = 25ns prop delay, CMOS I/O
(02) = 25ns prop delay, TTL I/O
(03) = 20ns prop delay, CMOS I/O
(04) = 20ns prop delay, TTL I/O
(05) = 25ns prop delay, CMOS I/O
(06) = 20ns prop delay, CMOS I/O
(07) = 15.5ns prop delay, CMOS I/O
(08) = 15.5ns prop delay, TTL I/O
Drawing Number: 94754
Total Dose:
(H) = 1E6 rads(Si)
(G) = 5E5 rads(Si)
(F) = 3E5 rads(Si)
(R) = 1E5 rads(Si)
Federal Stock Class Designator: No options
Notes:
1. Lead finish (A, C, or X) must be specified.
2. If an “X” is specified when ordering, part marking will match the lead finish and will be either “A” (solder) or “C” (gold).
3. Total dose radiation must be specified when ordering. QML Q and QML V not available without radiation hardening.
4. (01-04, 08) is VDD (min) = -0.009*(o C)+4.61.
5. (05-07) is VDD(min) = -0.009*(o C)+4.41.
6. (07, 08) is tested at -55°C, +25°C, and +50°C to 15.5ns for t PD . At +125°C tested to 20ns limit for tPD.
16
UT22VP10 Radiation Hardened PAL
UT22VP10 *
*
*
*
*
Radiation:
= None
Lead Finish:
(A) = Solder
(C) = Gold
(X) = Optional
Screening:
(C) = Military Temperature
(P) = Prototype
Package Type:
(P) = 24-pin DIP
(U) = 24-pin Flatpack
(W) = 28-pin Quad Flatpack
Device Type Modifier:
C-20 =
CMOS I/O: 20ns propagation delay
C-25 =
CMOS I/O: 25ns propagation delay
E-15 =
CMOS I/O: 15.5ns propagation delay
E-20 =
CMOS I/O: 20ns propagation delay
E-25 =
CMOS I/O: 25ns propagation delay
T-15 =
TTL I/O: 15.5ns propagation delay
T-20 =
TTL I/O: 20ns propagation delay
T-25 =
TTL I/O: 25ns propagation delay
Notes:
1. Lead finish (A, C, or X) must be specified.
2. If an “X” is specified when ordering, part marking will match the lead finish and will be either “A” (solder) or “C” (gold).
3. Military Temperature range flow per UTMC’s manufacturing flows document. Devices have 48 hours of burn-in and are tested at -55°C,
room temperature, and 125°C. Radiation characteristics are neither tested nor guaranteed and may not be specified.
4. Prototype flow per UTMC Manufacturing Flows Technical Description. Devices have prototype assembly and are tested at 25°C only.
Radiation is neither tested nor guaranteed.
5. (T-15, C-25, T-25, C-20, T-20) is V DD(min) = -0.009*(o C)+4.61.
6. (E-15, E-20 and E-25) is VDD (min) = -0.009*(oC)+4.41.
7. (E-15 and T-15) is tested at at -55°C, +25°C, and +50°C to 15.5ns for t PD . At +125°C tested to 20ns limit for tPD.
17
APPENDIX A
UT22VP10 RADPAL Power-On-Reset Ramp Rate Anomaly
UTMC has identified the following anomaly in the power up behavior of the UT22VP10
RADPAL (RC01 and RC02).
Anomaly:
The anomaly was observed for a power-up application where a residual voltage
between 200 and 500 mV was supplied to the VDD pin(s) of the RADPAL for several milliseconds prior to the 5V power supply ramping to 5 volts. Consequently,
the RADPAL enters a “test” mode (as opposed to a “user” mode). In the test mode,
all output buffers are placed and remain in a high impedance state and the RADPAL
does not function as programmed.
Through HSPICE simulation and laboratory tests, UTMC has found there exists a
window in which a residual voltage of a few hundred millivolts on the VDD pin(s)
prevents the RADPAL from generating an internal POR signal for its security circuit. The lack of a reset signal allows the security circuit to power up in either the
“user” or the “test” mode of operation. Entering the “test” mode prevents the
RADPAL from functioning as programmed. The anomaly is seen at room temperature and above, where a residual voltage above 200mV is applied to VDD before it
transitions to VDD minimum. The anomaly is not seen when the application of
power to the RADPAL starts at zero volts and transitions monotonically to VDD
minimum and the slew rate is greater than 0.1V/S.
The anomaly is not wafer lot dependent and affects all date code shipped.
Solution:
The UT22VP10 RADPAL is susceptible to this POR anomaly whenever residual
voltages of between 200mV and 500mV are on the VDD pin(s) prior to the application of the 5V power supply.
In order to avoid powering up the UT22VP10 RADPAL into a test mode,
the following specifications must be met:
The application of voltages on the VDD pin(s) of the RADPAL must start
at 0V and reach 1V at a rate of 0.1V/s or faster.
2) The power-up voltage must be continuously increasing with respect to
time, through 3V, and monotonic thereafter.
3) No voltage can be applied to VDD prior to the intended power-up
sequence.
1)
3/16/98
Page 1 of 2
An alternative or additional method to guarantee that the UT22VP10 RADPAL
functions in the user mode of operation is to implement he following fix into the
board level design:
1) Apply one of the opcodes shown in Table 1 to the corresponding inputs
of the RADPAL. Notice that the Clock and I9 inputs must have a logic
“1” applied during the application of a valid opcode.
Table 1: Valid Power-Up Opcodes
Mode of
Operation
Power-Up
Opcode
(HEX)1
RADPAL Input Pins
I
9
I
8
I
7
I
6
I
5
I
4
I
3
I
2
I
1
Clk/I
0
DC
1
1
1
0
1
1
1
0
0
1
2
DE
1
1
1
0
1
1
1
1
0
1
3
DF
1
1
1
0
1
1
1
1
1
1
4
E0
1
1
1
1
0
0
0
0
0
1
5
E1
1
1
1
1
0
0
0
0
1
1
6
E2
1
1
1
1
0
0
0
1
0
1
1. The Hexadecimal power-up opcode refers to the RADPAL inputs I8 - I1.
Notes:
2) Apply one of the opcodes from Table 1 for at least 100ns anytime after
VDD is within 5V + 10% to ensure all test mode latches are cleared.
Figure 1 shows the opcode timing diagram.
Opcode Valid
VDD
Opcode
5V + 10%
100ns Min.
VALID
I9
CLK/I
Figure 1. Opcode Timing
Applying one of the opcodes from Table 1 enables the programmed security fuse
to reset the internal test latch, forcing the UT22VP10 RADPAL into the user mode
of operation.
3/16/98
Page 2 of 2
APPENDIX B
RADPALTM Power-On-Reset Performance at Cold Temperatures
UTMC has identified the following anomaly in the power up behavior of the UT22VP10
RADPALTM .
Anomaly:
The anomaly was observed for power-up applications where the voltage applied to the VDD
pin(s) of the RADPALTM was within the specified voltage tolerance of 5V +10%, yet, was
not sufficient to turn off the internal reset pulse at cold temperature. Consequently, all programmed macro-cells would remain in reset until the power supply reached a minimum
voltage.
UTMC has characterized this anomaly through HSPICE simulation, and laboratory testing.
The characterization data shows that the minimum power-up voltage dependency on temperature fits a linear curve. Additionally, UTMC has identified distinct wafer lots that contain die with better cold temperature performance than the original supply of die. The wafer
characterization is performed in the following manner:
1) Each wafer is evaluated for the transistor threshold voltages.
2) Each wafer showing satisfactory threshold voltages is then mapped to find die that have
a high probability of representing the typical threshold voltage found across the wafer.
3) These selected die are then packaged, programmed, and characterized.
4) The test process ramps the voltage on the VDD pin(s) of the RADPALTM and measures
the minimum voltage required for the reset signal to turn off.
5) These voltage measurements are taken in five degree increments in temperature through
-55oC.
6) The characterization data is then plotted to verify that the samples fit the specified VDD
to temperature curve.
As a result of the characterization performed, UTMC has developed the following equations
that UT22VP10 RADPALTM device types will satisfy:
1) SMD device types 01, 02, 03, 04 (CMOS and TTL) satisfy
VDD = 4.61V - 0.0090 * (Temperature oC)
2) SMD device types 05, 06 (CMOS only) satisfy
VDD = 4.41V -0.0090 * (Temperature oC)
1
1/23/98
Solution:
To insure that the UT22VP10 RADPALTM will power up in a usable mode, the following
conditions must be met:
1) The voltage supplied to the VDD pin(s) must be equal to 0V prior to the intended
power-up sequence.
2) The voltage on VDD must rise from 0V to 1V at a rate of 0.1V/s or faster.
3) The VDD rise must be continuously increasing with respect to time, through 3V, and
monotonic thereafter.
4) Following reset, the clock input must not be driven from LOW to HIGH until all
applicable input and feedback setup times are met.
5) The power-up voltage must meet the minimum VDD requirements described by the
above device dependent equations. The customer can procure the specific device types
meeting the respective equation via the SMD#5962-94754.
NOTE: The minimum VDD requirement above is not applicable if the UT22VP10 application is purely
combinatorial (i.e. no outputs are registered)
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