ANACHIP PEEL18LV8ZI-15

PEEL™ 18LV8Z-15 / I-15
CMOS Programmable Electrically Erasable Logic Device
Features
•
Low Voltage, Ultra Low Power Operation
- Vcc = 2.7 to 3.6 V
- Icc = 5 µA (typical) at standby
- Icc = 1.5 mA (typical) at 1 MHz
- Meets JEDEC LV Interface Spec (JEDSD8-A)
- 5 Volts tolerant inputs and I/O’s
•
CMOS Electrically Erasable Technology
- Superior factory testing
- Reprogrammable in plastic package
- Reduces retrofit and development costs
•
Application Versatility
- Replaces random logic
- Super set of standard PLDs
- Pin and JEDEC compatible with 16V8
- Ideal for battery powered systems
- Replaces expensive oscillators
•
Architectural Flexibility
- Enhanced architecture fits in more logic
- 113 product terms x 36 input AND array
- 10 inputs and 8 I/O pins
- 12 possible macrocell configurations
- Asynchronous clear, Synchronous preset
- Independent output enables
- Programmable clock; pin 1 or p-term
- Programmable clock polarity
- 20 Pin DIP/SOIC/TSSOP and PLCC
- Schmitt triggers on clock and data inputs
•
Schmitt Trigger Inputs
- Eliminates external Schmitt trigger devices
- Ideal for encoder designs
General Description
The differences between the PEEL18LV8Z and
PEEL18CV8 include the addition of programmable clock
polarity, p-term clock, and Schmitt trigger input buffers on
all inputs, including the clock. Schmitt trigger inputs allow
direct input of slow or noisy signals.
The PEEL18LV8Z is a Programmable Electrically Erasable
Logic (PEEL) SPLD (Simple Programmable Logic Device)
that operates over the supply voltage range of 2.7V-3.6V
and features ultra-low, automatic "zero" power-down
operation. The PEEL18LV8Z is logically and functionally
similar to Anachip's 5V PEEL18CV8 and PEEL18CV8Z.
The "zero power" (25 µA max. Icc) power-down mode
makes the PEEL18LV8Z ideal for a broad range of batterypowered portable equipment applications, from hand-held
meters to PCMCIA modems. EE-reprogrammability
provides both the convenience of fast reprogramming for
product development and quick product personalization in
manufacturing, including Engineering Change Orders.
I/CLK1
1
20
V CC
I
2
19
I/O
I/CLK1
I
1
2
20
19
V CC
I/O
I
3
18
I/O
I
3
18
I/O
I
4
17
I/O
I
4
17
I/O
I
5
16
I/O
I
6
15
I/O
I
I
5
6
16
15
I/O
I/O
I
7
I
7
14
I/O
13
8
13
I/O
I
I
8
I
9
12
I/O
GND
9
10
12
11
I/O
I/O
I
10
11
I
GND
14
I/O
DIP
Like the PEEL18CV8, the PEEL18LV8Z is a logical
superset of the industry standard PAL16V8 SPLD. The
PEEL18LV8Z provides additional architectural features that
allow more logic to be incorporated into the design.
Anachip's JEDEC file translator allows easy conversion of
existing 20 pin PLD designs to the PEEL18LV8Z
architecture without the need for redesign. The
PEEL18LV8Z architecture allows it to replace over twenty
standard 20-pin DIP, SOIC, TSSOP and PLCC packages.
C LK MU X (Optional)
ª
I
I/O
I/O
2
VCC
I/O
3
I/CLK1
TSSOP
1 20 19
I
4
18
I/O
I
5
17
I/O
I
6
16
I/O
I
7
15
I/O
I
8
14
I/O
9 10 11 12 13
I/CLK1
1
20
I
2
I
I
3
4
19
18
I/O
17
I/O
I
5
16
I/O
I
I
6
15
14
I/O
I/O
I
7
8
13
I/O
I
9
12
10
11
I/O
I
I/O
I/O
I
I
GND
GND
PLCC-J
V CC
I/O
SOIC
Figure 2 - Block Diagram
Figure 1 - Pin Configuration
This datasheet contains new product information. Anachip Corp. reserves the rights to modify the product specification without notice. No liability is assumed as a result of the use of this product. No rights
under any patent accompany the sale of the product.
Rev. 1.0 Dec 16, 2004
1/10
(O p tio n a l)
I/ C LK*
I*
I*
I*
I*
I*
I*
I*
I*
* Schm itt
Trigger
Inputs
I*
Figure 3 - PEEL18LV8Z Logic Array Diagram
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Function Description
The PEEL18LV8Z implements logic functions as sum-ofproducts expressions in a programmable-AND/fixed-OR
logic array. Programming the connections of input signals
into the array creates user-defined functions. Userconfigurable output structures in the form of I/O macrocells
further increase logic flexibility.
Architecture Overview
The PEEL18LV8Z architecture is illustrated in the block
diagram of Figure 14. Ten dedicated inputs and 8 I/Os
provide up to 18 inputs and 8 outputs for creation of logic
functions. At the core of the device is a programmable
electrically erasable AND array that drives a fixed OR array.
With this structure, the PEEL18LV8Z can implement up to
8 sum-of-products logic expressions.
Associated with each of the 8 OR functions is an I/O
macrocell that can be independently programmed to one of
12 different configurations. The programmable macrocells
allow each I/O to be used to create sequential or
combinatorial logic functions of active-high or active-low
polarity, while providing three different feedback paths into
the AND array.
The PEEL18LV8Z provides 113 product terms to drive the
8 OR functions. These product terms are distributed
among the outputs in groups of 8, 10, 12, 14, and 16 to
form logical sums (see Figure 15). This distribution allows
optimum use of the device resources.
The unique twelve-configuration output macrocell provides
complete control over the architecture of each output. The
ability to configure each output independently lets you to
tailor the configuration of the PEEL18LV8Z to the precise
requirements of your design.
The programmable AND array of the PEEL18LV8Z (shown
in Figure 15) is formed by input lines intersecting product
terms. The input lines and product terms are used as
follows:
•
Variable Product Term Distribution
Programmable I/O Macrocell
AND/OR Logic Array
•
When programming the PEEL18LV8Z, the device
programmer first performs a bulk erase to remove the
previous pattern. The erase cycle opens every logical
connection in the array. The device is configured to
perform the user-defined function by programming selected
connections in the AND array. (Note that PEEL device
programmers automatically program all of the connections
on unused product terms so that they will have no effect on
the output function).
Macrocell Architecture
Each I/O macrocell, as shown in Figure 4, consists of a Dtype flip-flop and two signal-select multiplexers. The four
EEPROM bits controlling these multiplexers determine the
configuration of each macrocell. These bits determine
output polarity, output type (registered or non-registered)
and input-feedback path (bidirectional I/O, combinatorial
feedback). Refer to Table 1 for details.
36 Input Lines:
- 20 input lines carry the true and complement of
the signals applied to the 10 input pins
- 16 additional lines carry the true and complement
values of feedback or input signals from the 8
I/Os
Equivalent circuits for the twelve macrocell configurations
are illustrated in Figure 5. In addition to emulating the four
PAL-type output structures (configurations 3, 4, 9, and 10),
the macrocell provides eight additional configurations.
When creating a PEEL device design, the desired
macrocell configuration is generally specified explicitly in
the design file. When the design is assembled or compiled,
the macrocell configuration bits are defined in the last lines
of the JEDEC programming file.
113 product terms:
- 102 product terms are used to form sum of
product functions
- 8 output enable terms (one for each I/O)
- 1 global synchronous preset term
- 1 global asynchronous clear term
- 1 programmable clock term
At each input-line/product-term intersection, there is an
EEPROM memory cell that determines whether or not
there is a logical connection at that intersection. Each
product term is essentially a 36-input AND gate. A product
term that is connected to both the true and complement of
an input signal will always be FALSE and thus will not
affect the OR function that it drives. When all the
connections on a product term are opened, a "don't care"
state exists and that term will always be TRUE.
Output Type
The signal from the OR array can be fed directly to the
output pin (combinatorial function) or latched in the D-type
flip-flop (registered function). The D-type flip-flop latches
data on the rising edge of the clock and is controlled by the
global preset and clear terms. When the synchronous
preset term is satisfied, the Q output of the register is set
HIGH at the next rising edge of the clock input. Satisfying
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the asynchronous clear sets Q LOW, regardless of the
clock state. If both terms are satisfied simultaneously, the
clear will override the preset.
Combinatorial Feedback
The signal-select multiplexer gives the macrocell the ability
to feedback the output of the OR gate, bypassing the
output buffer, regardless of whether the output function is
registered or combinatorial. This feature allows the creation
of asynchronous latches, even when the output must be
disabled. (Refer to configurations 5, 6, 7, and 8 in Figure 5.)
Output Polarity
Each macrocell can be configured to implement active-high
or active-low logic. Programmable polarity eliminates the
need for external inverters.
Registered Feedback
Output Enable
Feedback also can be taken from the register, regardless
of whether the output function is programmed to be
combinatorial or registered. When implementing a
combinatorial output function, registered feedback allows
for the internal latching of states without giving up the use
of the external output.
The output of each I/O macrocell can be enabled or
disabled under the control of its associated programmable
output enable product term. When the logical conditions
programmed on the output enable term are satisfied, the
output signal is propagated to the I/O pin. Otherwise, the
output buffer is switched into the high-impedance state.
Programmable Clock Options
Under the control of the output enable term, the I/O pin can
function as a dedicated input, a dedicated output, or a bidirectional I/O. Opening every connection on the output
enable term will permanently enable the output buffer and
yield a dedicated output. Conversely, if every connection is
intact, the enable term will always be logically false and the
I/O will function as a dedicated input.
A unique feature of the PEEL18LV8Z is a programmable
clock multiplexer that allows the user to select true or
complement forms of either input pin or product-term clock
sources.
Operates in both 3 Volt and 3.3 Volt Systems
The PEEL18LV8Z macrocell also provides control over the
feedback path. The input/feedback signal associated with
each I/O macrocell can be obtained from three different
locations; from the I/O input pin, from the Q output of the
flip-flop (registered feedback), or directly from the OR gate
(combinatorial feedback).
The PEEL18LV8Z is designed to operate with a V CC range
of 2.7 to 3.6 Volts D.C. This allows operation in both 3 Volt
10% (battery operated) and 3.3 Volt 10% (power supply
operated) systems. The propagation delay t PD is 5 ns
slower at the lower voltage, but this is typically not an issue
in battery-operated systems (see - A.C. Electrical
CharacteristicsTable 1 - Absolute Maximum Ratings- A.C.
Electrical Characteristics).
Bi-directional I/O
Schmitt Trigger Inputs
Input/Feedback Select
The PEEL18LV8Z has Schmitt trigger input buffers on all
inputs, including the clock. Schmitt trigger inputs allow
direct input of slow signals such as biomedical and sine
waves or clocks. They are also useful in cleaning up noisy
signals. This makes the PEEL18LV8Z especially desirable
in portable applications where the environment is less
predictable.
The input/feedback signal is taken from the I/O pin when
using the pin as a dedicated input or as a bi-directional I/O.
(Note that it is possible to create a registered output
function with a bi-directional I/O, refer to Figure 4).
Zero Power Feature
The CMOS PEEL18LV8Z features "Zero-Power" standby
operation for ultra-low power consumption. With the "ZeroPower" feature, transition-detection circuitry monitors the
inputs, I/Os (including CLK) and feedbacks. If these signals
do not change for a period of time greater than
approximately three t PD 's, the outputs are latched in their
current state and the device automatically powers down.
When the next signal transition is detected, the device will
"wake up" for active operation until the signals stop
Figure 4 - PEEL18LV8Z I/O Macro cell
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switching long enough to trigger the next power-down.
(Note that the tPD is approximately 5 ns. slower on the first
transition from sleep mode.)
When the PEEL18LV8Z is powered up, a built-in feature
holds the outputs in tri-state until Vcc reaches 2.2V. This
prevents output transitions during power-up.
As a result of the "Zero-Power" feature, significant power
savings can be realized for combinatorial or sequential
operations when the inputs or clock change at a modest
rate. See Figure 6.
Figure 5 - Equivalent Circuits for the twelve configurations of the PEEL18LV8Z I/O Macrocell
Configuration
#
A
B
C
D
1
2
3
4
5
6
7
8
9
10
11
12
0
1
0
1
0
1
0
1
0
1
0
1
0
0
1
1
0
0
1
1
0
0
1
1
1
1
0
0
1
1
1
1
0
0
1
1
0
0
0
0
1
1
1
1
0
0
0
0
Input/Feedback Select
Output Select
Register
Bi-directional I/O
Combinatorial
Register
Combinatorial Feedback
Combinatorial
Register
Register Feedback
Combinatorial
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Active Low
Active High
Active Low
Active High
Active Low
Active High
Active Low
Active High
Active Low
Active High
Active Low
Active High
Rev. 1.0 Dec 16, 2004
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programmed. Once the security bit is set it is impossible to
verify (read) or program the PEEL until the entire device
has first been erased with the bulk-erase function.
100
10
Signature Word
ICC
in
mA
The signature word feature allows a 64-bit code to be
programmed into the PEEL18LV8Z if the software option is
used. The code can be read back even after the security
bit has been set. The signature word can be used to
identify the pattern programmed into the device or to
record the design revision, etc.
1
0.1
0.01
0.01
Programming Support
0.1
1
10
100
Anachip's JEDEC file translator allows easy conversion of
existing 20 pin PLD designs to the PEEL18LV8Z, without
the need for redesign. Anachip also offers (for free) its
proprietary PLACE software, an easy-to-use entry level
PC-based software development system.
Frequency in MHz
Figure 6 - Typical ICC vs. Input Clock Frequency for
the 18LV8Z
Design Security
Programming support includes all the popular third party
programmers such as BP Microsystems, System General,
Logic
Devices
and
numerous
others.
The PEEL18LV8Z provides a special EEPROM security bit
that prevents unauthorized reading or copying of designs
programmed into the device. The PLD programmer sets
the security bit, either at the conclusion of the programming
cycle or as a separate step, after the device has been
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This device has been designed and tested for the specified
operating ranges. Improper operation outside of these
levels is not guaranteed. Exposure to absolute maximum
ratings may cause permanent damage.
Table 1 - Absolute Maximum Ratings
Symbol
VCC
Parameter
Conditions
Supply Voltage
VI , VO
IO
Relative to Ground
Voltage Applied to Any Pin
2
Output Current
Relative to Ground
Rating
Unit
-0.5 to + 6.0
V
-0.5 to 5.5
V
± 25
mA
-65 to +150
°C
+300
°C
1
Per Pin (I OL , I OH )
TST
Storage Temperature
TLT
Lead Temperature
Soldering 10 Seconds
Table 2 - Operating Range
Symbol
Parameter
3
Vcc
Supply Voltage
TA
Ambient Temperature
TRVCC
Conditions
Min
Max
Unit
Commercial / Industrial
2.7
3.6
V
Commercial
Industrial
See Note 4
0
-40
+70
+85
250
°C
VCC Rise Time
ms
Table 3 - D. C. Electrical Characteristics Over the operating range (unless otherwise specified)
Symbol
VOH
VOHC
VOL
VOLC
Parameter
Conditions
Min
Max
Unit
Output HIGH Voltage - TTL
VCC = Min, IOH = -2.0 mA
VCC - 0.5
V
Output HIGH Voltage - CMOS
VCC = Min, IOH = -10 A
VCC - 0.3
V
Output LOW Voltage - TTL
VCC = Min, IOL = 8.0 mA
0.4
V
Output LOW Voltage - CMOS
VCC = Min, IOL = 10 A
0.15
V
Input HIGH Voltage
VCC = 3.3 V
2.0
5.5
V
VIL
Input LOW Voltage
VCC = 3.3 V
-0.3
0.8
VH
Input Voltage Hysteresis
VIH
Input Leakage Current
IIN
I/O Leakage Current
0.2
VCC = Max, GND ≤ VIN ≤ VCC, I/O = High Z
+/- 1
µA
VCC = Min, GND ≤ VIN ≤ 5.5V, I/O = High Z
25
µA
VCC = Max, GND ≤ VIN ≤ VCC, I/O = High Z
+/- 1
µA
500
µA
VCC = Min, GND ≤ VIN ≤ 5.5V, I/O = High Z
5
5 (typ)
25
µA
5
1.5 (typ)
3
mA
6
pF
12
pF
ICCS
VCC Current, Standby
VIN = 0V or VCC, All Outputs disabled
11
VCC Current, f=1MHz
VIN = 0V or VCC, All Outputs disabled
ICC
8
Input Capacitance
CIN
8
COUT
Output Capacitance
V
V
TA = 25°C, VCC = Max @ f = 1 MHz
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Table 4 - A.C. Electrical Characteristics
Over the operating range9
Symbol
-15/I-15
3V±10% 3.3V±10%
Min Max Min Max
Parameter
6
tPD
Input to non-registered output in continuous mode
13
Units
20
15
ns
6
7
20
15
ns
6
7
20
15
ns
tOE
Input to output enable
tOD
Input to output disable
tCO1
Clock to Output
17
12
ns
tCO2
30
25
ns
tCF
Clock to comb output delay via internal registered
feedback
Clock to Feedback
tSC
Input or feedback setup to clock
tHC
Input hold after clock
13
6
6
tCL, tCH
tCP
Clock low time, clock high time
9
Min clock period Ext (tSC + tCO1 )
fMAX1
Internal feedback 1/ (tSC + tCF)
fMAX2
External Feedback (1/ tCP)
fMAX3
12
12
No Feedback 1/ (tCL + tCH)
12
8
ns
17
12
ns
0
0
ns
15
10
ns
32
24
ns
33.3
50
MHz
31.25
41.67
MHz
33.3
50
MHz
20
15
ns
tAW
Asynchronous Reset Pulse Width
tAP
Input to Asynchronous Reset
20
15
ns
tAR
Asynchronous Reset recovery time
20
15
ns
5
5
µs
tRESET
Power-on reset time for registers in clear state
14
Inputs I/O,
Registered Feedback,
Synchronous Preset
Clock
Asynchronous
Reset
Registered
O utputs
Combinatorial
O utputs
Figure 7 - Switching Waveforms
Notes:
1.
2.
3.
4.
5.
6.
7.
Minimum DC input is -0.5V, however, inputs may undershoot to
-2.0V for periods less than 20 ns.
VI and VO are not specified for program / verify operation.
The Supply Voltage range of 2.7 to 3.6V was chosen to allow
this part to be used in both 3V ±10% and 3.3V ±10%
applications.
Test Points for Clock and VCC in tR and tF are referenced at
the 10% and 90% levels.
I/O pins are 0V and VCC .
"Input" refers to an input pin signal.
tOE is measured from input transition to V REF± 0.1V, TOD is
measured from input transition to VOH -0.1V or VOL +0.1V;
VREF =VL.
8.
9.
10.
11.
12.
13.
14.
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Capacitances are tested on a sample basis.
Test conditions assume: signal transition times of 3ns or less
from the 10% and 90% points, timing reference levels of 1.5V
(Unless otherwise specified).
Test one output at a time for duration of less than 1 second.
ICC for a typical application: This parameter is tested with the
device programmed as an 8-bit Counter.
Parameters are not 100% tested. Specifications are based on
initial characterization and are tested after any design process
modification that might affect operational frequency.
tPD , tOE , tOD , tCO , tSC , and tAP are approximately 5 ns.
slower on the first transaction from sleep mode.
All inputs at GND.
Rev. 1.0 Dec 16, 2004
8/10
3.15V
Standard
Load
VL
Thevenin
Equivalent
R1
RL
Output
Output
CL
CL
R2
Figure 8 - PEEL™ Device and Array Test Loads
Technology
R1
R2
RL
VL
CL
CMOS
284 kΩ
258 kΩ
113 kΩ
1.275V
33 pF
TTL
308 Ω
433 Ω
180 Ω
1.840V
33 pF
Ordering Information
Part Number
Speed
Temperature
Package
PEEL18LV8ZP-15 (L)
15ns
Commercial
20-pin Plastic DIP
PEEL18LV8ZPI-15 (L)
15ns
Industrial
20-pin Plastic DIP
PEEL18LV8ZJ-15 (L)
15ns
Commercial
20-pin PLCC
PEEL18LV8ZJI-15 (L)
15ns
Industrial
20-pin PLCC
PEEL18LV8ZS-15 (L)
15ns
Commercial
20-pin SOIC
PEEL18LV8ZSI-15 (L)
15ns
Industrial
20-pin SOIC
PEEL18LV8ZT-15 (L)
15ns
Commercial
20-pin TSSOP
PEEL18LV8ZTI-15 (L)
15ns
Industrial
20-pin TSSOP
Part Number
Device
Suffix
PEELTM18LV8Z PI-15X
Lead Free
Package
Speed
P = 20-pin Plastic 300mil DIP
J = 20-pin Plastic (J) Leaded Chip Carrier (PLCC)
S = 20-pin SOIC 300 mil Gullwing
T = 20-pin TSSOP 170 mil
Blank : Normal
L : Lead Free Package
-15 = 15ns tpd
Temperature Range
(Blank) = Commercial 0 to +70oC
I = Industrial -40 to +85oC
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Corporate Office
Email:
[email protected]
780 Montague Expressway, #201
San Jose, CA 95131
TEL (408) 321-9600
FAX (408) 321-9696
Website:
http://www.anachip.com
©2002 Anachip Corporation
Anachip reserves the right to make changes in specifications at any time and without notice. The information furnished by
Anachip in this publication is believed to be accurate and reliable. However, no responsibility is assumed by Anachip for
its use nor for any infringements of patents or other rights of third parties resulting from its use. No license is granted
under any patents or patent rights of Anachip. Anachip’s products are not authorized for use as critical components in life
support devices or systems.
Marks bearing © or ™ are registered trademarks and trademarks of Anachip Corp.
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