LATTICE MACH215-20JC

FINAL
COM’L: -12/15/20
IND: -14/18/24
Lattice Semiconductor
MACH215-12/15/20
High-Density EE CMOS Programmable Logic
DISTINCTIVE CHARACTERISTICS
■
44 Pins
■
38 Inputs with pull-up resistors
■
32 Output Macrocells
■
32 Outputs
■
32 Input Macrocells
■
64 Flip-flops
■
Product terms for:
— Individual flip-flop clock
— Individual asynchronous reset, preset
— Individual output enable
■
For asynchronous and synchronous
applications
■
4 “PAL22RA8” blocks with buried macrocells
■
Pin-compatible with MACH110, MACH111,
MACH210, and MACH211
■
12 ns tPD Commercial
14.5 ns tPD Industrial
■
67 MHz fCNT
GENERAL DESCRIPTION
The MACH215 is a member of the high-performance
EE CMOS MACH device family. This device has
approximately three times the capability of the popular
PAL20RA10 without loss of speed. This device is
designed for use in asynchronous as well as synchronous applications.
The MACH215 consists of four PAL blocks interconnected by a programmable switch matrix. The four PAL
blocks are essentially “PAL22RA8” structures complete
with product-term arrays and programmable macrocells, individual register control product terms, and input
registers. The switch matrix connects the PAL blocks to
each other and to all input pins, providing a high degree
of connectivity between the fully-connected PAL blocks.
This allows designs to be placed and routed efficiently.
The MACH215 has two kinds of macrocell: output and
input. The MACH215 output macrocell provides registered, latched, or combinatorial outputs with programmable polarity. If a registered configuration is chosen,
the register can be configured as D-type or T-type to
help reduce the number of product terms. The register
type decision can be made by the designer or by the
software. Each macrocell has its own dedicated clock,
asynchronous reset, and asynchronous preset control.
The polarity of the clock signal is programmable. All
output macrocells can be connected to an I/O cell.
The MACH215 has dedicated input macrocells which
provide input registers or latches for synchronizing input
signals and reducing setup time requirements.
Publication# 16751
Rev. E
Issue Date: May 1995
Amendment/0
BLOCK DIAGRAM
I0–I1,
I3–I4
I/O8–I/O15
I/O0–I/O7
8
I/O Cells
8
I/O Cells
8
8
Output
Macrocells
OE
Output
Macrocells
Input
Macrocells
CLK
OE
8
44x64
AND Logic Array
and
Logic Allocator
8
8
Input
Macrocells
CLK
8
44x64
AND Logic Array
and
Logic Allocator
22
8
8
4
22
Switch Matrix
22
22
44x64
AND Logic Array
and
Logic Allocator
OE
8
CLK
Output
Macrocells
I/O24–I/O31
8
OE
Input
Macrocells
8
8
8 2
CLK
Output
Macrocells
Input
Macrocells
8
8
I/O Cells
8
44x64
AND Logic Array
and
Logic Allocator
8
I/O Cells
I/O16–I/O23
8
CLK0/I2 CLK1/I5
16751E-1
2
MACH215-12/15/20
CONNECTION DIAGRAM
Top View
I/O0
GND
4
2
3
I/O29
I/O28
I/O2
I/O1
5
I/O31
I/O30
I/O3
6
VCC
I/O4
PLCC
1 44 43 42 41 40
I/O5
I/O6
7
39
I/O27
8
38
I/O7
I0
9
37
I/O26
I/O25
10
I/O24
CLK1/I5
I1
11
36
35
GND
12
34
GND
CLK0/I2
13
33
I4
I/O8
I/O9
14
32
I3
15
31
I/O10
I/O11
16
30
I/O23
I/O22
29
I/O21
17
I/O20
I/O18
I/O19
I/O16
I/O17
GND
VCC
I/O14
I/O15
I/O12
I/O13
18 19 20 21 22 23 24 25 26 27 28
16751E-2
Note:
Pin-compatible with MACH110, MACH111, MACH210, and MACH211.
PIN DESIGNATIONS
CLK/I =
GND =
I
=
I/O =
VCC
Clock or Input
Ground
Input
Input/Output
= Supply Voltage
MACH215-12/15/20
3
ORDERING INFORMATION
Commercial Products
Programmable logic products for commercial applications are available with several ordering options. The order number
(Valid Combination) is formed by a combination of:
MACH
215 -12
J
C
FAMILY TYPE
MACH = Macro Array CMOS High-Speed
OPTIONAL PROCESSING
Blank = Standard Processing
DEVICE NUMBER
215 = 32 Asynchronous Output Macrocells, 44 Pins
OPERATING CONDITIONS
C = Commercial (0°C to +70°C)
SPEED
-12 = 12 ns tPD
-15 = 15 ns tPD
-20 = 20 ns tPD
PACKAGE TYPE
J = 44-Pin Plastic Leaded Chip
Carrier (PL 044)
Valid Combinations
MACH215-12
MACH215-15
MACH215-20
4
JC
Valid Combinations
The Valid Combinations table lists configurations
planned to be supported in volume for this device.
Consult your local sales office to confirm availability of specific valid combinations and to check on newly
released combinations.
MACH215-12/15/20 (Com’l)
ORDERING INFORMATION
Industrial Products
Programmable logic products for industrial applications are available with several ordering options. The order number (Valid
Combination) is formed by a combination of:
MACH
215 -14
J
I
FAMILY TYPE
MACH = Macro Array CMOS High-Speed
OPTIONAL PROCESSING
Blank = Standard Processing
DEVICE NUMBER
215 = 32 Asynchronous Output Macrocells, 44 Pins
OPERATING CONDITIONS
I = Industrial (–40°C to +85°C)
SPEED
-14 = 14.5 ns tPD
-18 = 18 ns tPD
-24 = 24 ns tPD
PACKAGE TYPE
J = 44-Pin Plastic Leaded Chip
Carrier (PL 044)
Valid Combinations
MACH215-14
MACH215-18
MACH215-24
JI
Valid Combinations
The Valid Combinations table lists configurations
planned to be supported in volume for this device.
Consult your local sales office to confirm availability of specific valid combinations and to check on newly
released combinations.
MACH215-14/18/24 (Ind)
5
FUNCTIONAL DESCRIPTION
Table 1. Logic Allocation
The MACH215 consists of four asynchronous PAL
blocks connected by a switch matrix. There are 32 I/O
pins and 4 dedicated input pins feeding the switch
matrix. These signals are distributed to the four PAL
blocks for efficient design implementation. There are
also two additional global clock pins that can be used as
dedicated inputs. This device provides two kinds of
macrocell: output macrocells and input macrocells. This
adds greater logic density without affecting the number
of pins.
M0
M1
M2
M3
M4
M5
M6
M7
The PAL Blocks
Each PAL block in the MACH215 (Figure 1) contains a
64-product-term array, a logic allocator, 8 output
macrocells, 8 input macrocells, and 8 I/O cells. The
switch matrix feeds each PAL block with 22 inputs. This
makes the PAL block look effectively like an independent “PAL22RA8” with 8 input macrocells. All flip-flops
within the device can operate independently.
The Switch Matrix
The MACH215 switch matrix is fed by the inputs and
feedback signals from the PAL blocks. Each PAL block
provides 16 internal feedback signals and 8 I/O
feedback signals. The switch matrix distributes these
signals back to the PAL blocks in an efficient manner
that also provides for high performance. The design
software automatically configures the switch matrix
when fitting a design into the device.
The Product-term Array
The MACH215 product-term array consists of 32
product terms for logic use and 32 product terms for
generating macrocell control signals.
The logic allocator in the MACH215 (Figure 2) takes the
32 logic product terms and allocates them to the 16
macrocells as needed. Each macrocell can be driven by
up to 12 product terms. The design software automatically configures the logic allocator when fitting the
design into the device.
Table 1 illustrates which product term clusters are
available to each macrocell within a PAL block. Refer to
Figure 1 for cluster and macrocell numbers.
6
C0, C1
C0, C1, C2
C1, C2, C3
C2, C3, C4
C3, C4, C5
C4, C5, C6
C5, C6, C7
C6, C7
The Macrocell
There are two types of macrocell in the MACH215:
output macrocells and input macrocells. The output
macrocell takes the logic of the device and provides it to
I/O pins and/or provides feedback for additional logic
generation. The input macrocell allows I/O pins to be
configured as registered or latched inputs.
The output macrocell (Figure 3) can generate registered or combinatorial outputs. In addition, a transparent-low latched configuration is provided. If used, the
register can be configured as a T-type or a D-type
flip-flop. Register and latch functionality is defined in
Table 2. Programmable polarity and the T-type flip-flop
both give the software a way to minimize the number of
product terms needed. These choices can be made
automatically by the software when it fits the design into
the device.
Table 2. Register/Latch Operation
Configuration
The Logic Allocator
Available
Clusters
Output Macrocell
D/T
CLK/LE*
Q+
D-Register
X
0
1
0, 1, ↓ (↑)
↑ (↓)
↑ (↓)
Q
0
1
T-Register
X
0
1
0, 1, ↓ (↑)
↑ (↓)
↑ (↓)
Q
Q
Q
Latch
X
0
1
1 (0)
0 (1)
0 (1)
Q
0
1
*Polarity of CLK/LE can be programmed.
MACH215-12/15/20
The output macrocell sends its output back to the switch
matrix, via internal feedback, and to the I/O cell. The
feedback is always available regardless of the configuration of the I/O cell. This allows for buried combinatorial
or registered functions, freeing up the I/O pins for use as
inputs if not needed as outputs. The basic output
macrocell configurations are shown in Figure 4.
The clock/latch-enable for each individual output macrocell can be driven by one of four signals. Two of the
signals are provided by the global clock pin CLK0/LE0;
either polarity may be chosen. The other two signals
come from a product term provided for each output
macrocell. Either polarity of the logic generated by the
product term can be chosen. The global clock pin is also
available as an input, although care must be taken when
a signal acts as both clock and input to the same device.
Each individual output macrocell also has a product
term for asynchronous reset and a product term for
asynchronous preset. This means that any register or
latch may be reset or preset without affecting any other
register or latch in the device. The functionality of the
flip-flops with respect to initialization is illustrated in
Table 3.
The input macrocell (Figure 5) consists of a flip-flop that
can be used to provide registered or latched inputs. The
flip-flop can be clocked by either polarity of one of the
two global clock/latch-enable pins.
Reset or preset are not provided for these flip-flops. If
combinatorial inputs are desired, this macrocell is not
used, and the feedback from the I/O pin is used directly.
Both the I/O pin feedback and the output of the input
register or latch are always available to the switch
matrix.
Possible input macrocell configurations are shown in
Figure 6.
The I/O Cell
The I/O cell (Figure 7) provides a three-state output
buffer. The three-state control is provided by an
individual product term for each I/O cell. Depending on
the logic programmed onto this product term, the I/O pin
can be configured as an output, an input, or a
bidirectional pin. The feedback from the I/O pin is always
available to the switch matrix, regardless of the state of
the output buffer or the output macrocell.
Table 3. Asynchronous Reset/Preset Operation
AR
0
0
1
1
AP
0
1
0
1
CLK/LE
X
X
X
X
Q+
See Table 12
1
0
0
MACH215-12/15/20
7
0
4
8
12
16
20
24
28
32
36
40
43
Output
Macro
Cell
M0
I/O
Cell
I/O
I/O
Cell
I/O
I/O
Cell
I/O
I/O
Cell
I/O
I/O
Cell
I/O
I/O
Cell
I/O
I/O
Cell
I/O
I/O
Cell
I/O
2
2
Input
Macro
Cell
Output
Macro
Cell
M1
2
2
Input
Macro
Cell
0
Output
Macro
Cell
M2
C0
2
C1
Switch
Matrix
C3
C4
Logic Allocator
C2
2
Output
Macro
Cell
M3
2
2
M4
Input
Macro
Cell
Output
Macro
Cell
2
C5
C6
Input
Macro
Cell
2
M5
Input
Macro
Cell
Output
Macro
Cell
2
C7
64
63
2
M6
Input
Macro
Cell
Output
Macro
Cell
2
2
M7
Input
Macro
Cell
Output
Macro
Cell
2
2
8
12
16
20
24
28
32
36
40
43
CLK1
4
CLK0
0
Input
Macro
Cell
16
8
16751E-3
Figure 1. MACH215 PAL Block
8
MACH215-12/15/20
To
n–1
From
n–1
n
n
Product Term
Cluster
To
n+1
To Macrocell n
From
n+1
Logic
Allocator
16751E-4
Figure 2. Product Term Clusters and the Logic Allocator
Individual
Asynchronous
Preset
1
AP
D/T/L Q
Sum of Products
from Logic
Allocator
CLK0
Individual
Clock
1
0
0
To I/O
Cell
AR
Individual
Asynchronous
Reset
To
Switch
Matrix
16751E-5
Figure 3. Output Macrocell
MACH215-12/15/20
9
n
From Logic
Allocator
To I/O
Cell
To Switch
Matrix
a. Combinatorial, Active High
b. Combinatorial, Active Low
Individual
Preset
n
D APQ
CLK0
Individual
Clock
To I/O
Cell
From Logic
Allocator
AR
D APQ
CLK0
To I/O
Cell
AR
Individual
Preset
To Switch
Matrix
To Switch
Matrix
c. D-type Register, Active High
d. D-type Register, Active Low
Individual
Preset
Individual
Preset
n
T APQ
CLK0
Individual
Clock
To I/O
Cell
From Logic
Allocator
n
T APQ
CLK0
Individual
Clock
AR
Individual
Preset
To I/O
Cell
AR
Individual
Preset
To Switch
Matrix
To Switch
Matrix
f. T-type Register, Active Low
e. T-type Register, Active High
Individual
Preset
From Logic
Allocator
n
Individual
Clock
Individual
Preset
From Logic
Allocator
To I/O
Cell
To Switch
Matrix
Individual
Preset
From Logic
Allocator
n
From Logic
Allocator
Individual
Preset
n
L APQ
CLK0
G AR
Individual
Clock
Individual
Preset
To I/O
Cell
From Logic
Allocator
n
L APQ
CLK0
To I/O
Cell
G AR
Individual
Clock
Individual
Preset
To Switch
Matrix
To Switch
Matrix
h. Latch, Active Low
g. Latch, Active High
16751E-6
Figure 4. Output Macrocell Configurations
10
MACH215-12/15/20
From I/O Pin
AP
D/L
Q
CLK0
CLK1
To
Switch
Matrix
16751E-7
Figure 5. Input Macrocell
From I/O Cell
From I/O Cell
D
L
Q
CLK0
CLK0
CLK1
CLK1
Q
G
To Switch
Matrix
To Switch
Matrix
b. Input Latch
a. Input Register
16751E-8
Figure 6. Input Macrocell Configurations
Individual
Output Enable
Product Term
From Output
Macrocell
To Switch
Matrix
To Input
Macrocell
16751E-9
Figure 7. I/O Cell
MACH215-12/15/20
11
ABSOLUTE MAXIMUM RATINGS
OPERATING RANGES
Storage Temperature . . . . . . . . . . . –65°C to +150°C
Commercial (C) Devices
Ambient Temperature
with Power Applied . . . . . . . . . . . . . –55°C to +125°C
Temperature (TA) Operating
in Free Air . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C
Supply Voltage with
Respect to Ground . . . . . . . . . . . . . –0.5 V to +7.0 V
Supply Voltage (VCC) with
Respect to Ground . . . . . . . . . . . . +4.75 V to +5.25 V
DC Input Voltage . . . . . . . . . . . . –0.5 V to VCC + 0.5 V
DC Output or I/O
Pin Voltage . . . . . . . . . . . . . . . –0.5 V to VCC + 0.5 V
Operating ranges define those limits between which the functionality of the device is guaranteed.
Static Discharge Voltage . . . . . . . . . . . . . . . . . 2001 V
Latchup Current
(TA = 0°C to +70°C) . . . . . . . . . . . . . . . . . . . . 200 mA
Stresses above those listed under Absolute Maximum Ratings
may cause permanent device failure. Functionality at or above
these limits is not implied. Exposure to Absolute Maximum
Ratings for extended periods may affect device reliability.
Programming conditions may differ.
DC CHARACTERISTICS over COMMERCIAL operating ranges unless otherwise specified
Parameter
Symbol
Parameter Description
Test Conditions
Min
Typ
Max
Unit
VOH
Output HIGH Voltage
IOH = –3.2 mA, VCC = Min
VIN = VIH or VIL
2.4
VOL
Output LOW Voltage
IOL = 24 mA, VCC = Min
VIN = VIH or VIL (Note 1)
VIH
Input HIGH Voltage
Guaranteed Input Logical HIGH
Voltage for all Inputs (Note 2)
VIL
Input LOW Voltage
Guaranteed Input Logical LOW
Voltage for all Inputs (Note 2)
0.8
V
IIH
Input HIGH Current
VIN = 5.25 V, VCC = Max (Note 3)
10
µA
IIL
Input LOW Current
VIN = 0 V, VCC = Max (Note 3)
–100
µA
IOZH
Off-State Output Leakage
Current HIGH
VOUT = 5.25 V, VCC = Max
VIN = VIH or VIL (Note 3)
10
µA
IOZL
Off-State Output Leakage
Current LOW
VOUT = 0 V, VCC = Max
VIN = VIH or VIL (Note 3)
–100
µA
ISC
Output Short-Circuit Current
VOUT = 0.5 V, VCC = Max (Note 4)
–160
mA
ICC
Supply Current (Typical)
VCC = 5 V, TA = 25°C, f = 25 MHz
(Note 5)
V
0.5
2.0
V
V
–30
95
mA
Notes:
1.
2.
3.
4.
Total IOL for one PAL block should not exceed 128 mA.
These are absolute values with respect to device ground and all overshoots due to system or tester noise are included.
I/O pin leakage is the worst case of IIL and IOZL (or IIH and IOZH).
Not more than one output should be shorted at a time and duration of the short-circuit should not exceed one second.
VOUT = 0.5 V has been chosen to avoid test problems caused by tester ground degradation.
5. Measured with a 16-bit up/down counter pattern. This pattern is programmed in each PAL block and is capable of being
loaded, enabled, and reset.
12
MACH215-12/15/20 (Com’l)
CAPACITANCE (Note 1)
Parameter
Symbol
CIN
COUT
Parameter Description
Test Conditions
Typ
Unit
Input Capacitance
VIN = 2.0 V
VCC = 5.0 V, TA = 25°C,
6
pF
Output Capacitance
VOUT = 2.0 V
f = 1 MHz
8
pF
SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 2)
-12
Min Max
Parameter
Symbol
Parameter Description
tPD
Input, I/O, or Feedback to Combinatorial Output (Note 3)
tSA
Setup Time from Input, I/O, or
Feedback to Product Term Clock
3
fMAXA
tSS
Internal Feedback (fCNTA)
6
7
9
ns
Setup Time from Input, I/O,
or Feedback to Global Clock
tHS
Register Data Hold Time Using Global Clock
tCOS
Global Clock to Output (Note 3)
tWHS
fMAXS
Global Clock Width
Maximum
Frequency
Using
Global
Clock
(Note 1)
External Feedback
1/(tSS + tCOS)
Internal Feedback (fCNTS)
No Feedback
4
8
18
4
ns
22
ns
8
9
12
ns
HIGH
8
9
12
ns
D-type
52.6
41.7
33.3
MHz
T-type
50
40
32.2
MHz
D-type
58.8
45.5
35.7
MHz
T-type
55.6
43.5
34.5
MHz
62.5
55.6
41.7
MHz
D-type
7
10
13
ns
T-type
8
11
14
ns
0
0
0
ns
2
tWLS
6
14
LOW
1/(tWLA + tWHA)
No Feedback
ns
T-type
4
1/(tSA + tCOA)
Unit
ns
5
External Feedback
20
8
Product Term Clock to Output (Note 3)
Maximum
Frequency
Using
Product
Term
Clock
(Note 1)
3
6
Register Data Hold Time Using Product Term Clock
tWHA
15
5
tHA
Product Term, Clock Width
3
-20
Min Max
D-type
tCOA
tWLA
12
-15
Min Max
8
2
10
2
12
ns
LOW
6
6
8
ns
HIGH
6
6
8
ns
D-type
66.7
50
40
MHz
T-type
62.5
47.6
38.5
MHz
D-type
83.3
66.6
50
MHz
T-type
76.9
62.5
47.6
MHz
83.3
83.3
62.5
MHz
5
6
8
ns
5
6
8
ns
1/(tWLS + tWHS)
tHLA
Setup Time from Input, I/O,
or Feedback to Product Term Gate
Latch Data Hold Time Using Product Term Clock
tGOA
Product Term Gate to Output (Note 3)
tGWA
Product Term Gate Width LOW (for LOW transparent)
or HIGH (for HIGH transparent)
8
9
12
ns
tSLS
Setup Time from Input, I/O, or Feedback to Global Gate
7
10
13
ns
tHLS
Latch Data Hold Time Using Global Gate
0
0
0
ns
tGOS
Gate to Output (Note 3)
tGWS
Global Gate Width LOW (for LOW transparent)
or HIGH (for HIGH transparent)
tSLA
16
19
10
MACH215-12/15/20 (Com’l)
6
22
11
6
12
8
ns
ns
ns
13
SWITCHING CHARACTERISTICS over COMMERCIAL operating ranges (Note 2)
(continued)
Parameter
Symbol
Parameter Description
tPDL
-12
Min Max
Input, I/O, or Feedback to Output Through
Transparent Input or Output Latch
-15
Min Max
14
-20
Min Max
17
22
Unit
ns
tSIR
Input Register Setup Time
2
2
2
ns
tHIR
Input Register Hold Time
2
2.5
3
ns
tICO
Input Register Clock to Combinatorial Output
tICS
Input Register Clock to Output Register Setup
tWICL
Input Register Clock Width
tWICH
fMAXIR
Maximum Input Register Frequency
15
18
23
ns
D-type
12
15
20
ns
T-type
13
16
21
ns
LOW
6
6
8
ns
HIGH
6
6
8
ns
83.3
83.3
62.5
MHz
1/(tWICL + tWICH)
tSIL
Input Latch Setup Time
2
2
2
ns
tHIL
Input Latch Hold Time
2
2.5
3
ns
tIGO
Input Latch Gate to Combinatorial Output
17
20
25
ns
tIGOL
Input Latch Gate to Output Through Transparent
Output Latch
19
22
27
ns
tSLLA
Setup Time from Input, I/O, or Feedback Through
Transparent Input Latch to Product Term Output
Latch Gate
tIGSA
Input Latch Gate to Output Latch Setup Using
Product Term Output Latch Gate
tSLLS
Setup Time from Input, I/O, or Feedback Through
Transparent Input Latch to Global Output Latch Gate
7
8
10
ns
7
8
10
ns
9
12
15
ns
tIGSS
Input Latch Gate to Output Latch Setup Using Global
Output Latch Gate
13
16
21
ns
tWIGL
Input Latch Gate Width LOW
6
6
8
ns
tPDLL
Input, I/O, or Feedback to Output Through Transparent
Input and Output Latches
16
19
24
ns
Asynchronous Reset to Registered or Latched Output
16
20
25
ns
tAR
tARW
Asynchronous Reset Width (Note 1)
12
tARR
Asynchronous Reset Recovery Time (Note 1)
8
tAP
Asynchronous Preset to Registered or Latched Output
15
20
10
16
ns
15
20
ns
25
ns
tAPW
Asynchronous Preset Width (Note 1)
12
15
20
ns
tAPR
Asynchronous Preset Recovery Time (Note 1)
8
10
15
ns
tEA
Input, I/O, or Feedback to Output Enable (Note 3)
2
12
2
15
2
20
ns
tER
Input, I/O, or Feedback to Output Disable (Note 3)
2
12
2
15
2
20
ns
Notes:
1. These parameters are not 100% tested, but are evaluated at initial characterization and at any time the design is modified
where frequency may be affected.
2. See Switching Test Circuit for test conditions. Switching waveforms illustrate true clocks only. Switching waveforms can be
used to illustrate both synchronous and asynchronous clock timing. For example, tSS is the tS parameter for synchronous
clocks and tSA is the tS parameter for asynchronous clocks.
3. Parameters measured with 16 outputs switching.
14
MACH215-12/15/20 (Com’l)
ABSOLUTE MAXIMUM RATINGS
INDUSTRIAL OPERATING RANGES
Storage Temperature . . . . . . . . . . . –65°C to +150°C
Ambient Temperature (TA)
Operating in Free Air . . . . . . . . . . . . –40°C to +85°C
Ambient Temperature
with Power Applied . . . . . . . . . . . . . –55°C to +125°C
Supply Voltage with
Respect to Ground . . . . . . . . . . . . . –0.5 V to +7.0 V
DC Input Voltage . . . . . . . . . . . . –0.5 V to VCC + 0.5 V
Supply Voltage (VCC) with
Respect to Ground . . . . . . . . . . . . . . +4.5 V to +5.5 V
Operating ranges define those limits between which the functionality of the device is guaranteed.
DC Output or
I/O Pin Voltage . . . . . . . . . . . . . –0.5 V to VCC + 0.5 V
Static Discharge Voltage . . . . . . . . . . . . . . . . . 2001 V
Latchup Current
(TA = –40°C to +85°C) . . . . . . . . . . . . . . . . . . 200 mA
Stresses above those listed under Absolute Maximum Ratings
may cause permanent device failure. Functionality at or above
these limits is not implied. Exposure to Absolute Maximum
Ratings for extended periods may affect device reliability.
Programming conditions may differ.
DC CHARACTERISTICS over INDUSTRIAL operating ranges unless otherwise specified
Parameter
Symbol
Parameter Description
Test Conditions
Min
Typ
Max
Unit
VOH
Output HIGH Voltage
IOH = –3.2 mA, VCC = Min
VIN = VIH or VIL
2.4
VOL
Output LOW Voltage
IOL = 24 mA, VCC = Min
VIN = VIH or VIL (Note 1)
VIH
Input HIGH Voltage
Guaranteed Input Logical HIGH
Voltage for all Inputs (Note 2)
VIL
Input LOW Voltage
Guaranteed Input Logical LOW
Voltage for all Inputs (Note 2)
0.8
V
IIH
Input HIGH Leakage Current
VIN = 5.25 V, VCC = Max (Note 3)
10
µA
IIL
Input LOW Leakage Current
VIN = 0 V, VCC = Max (Note 3)
–100
µA
IOZH
Off-State Output Leakage
Current HIGH
VOUT = 5.25 V, VCC = Max
VIN = VIH or VIL (Note 3)
10
µA
IOZL
Off-State Output Leakage
Current LOW
VOUT = 0 V, VCC = Max
VIN = VIH or VIL (Note 2)
–100
µA
ISC
Output Short-Circuit Current
VOUT = 0.5 V, VCC = Max (Note 4)
–160
mA
ICC
Supply Current (Typical)
VCC = 5 V, TA = 25°C, f = 25 MHz (Note 5)
V
0.5
2.0
V
V
–30
95
mA
Notes:
1. Total IOL for one PAL block should not exceed 128 mA.
2. These are absolute values with respect to device ground and all overshoots due to system and/or tester noise are included.
3. I/O pin leakage is the worst case of IIL and IOZL (or IIH and IOZH).
4. Not more than one output should be shorted at a time. Duration of the short-circuit should not exceed one second.
VOUT = 0.5 V has been chosen to avoid test problems caused by tester ground degradation.
5. Measured with a 16-bit up/down counter pattern. This pattern is programmed in each PAL block and is capable of
being loaded, enabled, and reset.
MACH215-14/18/24 (Ind)
15
CAPACITANCE (Note 1)
Parameter
Symbol
CIN
COUT
Parameter Description
Test Conditions
Typ
Unit
Input Capacitance
VIN = 2.0 V
Output Capacitance
VOUT = 2.0 V
VCC = 5.0 V, TA = 25°C,
6
pF
f = 1 MHz
8
pF
SWITCHING CHARACTERISTICS over INDUSTRIAL operating ranges (Note 2)
-14
Min Max
Parameter
Symbol
Parameter Description
tPD
Input, I/O, or Feedback to Combinatorial Output
(Note 3)
tSA
Setup Time from Input, I/O, or
Feedback to Product Term Clock
tHA
Register Data Hold Time Using Product Term Clock
tCOA
Product Term Clock to Output (Note 3)
tWLA
Product Term, Clock Width
tWHA
fMAXS
tSS
Maximum
Frequency
Using
Product
Term
Clock
(Note 1)
External Feedback
1/(tSA + tCOA)
Internal Feedback (fCNTA)
No Feedback
tHS
Register Data Hold Time Using Global Clock
tCOS
Global Clock to Output (Note 3)
fMAXS
Maximum
Frequency
Using
Global
Clock
(Note 1)
External Feedback
1/(tSS + tCOS)
Internal Feedback (fCNTS)
No Feedback
24
Unit
ns
D-type
6
7.5
10
ns
T-type
7.5
8.5
11
ns
6
7.5
17
10
22
ns
26.5
ns
LOW
10
11
15
ns
HIGH
10
11
15
ns
D-type
42
33
26.5
MHz
T-type
40
32
25.5
MHz
D-type
47
36
28.5
MHz
T-type
44
34.5
27.5
MHz
50
44.5
33
MHz
D-type
8.5
12
16
ns
T-type
10
13.5
17
ns
0
0
0
12
ns
14.5
ns
LOW
7.5
7.5
10
HIGH
7.5
7.5
10
ns
D-type
53
40
32
MHz
T-type
50
38
30.5
MHz
D-type
66.5
53
40
MHz
T-type
61.5
50
38
MHz
66.5
66.5
50
MHz
6
7.5
10
ns
1/(tWLS + tWHS)
ns
tHLA
Setup Time from Input, I/O,
or Feedback to Product Term Gate
Latch Data Hold Time Using Product Term Clock
tGOA
Product Term Gate to Output (Note 3)
tGWA
Product Term Gate Width LOW (for LOW transparent)
or HIGH (for HIGH transparent)
10
11
14.5
8.5
12
16
ns
0
0
0
ns
tSLA
16
Global Clock Width
-24
Min Max
18
10
tWLS
tWHS
14.5
1/(tWLA + tWHA)
Setup Time from Input, I/O,
or Feedback to Global Clock
-18
Min Max
tSLS
Setup Time from Input, I/O, or Feedback to Global Gate
tHLS
Latch Data Hold Time Using Global Gate
tGOS
Gate to Output (Note 3)
tGWS
Global Gate Width LOW (for LOW transparent)
or HIGH (for HIGH transparent)
6
7.5
19.5
12
MACH215-14/18/24 (Ind)
7.5
10
23
13.5
7.5
ns
26.5
ns
14.5
10
ns
ns
ns
SWITCHING CHARACTERISTICS over INDUSTRIAL operating ranges (Note 2)
(continued)
-14
Parameter
Symbol
Parameter Description
Min
tPDL
Input, I/O, or Feedback to Output Through
Transparent Input or Output Latch
-18
Max
Min
17
-24
Max
Min
20.5
Max
Unit
26.5
ns
tSIR
Input Register Setup Time
2.4
2.4
2.4
ns
tHIR
Input Register Hold Time
3
3.5
4
ns
tICO
Input Register Clock to Combinatorial Output
tICS
Input Register Clock to Output Register Setup
tWICL
tWICH
fMAXIR
Input Register Clock Width
Maximum Input Register Frequency
18
18
24
ns
T-type
16
19.5
25.5
ns
LOW
7.5
7.5
10
ns
HIGH
7.5
7.5
10
ns
66.5
66.5
50
MHz
2.5
2.5
ns
Input Latch Setup Time
2.5
3
Input Latch Hold Time
Input Latch Gate to Combinatorial Output
tIGOL
Input Latch Gate to Output Through Transparent
Output Latch
tSLLA
ns
14.5
tSIL
tHIL
28
D-type
1/(tWICL + tWICH)
tIGO
22
Setup Time from Input, I/O, or Feedback Through
Transparent Input Latch to Product Term Output
Latch Gate
3.5
4
ns
20.5
24
30
ns
23
26.5
32.5
ns
8.5
10
12
ns
tIGSA
Input Latch Gate to Output Latch Setup Using
Product Term Output Latch Gate
8.5
10
12
ns
tSLLS
Setup Time from Input, I/O, or Feedback Through
Transparent Input Latch to Global Output Latch Gate
11
14.5
18
ns
tIGSS
Input Latch Gate to Output Latch Setup Using Global
Output Latch Gate
16
19.5
25.5
ns
tWIGL
Input Latch Gate Width LOW
7.5
7.5
10
ns
tPDLL
Input, I/O, or Feedback to Output Through Transparent
Input and Output Latches
19.5
23
29
ns
tAR
Asynchronous Reset to Registered or Latched Output
19.5
24
30
ns
tARW
Asynchronous Reset Width (Note 1)
tARR
Asynchronous Reset Recovery Time (Note 1)
tAP
Asynchronous Preset to Registered or Latched Output
14.5
18
24
ns
10
12
18
ns
19.5
14.5
24
18
30
tAPW
Asynchronous Preset Width (Note 1)
tAPR
Asynchronous Preset Recovery Time (Note 1)
tEA
Input, I/O, or Feedback to Output Enable (Note 3)
14.5
18
24
ns
tER
Input, I/O, or Feedback to Output Disable (Note 3)
14.5
18
24
ns
10
24
ns
12
ns
18
ns
Notes:
1. These parameters are not 100% tested, but are evaluated at initial characterization and at any time the design is modified
where frequency may be affected.
2. See Switching Test Circuit for test conditions. Switching waveforms illustrate true clocks only. Switching waveforms can be
used to illustrate both synchronous and asynchronous clock timing. For example, tSS is the tS parameter for synchronous
clocks and tSA is the tS parameter for asynchronous clocks.
3. Parameters measured with 16 outputs switching.
MACH215-14/18/24 (Ind)
17
TYPICAL CURRENT VS. VOLTAGE (I-V) CHARACTERISTICS
VCC = 5.0 V, TA = 25°C
IOL (mA)
80
60
40
20
VOL (V)
–1.0 –0.8 –0.6 –0.4 –0.2
–20
.2
.4
.6
.8
1.0
–40
–60
–80
16751E-10
Output, LOW
IOH (mA)
25
1
2
3
4
5
VOH (V)
–3
–2
–1
–25
–50
–75
–100
–125
–150
16751E-11
Output, HIGH
II (mA)
20
VI (V)
–2
–1
–20
1
2
3
4
5
–40
–60
–80
–100
16751E-12
Input
18
MACH215-12/15/20
TYPICAL ICC CHARACTERISTICS
VCC = 5 V, TA = 25°C
150
125
MACH215
100
ICC (mA)
75
50
25
0
0
10
20
30
40
50
60
70
80
90
Frequency (MHz)
16751E-13
The selected “typical” pattern is a 16-bit up/down counter. This pattern is programmed in each PAL block and is capable of
being loaded, enabled, and reset.
Maximum frequency shown uses internal feedback and a D-type register.
MACH215-12/15/20
19
TYPICAL THERMAL CHARACTERISTICS
Measured at 25°C ambient. These parameters are not tested.
Parameter
Symbol
Parameter Description
Typ
PLCC
Units
θjc
Thermal impedance, junction to case
15
°C/W
θja
Thermal impedance, junction to ambient
40
°C/W
200 lfpm air
36
°C/W
400 lfpm air
33
°C/W
600 lfpm air
31
°C/W
800 lfpm air
29
°C/W
θjma
Thermal impedance, junction to
ambient with air flow
Plastic θjc Considerations
The data listed for plastic θjc are for reference only and are not recommended for use in calculating junction temperatures. The
heat-flow paths in plastic-encapsulated devices are complex, making the θjc measurement relative to a specific location on the
package surface. Tests indicate this measurement reference point is directly below the die-attach area on the bottom center of the
package. Furthermore, θjc tests on packages are performed in a constant-temperature bath, keeping the package surface at a
constant temperature. Therefore, the measurements can only be used in a similar environment.
20
MACH215-12/15/20
SWITCHING WAVEFORMS
Input, I/O, or
Feedback
VT
tPD
Combinatorial
Output
VT
16751E-14
Combinatorial Output
Input, I/O,
or Feedback
Input, I/O, or
Feedback
VT
tS
VT
tH
tSL
Gate
VT
Clock
tHL
tCO
Registered
Output
VT
tPDL
tGO
Latched
Out
VT
VT
16751E-16
16751E-15
Registered Output
Latched Output (MACH 2, 3, and 4)
tWH
Clock
Gate
VT
tGWS
tWL
16751E-18
16751E-17
Clock Width
Gate Width (MACH 2, 3, and 4)
Registered
Input
VT
tSIR
Input
Register
Clock
Registered
Input
VT
tHIR
Input
Register
Clock
VT
tICO
Combinatorial
Output
VT
16751E-19
Output
Register
Clock
Registered Input (MACH 2 and 4)
VT
tICS
VT
16751E-20
Input Register to Output Register Setup
(MACH 2 and 4)
Notes:
1. VT = 1.5 V.
2. Input pulse amplitude 0 V to 3.0 V.
3. Input rise and fall times 2 ns–4 ns typical.
MACH215-12/15/20
21
SWITCHING WAVEFORMS
Latched
In
VT
tSIL
tHIL
Gate
VT
tIGO
Combinatorial
Output
VT
16751E-21
Latched Input (MACH 2 and 4)
tPDLL
Latched
In
VT
Latched
Out
Input
Latch Gate
VT
tIGOL
tSLL
tIGS
VT
Output
Latch Gate
16751E-22
Latched Input and Output
(MACH 2, 3, and 4)
Notes:
1. VT = 1.5 V.
2. Input pulse amplitude 0 V to 3.0 V.
3. Input rise and fall times 2 ns–4 ns typical.
22
MACH215-12/15/20
SWITCHING WAVEFORMS
tWICH
Clock
Input
Latch
Gate
VT
VT
tWICL
tWIGL
16751E-24
16751E-23
Input Register Clock Width
(MACH 2 and 4)
Input Latch Gate Width
(MACH 2 and 4)
tARW
tAPW
Input, I/O, or
Feedback
Input, I/O,
or Feedback
VT
VT
tAR
Registered
Output
tAP
Registered
Output
VT
VT
tARR
Clock
tAPR
Clock
VT
VT
16751E-25
16751E-26
Asynchronous Reset
Asynchronous Preset
Input, I/O, or
Feedback
VT
tER
Outputs
tEA
VOH - 0.5V
VOL + 0.5V
VT
16751E-27
Output Disable/Enable
Notes:
1. VT = 1.5 V.
2. Input pulse amplitude 0 V to 3.0 V.
3. Input rise and fall times 2 ns–4 ns typical.
MACH215-12/15/20
23
KEY TO SWITCHING WAVEFORMS
WAVEFORM
INPUTS
OUTPUTS
Must be
Steady
Will be
Steady
May
Change
from H to L
Will be
Changing
from H to L
May
Change
from L to H
Will be
Changing
from L to H
Don’t Care,
Any Change
Permitted
Changing,
State
Unknown
Does Not
Apply
Center
Line is HighImpedance
“Off” State
KS000010-PAL
SWITCHING TEST CIRCUIT
5V
S1
R1
Output
Test Point
R2
CL
16751E-28
Commercial
Specification
tPD, tCO
tEA
tER
S1
CL
R1
R2
Closed
Measured
Output Value
1.5 V
Z → H: Open
Z → L: Closed
35 pF
H → Z: Open
L → Z: Closed
5 pF
1.5 V
300 Ω
390 Ω
H → Z: VOH – 0.5 V
L → Z: VOL + 0.5 V
*Switching several outputs simultaneously should be avoided for accurate measurement.
24
MACH215-12/15/20
fMAX PARAMETERS
The parameter fMAX is the maximum clock rate at which
the device is guaranteed to operate. Because the flexibility inherent in programmable logic devices offers a
choice of clocked flip-flop designs, fMAX is specified for
three types of synchronous designs.
The first type of design is a state machine with feedback
signals sent off-chip. This external feedback could go
back to the device inputs, or to a second device in a
multi-chip state machine. The slowest path defining the
period is the sum of the clock-to-output time and the input setup time for the external signals (tS + tCO). The reciprocal, fMAX, is the maximum frequency with external
feedback or in conjunction with an equivalent speed device. This fMAX is designated “fMAX external.”
The second type of design is a single-chip state machine with internal feedback only. In this case, flip-flop
inputs are defined by the device inputs and flip-flop outputs. Under these conditions, the period is limited by the
internal delay from the flip-flop outputs through the internal feedback and logic to the flip-flop inputs. This fMAX is
designated “fMAX internal”. A simple internal counter is a
good example of this type of design; therefore, this parameter is sometimes called “fCNT.”
The third type of design is a simple data path application. In this case, input data is presented to the flip-flop
and clocked through; no feedback is employed. Under
these conditions, the period is limited by the sum of the
data setup time and the data hold time (tS + tH). However,
a lower limit for the period of each fMAX type is the minimum clock period (tWH + tWL). Usually, this minimum
clock period determines the period for the third fMAX, designated “fMAX no feedback.”
For devices with input registers, one additional fMAX parameter is specified: fMAXIR. Because this involves no
feedback, it is calculated the same way as fMAX no feedback. The minimum period will be limited either by the
sum of the setup and hold times (tSIR + tHIR) or the sum of
the clock widths (tWICL + tWICH). The clock widths are normally the limiting parameters, so that fMAXIR is specified
as 1/(tWICL + tWICH). Note that if both input and output registers are use in the same path, the overall frequency will
be limited by tICS.
All frequencies except fMAX internal are calculated from
other measured AC parameters. fMAX internal is measured directly.
CLK
CLK
(SECOND
CHIP)
LOGIC
LOGIC
REGISTER
tS
t CO
tS
fMAX Internal (fCNT)
fMAX External; 1/(tS + tCO)
LOGIC
REGISTER
CLK
CLK
REGISTER
REGISTER
tS
tSIR
fMAX No Feedback; 1/(tS + tH) or 1/(tWH + tWL)
LOGIC
tHIR
fMAXIR ; 1/(tSIR + tHIR) or 1/(tWICL + tWICH)
16751E-29
MACH215-12/15/20
25
ENDURANCE CHARACTERISTICS
The MACH families are manufactured using our
advanced Electrically Erasable process. This technology uses an EE cell to replace the fuse link used in
bipolar parts. As a result, the device can be erased and
reprogrammed, a feature which allows 100% testing at
the factory.
Endurance Characteristics
Parameter
Symbol
tDR
N
26
Parameter Description
Min
Units
Test Conditions
10
Years
Max Storage
Temperature
Min Pattern Data Retention Time
20
Years
Max Operating
Temperature
Max Reprogramming Cycles
100
Cycles
Normal Programming
Conditions
MACH215-12/15/20
INPUT/OUTPUT EQUIVALENT SCHEMATICS
VCC
100 kΩ
1 kΩ
VCC
ESD
Protection
Input
VCC
VCC
100 kΩ
1 kΩ
Preload
Circuitry
Feedback
Input
16751E-30
I/O
MACH215-12/15/20
27
POWER-UP RESET
The MACH devices have been designed with the capability to reset during system power-up. Following powerup, all flip-flops will be reset to LOW. The output state
will depend on the logic polarity. This feature provides
extra flexibility to the designer and is especially valuable
in simplifying state machine initialization. A timing diagram and parameter table are shown below. Due to the
synchronous operation of the power-up reset and the
Parameter
Symbol
wide range of ways VCC can rise to its steady state, two
conditions are required to insure a valid power-up reset.
These conditions are:
1. The VCC rise must be monotonic.
2. Following reset, the clock input must not be driven
from LOW to HIGH until all applicable input and
feedback setup times are met.
Parameter Descriptions
Max
Unit
tPR
Power-Up Reset Time
10
µs
tS
Input or Feedback Setup Time
tWL
Clock Width LOW
See
Switching
Characteristics
VCC
Power
4V
tPR
Registered
Output
tS
Clock
tWL
16751E-31
Power-Up Reset Waveform
28
MACH215-12/15/20
USING PRELOAD AND OBSERVABILITY
In order to be testable, a circuit must be both controllable
and observable. To achieve this, the MACH devices
incorporate register preload and observability.
Preloaded
HIGH
D
In preload mode, each flip-flop in the MACH device can
be loaded from the I/O pins, in order to perform
functional testing of complex state machines. Register
preload makes it possible to run a series of tests from a
known starting state, or to load illegal states and test for
proper recovery. This ability to control the MACH
device’s internal state can shorten test sequences,
since it is easier to reach the state of interest.
Q1
Q
AR
Preloaded
HIGH
The observability function makes it possible to see the
internal state of the buried registers during test by
overriding each register’s output enable and activating
the output buffer. The values stored in output and buried
registers can then be observed on the I/O pins. Without
this feature, a thorough functional test would be
impossible for any designs with buried registers.
D Q2
Q
AR
While the implementation of the testability features is
fairly straightforward, care must be taken in certain
instances to insure valid testing.
One case involves asynchronous reset and preset. If the
MACH registers drive asynchronous reset or preset
lines and are preloaded in such a way that reset or
preset are asserted, the reset or preset may remove the
preloaded data. This is illustrated in Figure 8. Care
should be taken when planning functional tests, so that
states that will cause unexpected resets and presets are
not preloaded.
Another case to be aware of arises in testing combinatorial logic. When an output is configured as combinatorial, the observability feature forces the output into
registered mode. When this happens, all product terms
are forced to zero, which eliminates all combinatorial
data. For a straight combinatorial output, the correct
value will be restored after the preload or observe
function, and there will be no problem. If the function
implements a combinatorial latch, however, it relies on
feedback to hold the correct value, as shown in Figure 9.
As this value may change during the preload or observe
operation, you cannot count on the data being correct
after the operation. To insure valid testing in these
cases, outputs that are combinatorial latches should not
be tested immediately following a preload or observe
sequence, but should first be restored to a known state.
On
Preload
Mode
Off
Q1
AR
Q2
Figure 8. Preload/Reset Conflict
16751E-32
Set
All MACH 2 devices support both preload and
observability.
Contact individual programming vendors in order to
verify programmer support.
Reset
Figure 9. Combinatorial Latch
16751E-33
MACH215-12/15/20
29
PHYSICAL DIMENSIONS*
PL 044
44-Pin Plastic Leaded Chip Carrier (measured in inches)
.685
.695
.650
.656
.042
.056
.062
.083
Pin 1 I.D.
.685
.695
.650
.656
.500 .590
REF .630
.013
.021
.026
.032
.050 REF
.009
.015
TOP VIEW
SEATING PLANE
SIDE VIEW
*For reference only. BSC is an ANSI standard for Basic Space Centering.
34
.090
.120
.165
.180
MACH215-12/15/20
16-038-SQ
PL 044
DA78
6-28-94 ae