ispPAC-POWR1208 Data Sheet

ispPAC®-POWR1208 Device Datasheet
September 2010
All Devices Discontinued!
Product Change Notification (PCN) #13-10 has been issued to discontinue all devices in
this data sheet.
The original datasheet pages have not been modified and do not reflect those changes.
Please refer to the table below for reference PCN and current product status.
Product Line
ispPACPOWR1208
Ordering Part Number
ispPAC-POWR1208-01T44I
ispPAC-POWR1208-01T44E
ispPAC-POWR1208-01TN44I
ispPAC-POWR1208-01TN44E
Product Status
Reference PCN
Discontinued
PCN#13-10
5555 N.E. Moore Ct.  Hillsboro, Oregon 97124-6421  Phone (503) 268-8000  FAX (503) 268-8347
Internet: http://www.latticesemi.com
®
ispPAC-POWR1208
In-System Programmable Power Supply
Sequencing Controller and Monitor
August 2004
Data Sheet DS1031
Features
Application Block Diagram
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■ Monitor and Control Multiple Power
Supplies
•
•
•
•
-48V
Primary
Simultaneously monitors up to 12 power supplies
Sequence controller for power-up conditions
Provides eight output control signals
Programmable digital and analog circuitry
-48V
Primary
■ Embedded PLD for Sequence Control
-48V
Primary
• Implements state machine and input conditional
events
• In-System Programmable (ISP™) through JTAG
and on-chip E2CMOS®
-48V
Primary
+
DC/DC
Supply Gnd
+
-
+
DC/DC
Supply Gnd
+5V
Circuits
RG
+3.3V
Circuits
+3.3V
RG
+2.5V
Circuits
+2.5V
+
DC/DC
Supply Gnd
+
-
+1.8V
+1.8V
Circuits
RG
10uF
■ Analog Comparators for Monitoring
• 12 analog comparators for monitoring
• 192 precise programmable threshold levels
spanning 1.03V to 5.72V
• Each comparator can be independently configured around standard logic supply voltages of
1.2V, 1.5V, 1.8V, 2.5V, 3.3V, 5V
• Other user-defined voltages possible
• Eight direct comparator outputs
VDD
0.1uF
OE/EN
VDD VDDINP
VMON1
HVOUT1
VMON2
HVOUT2
VMON3
HVOUT3
VMON4
HVOUT4
VMON5
OUT5
VMON6 ispPAC-POWR1208 OUT6
VMON7
OUT7
VMON8
OUT8
Power Sequence
VMON9
Comp1
Controller
VMON10
Comp2
VMON11
Comp3
VMON12
Comp4
CLK
Comp5
Comp6
RESET
Comp7
IN1
Comp8
IN2
POR
IN3
IN4
■ Embedded Oscillator
CREF
DC/DC Supply
or Regulator
OE/EN
DC/DC Supply
or Regulator
3.3V
EN
Digital
Logic
3.3V
EN
0.1uF
Digital
Logic
Description
Built-in clock generator, 250kHz
Programmable clock frequency
Programmable timer pre-scaler
External clock support
■ Programmable Output Configurations
• Four digital outputs for logic and power supply
control
• Four fully programmable gate driver outputs for
FET control, or programmable as four additional
digital outputs
• Expandable with ispMACH™ 4000 CPLD
■ 2.25V to 5.5V Supply Range
In-system programmable at 3.0V to 5.5V
Industrial temperature range: -40°C to +85°C
Automotive temperature range: -40°C to +125°C
44-pin TQFP package
Lead-free package option
U
+
-
+5V
12 Analog Inputs
• 4 Programmable 8-bit timers (32µs to 524ms)
• Programmable time delay between multiple
power supply ramp-up and wait statements
•
•
•
•
•
DC/DC
+
Supply Gnd
RG
■ Embedded Programmable Timers
•
•
•
•
+
-
The Lattice ispPAC-POWR1208 incorporates both insystem programmable logic and in-system programmable analog circuits to perform special functions for
power supply sequencing and monitoring. The ispPACPOWR1208 device has the capability to be configured
through software to control up to eight outputs for power
supply sequencing and 12 comparators monitoring supply voltage limits, along with four digital inputs for interfacing to other control circuits or digital logic. Once
configured, the design is downloaded into the device
through a standard JTAG interface. The circuit configuration and routing are stored in non-volatile E2CMOS.
PAC-Designer,® an easy-to-use Windows-compatible
software package gives users the ability to design the
logic and sequences that control the power supplies or
FET driver circuits. The user has control over timing
functions, programmable logic functions and comparator threshold values as well as I/O configurations.
© 2004 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other
brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without
notice.
www.latticesemi.com
1-1
DS1031_04.1
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Power Supply Sequence Controller and Monitor
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The ispPAC-POWR1208 device is specifically designed as a fully-programmable power supply sequencing controller and monitor for managing up to eight separate power supplies, as well as monitoring up to 12 analog inputs or
supplies. The ispPAC-POWR1208 device contains an internal PLD that is programmable by the user to implement
digital logic functions and control state machines. The internal PLD connects to four programmable timers, special
purpose I/O and the programmable monitoring circuit blocks. The internal PLD and timers can be clocked by either
an internal programmable clock oscillator or an external clock source.
The voltage monitors are arranged as 12 independent comparators each with 192 programmable trip point settings. Monitoring levels are set around the following standard voltages: 1.2V, 1.5V, 1.8V, 2.5V, 3.3V or 5.0V.
All 12 voltages can be monitored simultaneously (i.e., continuous-time operation). Other non-standard voltage levels can be accounted for using various scale factors.
For added robustness, the comparators feature a variable hysteresis that scales with the voltage they monitor.
Generally, a larger hysteresis is better. However, as power supply voltages get smaller, that hysteresis increasingly
affects trip-point accuracy. Therefore, the hysteresis is +/-16mV for 5V supplies and scales down to +/-3mV for 1.2V
supplies, or about 0.3% of the trip point.
The programmable logic functions consist of a block of 36 inputs with 81 product terms and 16 macrocells. The
architecture supports the sharing of product terms to enhance the overall usability.
Output pins are configurable in two different modes. There are eight outputs for controlling eight different power
supplies. OUT5-OUT8 are open-drain outputs for interfacing to other circuits. The HVOUT1-HVOUT4 pins can be
programmed individually as open-drain outputs or as high voltage FET gate drivers. As high voltage FET gate
driver outputs, they can be used to drive an external N-Channel MOSFET as a switch to control the voltage rampup of the target board. The four HVOUT drivers have programmable current and voltage levels. Of the eight outputs, four can be configured in the FET gate driver mode or open-drain digital mode.
Figure 1-1. ispPAC-POWR1208 Block Diagram
ispPAC-POWR1208
VMON1
VMON2
VMON3
VMON4
VMON5
VMON6
VMON7
VMON8
VMON9
VMON10
VMON11
VMON12
8
Analog
Inputs
12
Sequence
Controller
CPLD
IN1
U
High Voltage
Outputs
VDD
HVOUT1
HVOUT2
HVOUT3
HVOUT4
4
36 I/P & 16
Macrocell
GLB
5
IN2
IN3
IN4
RESET
Comparator
Outputs
COMP1
COMP2
COMP3
COMP4
COMP5
COMP6
COMP7
COMP8
Digital
Inputs
250kHz
Internal
OSC
4 Timers
CLKIO
1-2
4
Logic
Outputs
OUT5
OUT6
OUT7
OUT8
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Pin Descriptions
Number
1
HVOUT4
HVOUT3
Pin Type
Voltage Range
Description
O/D Output
2.25V-5.5V2
Open-drain Output 4
Current Source
8V-12V3
FET Gate Driver 4
O/D Output
2.25V-5.5V2
Open-drain Output 3
Current Source
8V-12V3
FET Gate Driver 3
O/D Output
2.25V-5.5V2
Open-drain Output 2
Current Source
8V-12V3
FET Gate Driver 2
O/D Output
2.25V-5.5V2
Open-drain Output 1
Current Source
8V-12V3
FET Gate Driver 1
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2
Name
3
HVOUT2
4
HVOUT1
5
VDD
Power
2.25V-5.5V
Main Power Supply
6
IN1
CMOS Input
VDDINP1
Input 1
7
IN2
CMOS Input
VDDINP1
Input 2
8
IN3
CMOS Input
VDDINP1
Input 3
9
IN4
CMOS Input
VDDINP1
Input 4
10
RESET
CMOS input
7
VDD
PLD Reset Input, Active Low
4
Digital Inputs Power Supply
11
VDDINP
Power
2.25V-5.5V
12
OUT5
O/D Output
2.25V-5.5V2
Open-Drain Output
2
Open-Drain Output
13
OUT6
O/D Output
2.25V-5.5V
14
OUT7
O/D Output
2.25V-5.5V2
Open-Drain Output
2
15
OUT8
O/D Output
2.25V-5.5V
Open-Drain Output
16
COMP8
O/D Output
2.25V-5.5V2
VMON8 Comparator Output (Open-Drain)
2
17
COMP7
O/D Output
2.25V-5.5V
VMON7 Comparator Output (Open-Drain)
18
COMP6
O/D Output
2.25V-5.5V2
VMON6 Comparator Output (Open-Drain)
19
COMP5
O/D Output
2.25V-5.5V2
VMON5 Comparator Output (Open-Drain)
20
COMP4
O/D Output
2.25V-5.5V2
VMON4 Comparator Output (Open-Drain)
21
COMP3
O/D Output
2.25V-5.5V2
VMON3 Comparator Output (Open-Drain)
22
COMP2
O/D Output
2.25V-5.5V2
VMON2 Comparator Output (Open-Drain)
23
COMP1
O/D Output
2.25V-5.5V2
VMON1 Comparator Output (Open-Drain)
24
TCK
TTL/LVCMOS Input
VDD6
Test Clock (JTAG Pin)
25
POR
O/D Output
2.25V-5.5V
Power-On-Reset Output
26
CLK
Bi-directional I/O
VDD
Clock Output (Open-Drain) or Clock Input
27
GND
Ground
28
TDO
TTL/LVCMOS Output
VDD
Test Data Out (JTAG Pin)
29
TRST
TTL/LVCMOS Input
VDD
Test Reset, Active Low, 50k Ohm Internal Pull-up
(JTAG Pin, Optional Use)
30
TDI
TTL/LVCMOS Input
VDD
Test Data In, 50k Ohm Internal Pull-up (JTAG Pin)
Test Mode Select, 50k Ohm Internal pull-up (JTAG
Pin)
Ground
31
TMS
TTL/LVCMOS Input
VDD
32
VMON1
Analog Input
0V-5.72V5
5
Voltage Monitor Input 1
VMON2
Analog Input
0V-5.72V
Voltage Monitor Input 2
34
VMON3
Analog Input
0V-5.72V5
Voltage Monitor Input 3
35
VMON4
Analog Input
0V-5.72V5
Voltage Monitor Input 4
36
VMON5
Analog Input
0V-5.72V5
Voltage Monitor Input 5
37
VMON6
Analog Input
0V-5.72V5
Voltage Monitor Input 6
38
VMON7
Analog Input
0V-5.72V5
Voltage Monitor Input 7
U
33
1-3
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Pin Descriptions (Continued)
Number
Name
Pin Type
Voltage Range
Description
Reference for Internal Use, Decoupling Capacitor
(.1uf Required, CREF to GND)
8
39
CREF
Reference
1.17V
40
VMON8
Analog Input
0V-5.72V5
Voltage Monitor Input 8
Analog Input
5
Voltage Monitor Input 9
5
Voltage Monitor Input 10
5
Voltage Monitor Input 11
5
Voltage Monitor Input 12
VMON9
0V-5.72V
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41
42
VMON10
43
VMON11
44
VMON12
Analog Input
0V-5.72V
Analog Input
0V-5.72V
Analog Input
0V-5.72V
1. IN1...IN4 are digital inputs to the PLD. The thresholds for these pins are referenced by the voltage on V DDINP.
2. The 18 open-drain outputs can be powered independently of VDD, the open-drain outputs can be pulled up as high as +6.0V (referenced to
ground). Exception, CLK pin 26 can only be pulled as high as VDD.
3. The four FET driver outputs (when this mode is activated, the corresponding 4 open-drain outputs are disabled) are internally powered and
can source up to 7.5V above VDD.
4. VDDINP can be chosen independent of VDD. It applies only to the four logic inputs IN1-IN4.
5. The 12 VMON inputs can be biased independently of VDD. The 12 VMON inputs can be as high as 7.0V Max (referenced to ground).
6. CLK is the PLD clock output in master mode. It is re-routed as an input in slave mode. The clock mode is set in software during design time.
In output mode it is an open-drain type pin and requires an external pull-up resistor (pull-up voltage must be ≤ VDD). Multiple ispPACPOWR1208 devices can be tied together with one acting as the master, the master can use the internal clock and the slave can be clocked
by the master. The slave needs to be set up using the clock as an input.
7. RESET is an active low INPUT pin, external pull-up resistor to VDD is required. When driven low it resets all internal PLD flip-flops to zero or
one, and may turn “ON” or “OFF” the output pins, including the HVOUT pins depending on the polarity configuration of the outputs in the
PLD. If a reset function is needed for the other devices on the board, the PLD inputs and outputs can be used to generate these signals.
The RESET connected to the POR pin can be used if multiple ispPAC-POWR1208 devices are cascaded together in expansion mode or if
a manual reset button is needed to reset the PLD logic to the initial state. While using the ispPAC-POWR1208 in hot-swap applications it is
recommended that either the RESET pin be connected to the POR pin, or connect a capacitor to ground (such that the time constant is 10
ms with the pull-up resistor) from the RESET pin.
8. The CREF pin requires a 0.1µF capacitor to ground, near the device pin. This reference is used internally by the device. No additional external circuitry should be connected to this pin.
Absolute Maximum Ratings
Absolute maximum ratings are shown in the table below. Stresses above those listed values may cause permanent
damage to the device. Functional operation of the device at these or any other conditions above those indicated in
the operating sections of this specification is not implied.
Symbol
VDD
VDDINP
Parameter
Core supply voltage at pin
1
Digital input supply voltage for IN1-IN4
HVOUTmax HVOUT pin voltage, max = VDD + 9V
Conditions
Min.
Max.
Units
—
-0.5
6.0
V
—
-0.5
6.0
V
—
-0.5
15
V
VIN2
Input voltage applied, digital inputs
—
-0.5
6.0
V
VMON
Input voltage applied, VMON voltage monitor inputs
—
-0.5
7.0
V
VTRI
Tristated or open drain output, external voltage applied (CLK
pin 26 pullup ≤ VDD).
—
-0.5
6.0
V
TS
Storage temperature
—
-65
150
°C
TA
Ambient temperature with power applied
—
-55
125
°C
TSOL
Maximum soldering temperature (10 sec. at 1/16 in.)
—
—
260
°C
U
1. VDDINP is the supply pin that controls logic inputs IN1-IN4 only. Place 0.1µF capacitor to ground and supply the V DDINP pin with appropriate
supply voltage for the given input logic range.
2. Digital inputs are tolerant up to 5.5V, independent of the VDDINP voltage.
1-4
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Recommended Operating Conditions
Symbol
VDD
Parameter
Conditions
Core supply voltage at pin
VDDPROG
VDDINP
1
2
2
Core supply voltage at pin
During E cell programming
Digital input supply voltage for IN1-IN4
Input voltage digital inputs
VMON
Voltage monitor inputs VMON1 - VMON12
Max.
Units
2.25
5.5
V
3.0
5.5
V
2.25
5.5
V
0
5.5
V
0
6.0
V
1000
—
Cycles
-40
+85
°C
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VIN3
Min.
EEPROM, programmed at
VDD = 3.0V to 5.5V
-40°C to +85°C
Erase/Program
Cycles
TAPROG
Ambient temperature during
programming
TA
Ambient temperature
Power applied - Industrial
-40
+85
°C
Power applied - Automotive
-40
+125
°C
1. The ispPAC-POWR1208 device must be powered from 3.0V to 5.5V during programming of the E 2CMOS memory.
2. VDDINP is the supply pin that controls logic inputs IN1-IN4 only. Place 0.1µF capacitor to ground and supply the V DDINP pin with appropriate
supply voltage for the given input logic range.
3. Digital inputs are tolerant up to 5.5V, independent of the VDDINP voltage.
Analog Specifications
Over Recommended Operating Conditions
Symbol
IDD
Parameter
Conditions
Min.
Typ.
Max.
Units
Supply Current
Internal Clock = 250kHz
—
7
15
mA
Conditions
Min.
Typ.
Max.
Units
T = 25°C
—
1.17
—
V
Reference
Symbol
VREF1
Parameter
Reference voltage at CREF pin
1. CREF pin requires a 0.1µF capacitor to ground.
Voltage Monitors
Symbol
Parameter
RIN
Input impedance
VMON Range
Programmable voltage monitor trip
point (192 steps)
VMON Accuracy
Absolute accuracy of any trip point
VMON Tempco1
Temperature drift of any trip point
HYST
PSR
Conditions
T = 25 °C,
VDD = 3.3V
Typ.
Max.
Units
70
100
130
kΩ
1.03
5.72
V
-0.9
+0.9
%
-40°C to +85°C
50
ppm/ °C
-40°C to +125°C
76
ppm/ °C
+/- 0.3% of
trip point
setting
%
0.06
%/V
VDD = 3.3V
Hysteresis of VMON input,
VHYST = HYST*VMON (+/-3 to +/-13mV)
Trip point sensitivity to VDD
Min.
VDD = 3.3V
U
1. See typical performance curves.
1-5
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
High Voltage FET Drivers
Symbol
Parameter
Conditions
VPP Range
Programmable gate driver voltage
(eight steps)
(Note 1)
VPP Accuracy
Absolute accuracy of VPP output
voltage
25°C
Typ.
Max.
Units
8
—
12
V
-10
—
10
%
Gate driver voltage step
(Note 2)
—
0.5
—
V
Programmable ISOURCE current
(32 steps)
FET Driver mode
-40°C to +85°C
0.5
—
50
µA
Programmable ISOURCE current
(16 steps)
FET Driver mode
+85°C to +125°C (Note 3)
5.45
—
50
µA
ISOURCE Accuracy
Absolute accuracy of ISOURCE
current
-40°C to +125°C
ISOURCE > 0.5µA
—
10
—
%
ISTEP
Relative current value, from any
ISOURCE setting to the next
—
15
—
%
RSINK
Gate driver sink/discharge resistor FET Driver in OFF state
when setting FET driver to a LOW VDD = 2.25V
state
—
8
—
kΩ
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VPP Step
Min.
ISOURCE Range
1. Maximum voltage of VPP is not to exceed 7.5V over VDD.
2. The high voltage driver outputs are set in software, HVOUT voltage range is between 8V and 12V. V DD values determine the maximum VPP.
3. For high temperature operation from +85°C to +125°C, the lower HVOUT source current selections (0.5µA to 4.62µA) should not be used to
drive MOSFETs due to increased leakage current to GND. Select gate currents from 5.45µA to 50µA for high temperature use.
Power-On-Reset
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
VLPOR
VDD supply threshold beyond which POR
output is guaranteed to be driven low
VDD ramping up1
—
—
1.15
V
VHPOR
VDD supply threshold above which POR
output is guaranteed driven high, and device VDD ramping up1
initializes
—
—
2.1
V
U
1. POR tests run with 10kΩ resistor pulled up to VDD.
1-6
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
AC/Transient Characteristics
Over Recommended Operating Conditions
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units.
Glitch filter set to 5µs.1
Input VTRIP + 100mV to VTRIP - 100mV
—
5
—
µs
Propagation Delay. Output
transitions after a step input.
Glitch filter set to 20us.1
Input VTRIP + 100mV to VTRIP - 100mV
—
20
—
µs
fCLK
Internal Master Clock
frequency
(Note 2)
230
—
330
kHz
PLDCLK
Range
Programmable frequency range Internal Osc 250kHz
of PLD clock (8 binary steps)
1.95
—
250
kHz
PLDCLKext
Max frequency of applied
external clock source
External clock applied
—
—
1
MHz
Range of programmable
time-out duration (15 steps)
Internal Osc 250kHz
0.03
—
524
ms
Voltage Monitors
Propagation Delay. Output
transitions after a step input.
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tPD5
tPD20
Oscillators
Timers
Timeout
Range
1. See Typical Performance Graphs.
2. fCLK frequency sensitivity with respect to VDD, 0.4%/Volt, typical.
Digital Specifications
Over Recommended Operating Conditions
Symbol
Parameter
Conditions
IIL, IIH
Input or I/O leakage current, no pull-up
0V ≤ VIN ≤ VDDINP or VDD
25 °C
IPU
Input pull-up current (TMS, TDI, TRST)
25 °C
VOL
[OUT5-OUT8]
[COMP1-COMP8]
[HVOUT1-HVOUT4]
ISINKOUT = 4mA
ISINKHVOUT
Min.
Typ.
Max.
Units
+/-10
µA
70
µA
0.4
V
Maximum sink current for HVOUT pins in (Note 1)
open-drain mode [HVOUT1-HVOUT4]
4
mA
ISINKOUT
Maximum sink current for logic outputs
[OUT5-OUT8], [COMP1-COMP8]
(Note 1)
20
mA
ISINKTOTAL
Total combined sink currents from all
outputs [OUT, HVOUT, COMP]
(Note 1)
80
mA
1. [OUT5-OUT8] and [COMP1-COMP8] can sink up to 20mA max. per pin for LEDs, etc. However, output voltage levels may exceed VOL.
Total combined sink currents from all outputs (OUT, HVOUT, COMP) should not exceed ISINKTOTAL.
DC Input Levels: IN1-IN4
VIL (V)
Standard
Min.
VIH (V)
Max.
Min.
Max.
CMOS, LVCMOS3.3, LVTTL, TTL
-0.3
0.8
2.0
5.5
LVCMOS2.5
-0.3
0.7
1.7
5.5
U
Note: VDDINP is the input supply pin for IN1-IN4 digital logic input pins. The logic threshold trip point of IN1-IN4 is dependent on the voltage at
VDDINP.
1-7
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Transient Characteristics
Over Recommended Operating Conditions
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Units
PLD Timing
Minimum pulse width to transition through Applied to IN1-IN4
glitch filter.
20
µs
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Digital Glitch
Filter
tCO
Clock to Out Delay. Rising edge of clock to Stable input before
output transition.
clock edge (Note 1)
tSU
Time that input needs to be present when Data valid before clock
using a registered function with the clock. (Note 1)
20
µs
tH
Time that input needs to be held valid after Hold data after clock
the clock edge when using a registered
function with the clock.
0
µs
tPD
Propagation delay internal to the
embedded PLD
tRST
RESET pulse width
300
90
25
U
1. External clock 1MHz. Open drain outputs with 2k pull-up resistor to VDD.
Note: All the above parameters apply to signal paths from the digital inputs [IN1-IN4].
1-8
ns
ns
µs
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Timing for JTAG Operations
Symbol
Parameter
tCKMIN
Minimum clock period
Conditions
Min
Typ.
Max
Units
1
µs
TCK high time
200
ns
TCK low time
200
ns
tMSS
TMS setup time
15
ns
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tCKH
tCKL
tMSH
TMS hold time
50
ns
tDIS
TDI setup time
15
ns
tDIH
TDI hold time
50
ns
tDOZX
TDO float to valid delay
200
ns
tDOV
TDO valid delay
200
ns
tDOXZ
TDO valid to float delay
200
ns
tRSTMIN
Minimum reset pulse width
40
1
ns
tPWP
Time for a programming operation
40
100
ms
tPWE
Time for an erase operation
40
100
ms
2
1. tPWP represents programming pulse width for a single row of E CMOS cells.
tCKH
tCKL
tPWP, tPWE
tCKMIN
tCK
tCK
tMSS
tMSS tMSH
tMS
tMS
tDIS tDIH
tDI
tDOZH
tDOV
tDOXZ
U
tDO
1-9
tMSS
Program and Erase cycles
executed in Run-Test/Idle
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Typical Performance Graphs
VMON Trip Point Error 25°C
Propagation Delay vs. Overdrive
7000
125
6000
100
Propagation Delay (μs)
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Count
5000
4000
3000
Glitch Filter = 20μs
75
50
2000
25
1000
Glitch Filter = 5μs
0
0
-1
-0.8 -0.6 -0.4 -0.2
0
0.2
0.4
0.6
0.8
1
10
20
Trip Point Error %
50
100
200
Input Overdrive (mV)
Note: Typical propagation delay of VMON inputs to outputs
as a function of overdrive beyond selected trip point.
Typical VMON Comparator Trip Point
Accuracy vs. Temperature
3
2.5
% Error
2
1.5
1
0.5
0
-0.5
-50
0
50
U
Temperature (°C)
1-10
100
150
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Table1-1. VMON Trip Point Table1
1.2 high
1.5 low
1.5 high
1.8 low
1.8 high
2.5 low
2.5 high
3.3 low
3.3 high
5.0 low
5.0 high
1.036
1.202
1.291
1.502
1.549
1.801
2.153
2.500
2.842
3.297
4.299
4.991
1.046
1.213
1.303
1.516
1.564
1.818
2.173
2.524
2.869
3.328
4.340
5.038
1.056
1.225
1.316
1.531
1.579
1.836
2.195
2.549
2.897
3.361
4.383
5.088
1.066
1.237
1.329
1.546
1.595
1.854
2.216
2.574
2.926
3.394
4.426
5.138
1.076
1.249
1.341
1.560
1.609
1.871
2.237
2.597
2.952
3.425
4.466
5.185
1.087
1.261
1.354
1.575
1.625
1.889
2.258
2.622
2.981
3.458
4.509
5.235
1.096
1.272
1.366
1.590
1.639
1.906
2.279
2.646
3.008
3.489
4.550
5.282
1.107
1.284
1.379
1.605
1.655
1.924
2.300
2.671
3.036
3.522
4.593
5.332
1.117
1.295
1.391
1.619
1.669
1.941
2.320
2.694
3.063
3.553
4.633
5.379
1.127
1.307
1.404
1.634
1.685
1.959
2.342
2.719
3.091
3.586
4.676
5.429
1.137
1.319
1.417
1.649
1.700
1.977
2.363
2.744
3.120
3.619
4.719
5.479
1.147
1.331
1.429
1.663
1.715
1.994
2.384
2.768
3.147
3.650
4.760
5.526
1.157
1.343
1.442
1.678
1.730
2.012
2.405
2.793
3.175
3.683
4.803
5.576
1.168
1.355
1.455
1.693
1.746
2.030
2.427
2.818
3.203
3.716
4.846
5.626
1.178
1.366
1.467
1.707
1.761
2.047
2.447
2.841
3.230
3.747
4.886
5.673
1.188
1.378
1.480
1.722
1.776
2.065
2.469
2.866
3.259
3.780
4.929
5.723
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1.2 low
1.All possible comparator trip voltages using internal attenuation settings.
Table 1-1 shows all possible comparator trip point voltage settings. The internal resistive divider allows ranges for
1.2V, 1.8V, 2.5V, 3.3V and 5.0V. There are 192 available voltages, ranging from 1.036V to 5.723V. In addition to the
192 voltage monitor trip points, the user can add additional resistors outside the device to divide down the voltage
and achieve virtually any voltage trip point. This allows the capability to monitor higher voltages such and 12V, 15V,
24V, etc. Voltage monitor trip points are set in the graphical user interface of PAC-Designer software by simple pulldown menus. The user simply selects the given range and corresponding trip point value. Attenuation and reference values are set internally using E2CMOS configuration bits internal to the device.
Figure 1-2 shows a single comparator, the attenuation network and reference used to program the monitor trip
points. Each of the twelve comparators are independently set in the same way.
Theory Of Operation
The ispPAC-POWR1208 incorporates programmable voltage monitors along with digital inputs and outputs as well
as high voltage FET gate drivers to control MOSFETs for ramping up power supply rails. The 16 macrocell PLD
inputs are from the 12 voltage monitors and four digital inputs. There are four embedded programmable timers that
interface with the PLD, along with an internal programmable oscillator.
The 12 independently programmable voltage monitors each have 192 programmable trip points.
U
Figure 1-2 shows a simplified schematic representation of one of these monitors.
1-11
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-2. Voltage Monitors
Reference
Monitor Voltage
To PLD Array
VMON1..VMON12
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3mV
Hysteresis
Each monitor consists of three major subsystems. The core of the monitor is a voltage comparator. This comparator outputs a HIGH signal to the PLD array if the voltage at its positive terminal is greater than that at its negative
terminal, otherwise it outputs a LOW signal. A small amount of hysteresis is provided by the comparator to reduce
the effects of input noise.
The input signal is attenuated by a programmable resistive divider before it is fed into the comparator. This feature
is used to determine the coarse range in which the comparator should trip (e.g. 1.8V, 3.3V, 5V). Twelve possible
ranges are available from the input divider network. The comparator’s negative terminal is obtained from a programmable reference source (Reference), which may be set to one of 16 possible values scaled in approximately
1% increments from each other, allowing for fine tuning of the voltage monitor’s trip points. This combination of
coarse and fine adjustment supports 192 possible trip-point voltages for a given monitor circuit. Because each
monitor’s reference and input divider settings are completely independent of those of the other monitor circuits’, the
user can set any input monitor to any of the 192 available settings.
Comparator Hysteresis
VMON
Range Setting1
Typical Hysteresis on Typical Hysteresis on
Over Voltage Range Under Voltage Range
Units
5.0V
+/- 16.2
+/- 14.0
mV
3.3V
+/- 10.7
+/- 9.2
mV
2.5V
+/- 8.1
+/- 7.0
mV
1.8V
+/- 5.8
+/- 5.0
mV
1.5V
+/- 4.9
+/- 4.2
mV
1.2V
+/- 3.9
+/- 3.4
mV
1. The hysteresis scales depending on the voltage monitor range that is selected. The values shown are typical
and are centered around the nominal voltage trip point for a given range selection.
PLD Architecture
U
The ispPAC-POWR1208 digital logic is composed of an internal PLD that is programmed to perform the sequencing functions. The PLD architecture allows flexibility in designing various state machines and control logic used for
monitoring. The macrocell shown in Figure 1-3 is the heart of the PLD. There are 16 macrocells that can be used to
control the functional states of the sequencer state machine or other control or monitoring logic. The PLD AND
array shown in Figure 1-4 has 36 inputs, and 81 product terms (PTs). The resources from the AND array feed the
16 macrocells. The resources within the macrocells share routing and contain a product-term allocation array. The
1-12
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
product term allocation array greatly expands the PLD’s ability to implement complex logical functions by allowing
logic to be shared between adjacent blocks and distributing the product terms to allow for wider decode functions.
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The basic macrocell has five product terms that feed the OR gate and the flip-flop. The flip-flop in each macrocell is
independently configured. It can be programmed to function as a D-Type or T-Type flip-flop. The combinatorial functions are achieved through the bypass MUX function shown. By having the polarity control XOR, the logic reduction
can be best fit to minimize the number of product terms. The flip-flop’s clock is driven from a common clock that can
be generated from a pre-scaled, on-board clock source or from an external clock. The macrocell also supports
asynchronous reset and preset functions, derived from either product terms, the global reset input or the power-on
reset signal.
Figure 1-3. ispPAC-POWR1208 Macrocell Block Diagram
Global Reset
Power On Reset
Global Polarity Fuse for
Init Product Term
Block Init Product Term
Product Term Allocation
PT4
PT3
PT2
PT1
R
P
PT0
D/T
Q
Polarity
CLK
Clock
U
Macrocell flip-flop provides
D, T, or combinatorial
output with polarity
1-13
To ORP
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-4. PLD and Timer Functional Block Diagram
POR/RESET
MC0
HVOUT1
MC1
HVOUT2
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AND
Array
HVOUT3
MC2
HVOUT4
MC3
VMON[1:12]
Comparators
IN[1:4]
12
MC4
36 Inputs
81 PTs
16 Outputs
MC6
4
MC7
MC8
MC9
MC10
MC11
4
MC12
16
MC13
MC14
MC15
BLK-INIT PT
Timer1
16
Timer2
Timer3
OUT5
MC5
Routing
Pool
Timer4
U
Clock Generation
1-14
OUT6
Output
Routing
Pool
OUT7
OUT8
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Clock and Timer Systems
Figure 1-5 shows a block diagram of the ispPAC-POWR1208’s internal clock and timer systems. The PLD clock can
be programmed with eight different frequencies based on the internal oscillator frequency of 250kHz.
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Figure 1-5. Clock and Timer Block
Timer1
Timer2
Internal
OSC
250kHz
Timer Prescaler
(Time Out Range)
Timer3
Timer4
CLK
PLD Clock
Prescaler
Table 1-2. PLD Clock Prescaler1
PLD Clock Frequency (kHz)
PLD Prescaler Divider
250
1
125
2
62.5
4
31.3
8
15.6
16
7.8
32
3.9
64
2
128
1. Values based on 250kHz clock.
The internal oscillator runs at a fixed frequency of 250kHz. This main signal is then fed to the PLD clock pre-scaler
and also the Timer Clock pre-scaler (Figure 1-5). For the PLD Clock, the main 250kHz oscillator is divided down to
eight selectable frequencies shown in the Table 1-2. The architecture of the clock network allows the PLD clock to
be driven to the CLK pin. This enables the user access to the PLD clock as an output for expansion mode or other
uses of the (CLK) clock pin.
U
Schematically, when the switch is in the upper position, the internal oscillator drives the PLD clock pre-scaler and
the timer pre-scaler. In this mode, the CLK pin is an open-drain output and represents the same frequency as the
PLD clock. This is used when operating other devices (such as “slave” sequencing devices) in a synchronized
mode. When the switch is in the lower position, the CLK pin is an input and must be driven with an external clock
source. When driven from an external source, the same PLD clock pre-scaler is available to this external clock. The
frequencies available for the PLD clock will be the external clock frequency divided by 1, 2, 4, 8, 16, 32, 64 or 128,
depending on the programmable value chosen.
The Timer Clock Pre-Scaler divides the internal 250kHz oscillator (or external clock, if selected) down before it generates the clock for the four programmable timers. The pre-scaler has eight different divider ratios: Divide by 4, 8,
1-15
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
16, 32, 64, 128, 256 and 512 (Table 1-3). After the clock for the timers is divided down, it is used to drive the programmable timers. The four timers share the same timer clock frequency but may have different end count values.
The timers can cover a range from 32us to 524ms for the internal oscillator. Longer delays can be achieved by
using the external clock as an input.
Table 1-3. Timer Values1
÷8
31.2 kHz
÷ 16
15.6 kHz
÷ 32
7.8 kHz
÷ 64
3.9 kHz
÷ 128
2 kHz
÷ 256
1 kHz
÷ 512
0.5 kHz
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÷4
62 kHz
0.032 ms
0.064 ms
0.064 ms
0.128 ms
0.128 ms
0.128 ms
0.256 ms
0.256 ms
0.256 ms
0.256 ms
0.512 ms
0.512 ms
0.512 ms
0.512 ms
0.512 ms
1.024 ms
1.024 ms
1.024 ms
1.024 ms
1.024 ms
1.024 ms
2.048 ms
2.048ms
2.048ms
2.048ms
2.048ms
2.048ms
4.096 ms
2.048ms
4.096 ms
4.096 ms
4.096 ms
4.096 ms
4.096 ms
4.096 ms
4.096 ms
8.192 ms
8.192 ms
8.192 ms
8.192 ms
8.192 ms
8.192 ms
8.192 ms
16.384 ms
16.384 ms
16.384 ms
16.384 ms
16.384 ms
16.384 ms
32.768 ms
32.768 ms
32.768 ms
32.768 ms
32.768 ms
65.536 ms
65.536 ms
65.536 ms
65.536 ms
131.072 ms
131.072 ms
131.072 ms
262.144 ms
262.144 ms
524.288 ms
1. Timer values based on 250kHz clock.
For design entry, the user can select the source for the clock and the PAC-Designer software will calculate the
appropriate delays in an easy-to-select menu format.
The control inputs for Timer1-Timer4 can be driven by any of the 16 PLD macrocell outputs. The reset for the timers
is a function of the Global Reset pin (RESET), a power-on reset or when the timer gate goes low. The waveforms in
Figure 1-6 show the basic timer start and reset functions. Timer and clock divider values are entered in during the
design phase using PAC-Designer software, simple pull-down menus allow the user to select the clocking mode
and the values for the timers and the PLD clock.
Figure 1-6. Timer Waveforms
Timer Gate
Timer Period
Timer Period
(From PLD)
Timer Output
U
(To PLD)
Start
Timer
Timer
Expired
ProgrammableTimer
Delay
Reset
Timer
Start
Timer
Timer
Expired
ProgrammableTimer
Delay
1-16
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Note that if the clock module is configured as “slave” (i.e. the CLK is an input), the actual time-out of the four timers
is determined by the external clock frequency.
Output Configuration Modes
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The output pins for the ispPAC-POWR1208 device are programmable for different functional modes. The four outputs HVOUT1-HVOUT4, can be used as FET gate drivers or be programmed as open-drain digital outputs.
Figure 1-7 explains the details of the gate driver mode.
Figure 1-7. Basic Function Diagram for an Output in Gate Driver Mode
ISource
(0.5-50uA)
VPP
(8-12V)
Output to
IC Pin
≈ 8kΩ
Digital In
From Sequence
Controller
Figure 1-7 shows an output programmed for gate driver mode. In this mode the output is a current source that is
programmable between 0.5µA to 50µA. The maximum voltage that the output level at the pin will rise is also programmable. The levels required depend on the gate-to-source threshold of the FET and the supply voltage. The
maximum level needs to be sufficient to turn the gate-to-source threshold on and accommodate for the voltage of
the board also, since the source pin of the FET is tied to the supply of the target board. When the HVOUT pin is
sourcing current, charging a FET gate, the current is programmable between 0.5µA and 50µA. When the driver is
turned to the off state, the driver will sink current. through the 8kΩ resistor.
Predicting MOSFET Turn-on Time
U
Because the ispPAC-POWR1208’s MOSFET output drivers source a precise and well-defined output current, it
becomes possible to predict MOSFET gate rise times if one knows the value of the load capacitance presented by
the MOSFET being driven. The other method is by relating the total gate charge to the gate-to-source voltage.
1-17
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-8. MOSFET Gate Charge vs. Gate-Source Voltage
VGS, Gate-to-source Voltage (V)
9
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6
3
0
0
20
40
60
QG, Total Gate Charge (nC)
Using this method, it becomes straightforward to estimate the gate rise time for a given charging current. As an
example a MOSFET’s source voltage (VS) will be 3.3V when the device is fully switched on, while the gate voltage
(VG) will be 10V in this condition. The device’s gate-to-source voltage (VGS) will therefore be 6.7V. Reading across
and down the plot of Figure 1-8, a VGS of 6.7V corresponds to ~40 nC of gate charge (QG). Because charge is
equal to the product of current (I) and time (tCHARGE-TIME) when current is constant, gate charging time can be
expressed as:
dQ
(1)
i=
dt
tCHARGE-TIME =
QG
I
(2)
For this example, let us assume a charging current of 10.9µA. Gate charging time is given by:
tCHARGE-TIME =
40 x 10-9C
10.9 x 10-6A
= 3.7 x 1
(3)
U
Validation of this result can be seen in the scope plot shown in Figure 1-9. The top set of traces shows gate rise
times for various (5.5µA to 50.3µA) gate drive currents. The trace labeled 10.9µA shows a 0-10V rise time of just
over 3 milliseconds, which agrees to within 25% of our predicted value, well within the limits of device-to-device
variation.
1-18
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
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Figure 1-9. Gate and Source Voltage Responses for a 3.3V Supply
MOSFET gate capacitance ranges from hundreds to thousands of picoFarads. Refer to the MOSFET manufacturer’s data sheet for values of Cgs (Capacitance gate-to-source). If slower ramps are required, an additional external low leakage capacitor (e.g. a polycarbonate or other poly type capacitor) can be added from the gate to ground.
As a good design practice, it is recommended that a series resistor of 10-100Ω be placed in the gate drive signal
near the FET gate pin.
Charge Pump
Four internal charge pumps are provided to fully support external N-channel FET devices. No external components
are required for the charge pumps. The output voltage is programmable from 8 to 12V in 0.5V steps. The user must
select a high voltage limit no greater than 7.5V above VDD (the software assists this process). This voltage is controlled with an on-chip feedback loop, and is independent of the actual supply voltage.
Programmable Output Voltage Levels for HVOUT1- HVOUT4
There are eight selectable steps for the output voltage of the FET drivers when in FET driver mode. The output pins
HVOUT1-4 are current source outputs, each with a programmable current. The current is programmable in 32 different steps ranging from .5µA to 50µA. The voltage that the pin is capable of driving to is listed in Table 1-4. For
each supply range, the charge-pump range will be set by the software.
Table 1-4. HVOUT Gate Driver Voltage Range
VDD = 2.5V
VDD = 3.3V
VDD = 5V
8
8
8
8.5
8.5
8.5
9
9
9
9.5
9.5
9.5
10
10
10.5
11
U
12
1-19
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
IEEE Standard 1149.1 Interface
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Communication with the ispPAC-POWR1208 is facilitated via an IEEE 1149.1 test access port (TAP). It is used by
the ispPAC-POWR1208 as a serial programming interface, and not for boundary scan test purposes. There are no
boundary scan logic registers in the ispPAC-POWR1208 architecture. This does not prevent the ispPACPOWR1208 from functioning correctly, however, when placed in a valid serial chain with other IEEE 1149.1 compliant devices. Since the ispPAC-POWR1208 is used to powerup other devices, it should be programmed in a separate chain from PLDs, FPGAs or other JTAG devices.
A brief description of the ispPAC-POWR1208 serial interface follows. For complete details of the reference specification, refer to the publication, Standard Test Access Port and Boundary-Scan Architecture, IEEE Std 1149.1-1990
(which now includes IEEE Std 1149.1a-1993).
Overview
An IEEE 1149.1 test access port (TAP) provides the control interface for serially accessing the digital I/O of the ispPAC-POWR1208. The TAP controller is a state machine driven with mode and clock inputs. Under the correct protocol, instructions are shifted into an instruction register, which then determines subsequent data input, data
output, and related operations. Device programming is performed by addressing various registers, shifting data in,
and then executing the respective program instruction. The programming instructions transfer the data into internal
E2CMOS memory. It is these non-volatile memory cells that determine the configuration of the ispPAC-POWR1208.
By cycling the TAP controller through the necessary states, data can also be shifted out of the various registers to
verify the current ispPAC-POWR1208 configuration. Instructions exist to access all data registers and perform
internal control operations.
For compatibility between compliant devices, two data registers are mandated by the IEEE 1149.1 specification.
Other registers are functionally specified, but inclusion is strictly optional. Finally, there are provisions for optional
user data registers that are defined by the manufacturer. The two required registers are the bypass and boundaryscan registers. For ispPAC-POWR1208, the bypass register is a 1-bit shift register that provides a short path
through the device when boundary testing or other operations are not being performed. The ispPAC-POWR1208,
as mentioned earlier has no boundary-scan logic and therefore no boundary scan register. All instructions relating
to boundary scan operations place the ispPAC-POWR1208 in the BYPASS mode to maintain compliance with the
specification.
U
The optional identification (IDCODE) register described in IEEE 1149.1 is also included in the ispPAC-POWR1208.
Six additional user data registers are included in the TAP of the ispPAC-POWR1208 as shown in Figure 1-10. Most
of these additional registers are used to program and verify the analog configuration (CFG) and PLD bits. A status
register is also provided to read the status of the twelve analog comparators.
1-20
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-10. TAP Registers
ANALOG COMPARATOR ARRAY (12 bits)
STATUS REGISTER (12 bits)
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IDCODE REGISTER (32 bits)
UES REGISTER (16 bits)
CFG REGISTER (41 bits)
ANALOG
CONFIGURATION
E2 NON-VOLATILE
MEMORY
(164 bits)
MULTIPLEXER
CFG ADDRESS REGISTER (4 bits)
PLD DATA REGISTER (81 bits)
PLD
AND / ARCH
E2 NON-VOLATILE
MEMORY
(6075 bits)
PLD ADDRESS REGISTER (75 bits)
INSTRUCTION REGISTER (6 bits)
BYPASS REGISTER (1 bit)
TEST ACCESS PORT
(TAP) LOGIC
TDI
TCK
OUTPUT
LATCH
TMS
TDO
TAP Controller Specifics
The TAP is controlled by the Test Clock (TCK) and Test Mode Select (TMS) inputs. These inputs determine whether
an Instruction Register or Data Register operation is performed. Driven by the TCK input, the TAP consists of a
small 16-state controller. In a given state, the controller responds according to the level on the TMS input as shown
in Figure 1-11. Test Data In (TDI) and TMS are latched on the rising edge of TCK, with Test Data Out (TDO) becoming valid on the falling edge of TCK. There are six steady states within the controller: Test-Logic-Reset, Run-Test/
Idle, Shift-Data-Register, Pause-Data-Register, Shift-Instruction-Register, and Pause-Instruction-Register. But
there is only one steady state for the condition when TMS is set high: the Test-Logic-Reset state. This allows a
reset of the test logic within five TCKs or less by keeping the TMS input high. Test-Logic-Reset is the power-on
default state.
U
When the correct logic sequence is applied to the TMS and TCK inputs, the TAP will exit the Test-Logic-Reset state
and move to the desired state. The next state after Test-Logic-Reset is Run-Test/Idle. Until a data or instruction
scan is performed, no action will occur in Run-Test/Idle (steady state = idle). After Run-Test/Idle, either a data or
instruction scan is performed. The states of the Data and Instruction Register blocks are identical to each other differing only in their entry points. When either block is entered, the first action is a capture operation. For the Data
Registers, the Capture-DR state is very simple; it captures (parallel loads) data onto the selected serial data path
(previously chosen with the appropriate instruction). For the Instruction Register, the Capture-IR state will always
load the IDCODE instruction. It will always enable the ID Register for readout if no other instruction is loaded prior
to a Shift-DR operation. This, in conjunction with mandated bit codes, allows a “blind” interrogation of any device in
a compliant IEEE 1149.1 serial chain.
1-21
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-11. TAP States
Select-DR-Scan
0
1
Capture-DR
0
Shift-DR
0
1
Exit1-DR
1
0
1
1
Select-IR-Scan
0
1
Capture-IR
0
Shift-IR
0
1
Exit1-IR
1
0
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1 Test-Logic-Reset
0
1
0 Run-Test/Idle
Pause-DR
Pause-IR
1
0
1
0
Exit2-DR
1
Update-DR
1
0
0
0
Exit2-IR
1
Update-IR
1
0
Note: The value shown adjacent to each state transition represents the signal present
at TMS at the time of a rising edge at TCK.
From the Capture state, the TAP transitions to either the Shift or Exit1 state. Normally the Shift state follows the
Capture state so that test data or status information can be shifted out or new data shifted in. Following the Shift
state, the TAP either returns to the Run-Test/Idle state via the Exit1 and Update states or enters the Pause state via
Exit1. The Pause state is used to temporarily suspend the shifting of data through either the Data or Instruction
Register while an external operation is performed. From the Pause state, shifting can resume by re-entering the
Shift state via the Exit2 state or be terminated by entering the Run-Test/Idle state via the Exit2 and Update states.
If the proper instruction is shifted in during a Shift-IR operation, the next entry into Run-Test/Idle initiates the test
mode (steady state = test). This is when the device is actually programmed, erased or verified. All other instructions
are executed in the Update state.
Test Instructions
U
Like data registers, the IEEE 1149.1 standard also mandates the inclusion of certain instructions. It outlines the
function of three required and six optional instructions. Any additional instructions are left exclusively for the manufacturer to determine. The instruction word length is not mandated other than to be a minimum of two bits, with only
the BYPASS and EXTEST instruction code patterns being specifically called out (all ones and all zeroes respectively). The ispPAC-POWR1208 contains the required minimum instruction set as well as one from the optional
instruction set. In addition, there are several proprietary instructions that allow the device to be configured, verified,
and monitored. For ispPAC-POWR1208, the instruction word length is 6-bits. All ispPAC-POWR1208 instructions
available to users are shown in Table 1-5.
1-22
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Table 1-5. ispPAC-POWR1208 TAP Instruction Table
Instruction
Code
Description
EXTEST
000000
External Test. Defaults to BYPASS.
ADDPLD1
000001
Address PLD address register (75 bits).
DATAPLD
000010
Address PLD column data register (81 bits).
ERASEAND1, 2
000011
Bulk Erase AND array.
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1
1, 2
ERASEARCH
000100
Bulk Erase Architect array.
PROGPLD1, 2
000101
Program PLD column data register into E2.
PROGESF1, 2
000110
Program the Electronic Security Fuse bit.
BYPASS
000111
Bypass (connect TDI to TDO).
001000
Reads PLD column data from E2 to the register (81 bits).
001001
Fast VPP discharge.
ADDCFG
001010
Address CFG array address (4 bits).
DATACFG1
001011
Address CFG data (41 bits).
ERASECFG
001100
Bulk Erase CFG data.
PROGCFG1, 2
001101
Program CFG data register into E2.
READCFG1
001110
Read CFG column data from E2 to the register (41 bits).
CFGBE
010110
Bulk Erase all E2 memory (CFG, PLD, USE, and ESF).
SAFESTATE1
010111
Digital outputs hiZ (FET pulled L)
PROGRAMEN1
011000
Enable program mode (SAFESTATE IO)
IDCODE
011001
Address Identification Code data register (32 bits).
PROGRAMDIS
011010
Disable Program mode (normal IO)
1
READPLD
1
DISCHARGE
1
1, 2
1, 2
ADDSTATUS
011011
Address STATUS register (12 bits).
SAMPLE
011100
Sample/Preload. Default to Bypass.
ERASEUES1, 2
011101
Bulk Erase UES.
SHIFTUES
011110
Reads UES data from E2 and selects the UES register (16 bits).
PROGUES1, 2
011111
Program UES data register into E2.
BYPASS
1xxxxx
Bypass (connect TDI to TDO).
1. When these instructions are executed, the outputs are placed in the same mode as the instruction SAFESTATE (as
described later) to prevent invalid and potentially destructive power supply sequencing.
2. Instructions that erase or program the E2CMOS memory must be executed only when the supply to the device is
maintained at 3.0V to 5.5V.
BYPASS is one of the three required instructions. It selects the Bypass Register to be connected between TDI and
TDO and allows serial data to be transferred through the device without affecting the operation of the ispPACPOWR1208. The IEEE 1149.1 standard defines the bit code of this instruction to be all ones (111111).
The required SAMPLE/PRELOAD instruction dictates the Boundary-Scan Register be connected between TDI
and TDO. The ispPAC-POWR1208 has no boundary scan register, so for compatibility it defaults to the BYPASS
mode whenever this instruction is received. The bit code for this instruction is defined by Lattice as shown in
Table 1-5.
U
The EXTEST (external test) instruction is required and would normally place the device into an external boundary
test mode while also enabling the boundary scan register to be connected between TDI and TDO. Again, since the
ispPAC-POWR1208 has no boundary scan logic, the device is put in the BYPASS mode to ensure specification
compatibility. The bit code of this instruction is defined by the 1149.1 standard to be all zeros (000000).
The optional IDCODE (identification code) instruction is incorporated in the ispPAC-POWR1208 and leaves it in its
functional mode when executed. It selects the Device Identification Register to be connected between TDI and
TDO. The Identification Register is a 32-bit shift register containing information regarding the IC manufacturer,
1-23
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
device type and version code (Figure 1-12). Access to the Identification Register is immediately available, via a
TAP data scan operation, after power-up of the device, or by issuing a Test-Logic-Reset instruction. The bit code for
this instruction is defined by Lattice as shown in Table 1-5.
Figure 1-12. ID Code
MSB
LSB
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XXXX / 0000 0001 0100 0000 / 0000 0100 001 / 1
Part Number
(16 bits)
0140h = ispPAC-POWR1208
Version
(4 bits)
E 2 Configured
JEDEC Manufacturer
Identity Code for
Lattice Semiconductor
(11 bits)
Constant 1
(1 bit)
per 1149.1-1990
ispPAC-POWR1208 Specific Instructions
There are 21 unique instructions specified by Lattice for the ispPAC-POWR1208. These instructions are primarily
used to interface to the various user registers and the E2CMOS non-volatile memory. Additional instructions are
used to control or monitor other features of the device. A brief description of each unique instruction is provided in
detail below, and the bit codes are found in Table 1-5.
ADDPLD – This instruction is used to set the address of the PLD AND/ARCH arrays for subsequent program or
read operations. This instruction also forces the outputs into the SAFESTATE.
DATAPLD – This instruction is used to shift PLD data into the register prior to programming or reading. This
instruction also forces the outputs into the SAFESTATE.
ERASEAND – This instruction will bulk erase the PLD AND array. The action occurs at the second rising edge of
TCK in Run-Test-Idle JTAG state. The device must already be in programming mode (PROGRAMEN instruction).
This instruction also forces the outputs into the SAFESTATE.
ERASEARCH – This instruction will bulk erase the PLD ARCH array. The action occurs at the second rising edge
of TCK in Run-Test-Idle JTAG state. The device must already be in programming mode (PROGRAMEN instruction).
This instruction also forces the outputs into the SAFESTATE.
PROGPLD – This instruction programs the selected PLD AND/ARCH array column. The specific column is preselected by using ADDPLD instruction. The programming occurs at the second rising edge of the TCK in Run-TestIdle JTAG state. The device must already be in programming mode (PROGRAMEN instruction). This instruction
also forces the outputs into the SAFESTATE.
PROGESF – This instruction is used to program the electronic security fuse (ESF) bit. Programming the ESF bit
protects proprietary designs from being read out. The programming occurs at the second rising edge of the TCK in
Run-Test-Idle JTAG state. The device must already be in programming mode (PROGRAMEN instruction). This
instruction also forces the outputs into the SAFESTATE.
READPLD – This instruction is used to read the content of the selected PLD AND/ARCH array column. This specific column is preselected by using ADDPLD instruction. This instruction also forces the outputs into the SAFESTATE.
U
DISCHARGE – This instruction is used to discharge the internal programming supply voltage after an erase or programming cycle and prepares ispPAC-POWR1208 for a read cycle. This instruction also forces the outputs into the
SAFESTATE.
1-24
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
ADDCFG – This instruction is used to set the address of the CFG array for subsequent program or read operations.
This instruction also forces the outputs into the SAFESTATE.
DATACFG – This instruction is used to shift data into the CFG register prior to programming or reading. This
instruction also forces the outputs into the SAFESTATE.
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ERASECFG – This instruction will bulk erase the CFG array. The action occurs at the second rising edge of TCK in
Run-Test-Idle JTAG state. The device must already be in programming mode (PROGRAMEN instruction). This
instruction also forces the outputs into the SAFESTATE.
PROGCFG – This instruction programs the selected CFG array column. This specific column is preselected by
using ADDCFG instruction. The programming occurs at the second rising edge of the TCK in Run-Test-Idle JTAG
state. The device must already be in programming mode (PROGRAMEN instruction). This instruction also forces
the outputs into the SAFESTATE.
READCFG – This instruction is used to read the content of the selected CFG array column. This specific column is
preselected by using ADDCFG instruction. This instruction also forces the outputs into the SAFESTATE.
CFGBE – This instruction will bulk erase all E2CMOS bits (CFG, PLD, UES, and ESF) in the ispPAC-POWR1208.
The device must already be in programming mode (PROGRAMEN instruction). This instruction also forces the outputs into the SAFESTATE.
SAFESTATE – This instruction turns off all of the open-drain output transistors. Pins that are programmed as FET
drivers will be placed in the active low state. This instruction is effective after Update-Instruction-Register JTAG
state.
PROGRAMEN – This instruction enables the programming mode of the ispPAC-POWR1208. This instruction also
forces the outputs into the SAFESTATE.
IDCODE – This instruction connects the output of the Identification Code Data Shift (IDCODE) Register to TDO
(Figure 1-13), to support reading out the identification code.
Figure 1-13. IDCODE Register
TDO
Bit
31
Bit
30
Bit
29
Bit
28
Bit
27
Bit
4
Bit
3
Bit
2
Bit
1
Bit
0
PROGRAMDIS – This instruction disables the programming mode of the ispPAC-POWR1208. The Test-LogicReset JTAG state can also be used to cancel the programming mode of the ispPAC-POWR1208.
ADDSTATUS – This instruction is used to both connect the status register to TDO (Figure 1-14) and latch the 12
voltage monitor (comparator outputs) into the status register. Latching of the 12 comparator outputs into the status
register occurs during Capture-Data-Register JTAG state.
Figure 1-14. Status Register
TDO
VMON
1
VMON
2
VMON
3
VMON
4
VMON
5
VMON
6
VMON
7
VMON
8
VMON
9
VMON
10
VMON
11
VMON
12
U
ERASEUES – This instruction will bulk erase the content of the UES E2CMOS memory. The device must already
be in programming mode (PROGRAMEN instruction). This instruction also forces the outputs into the SAFESTATE.
SHIFTUES – This instruction both reads the E2CMOS bits into the UES register and places the UES register
between the TDI and TDO pins (as shown in Figure U), to support programming or reading of the user electronic
signature bits.
1-25
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-15. UES Register
TDO
Bit
15
Bit
14
Bit
13
Bit
12
Bit
11
Bit
10
Bit
9
Bit
8
Bit
7
Bit
6
Bit
5
Bit
4
Bit
3
Bit
2
Bit
1
Bit
0
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PROGUES – This instruction will program the content of the UES Register into the UES E2CMOS memory. The
device must already be in programming mode (PROGRAMEN instruction). This instruction also forces the outputs
into the SAFESTATE.
Notes:
In all of the descriptions above, SAFESTATE refers both to the instruction and the state of the digital output pins, in
which the open-drains are tri-stated and the FET drivers are pulled low.
Before any of the above programming instructions are executed, the respective E2CMOS bits need to be erased
using the corresponding erase instruction.
Application Example
The ispPAC-POWR1208 device has 12 comparators to monitor various power supply levels. The comparators each
have a programmable trip point that is programmed by the user at design time. The output of the comparators feed
into the PLD logic array to drive the state machine logic or monitor logic. The outputs of comparators
COMP1...COMP8 are also routed to external pins to be monitored directly or can be used to drive additional control
logic if expansion is required. The comparator outputs are open-drain type output buffers and require a pull up
resistor to drive a logic high. All 12 comparators have hysteresis, the hysteresis is dependent on the voltage trip
point scale that is set, it ranges from 3.4mV for the 1.2V monitor supply range to 16.2mV for the 5.0V monitor supply range. The comparators can be set with a trip point from 1.03V to 5.72V, with 192 different values. The application diagram shows a set-up that can monitor and control multiple power supplies. The ispPAC-POWR1208 device
controls FET switches to ramp the supplies at different slew rates and time delays. The digital outputs and inputs
are also used to interface with the board that is being powered up.
U
To reduce the possibility of RF oscillation, a gate resistor (RG) is often inserted in series with the gate of the MOSFET power switch. This resistor should be placed physically close to the MOSFET gate terminal, and connected by
as short a PCB trace as is feasible. An appropriate value for these gate resistors is highly dependent on both the
characteristics of the MOSFET being used and the circumstances of the application, but will often be in the range
of 10Ω to 100Ω.
1-26
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Figure 1-16. Typical Application Example: ispPAC-POWR1208 Driving [4] FET Switches [4] Digital OE/EN
Lines
+
-
DC/DC
+
Supply Gnd
+
-
+
DC/DC
Supply Gnd
+
-
+
DC/DC
Supply Gnd
+5V
+5V
Circuits
RG
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-48V
Primary
-48V
Primary
-48V
Primary
+3.3V
Circuits
+3.3V
RG
+2.5V
Circuits
+2.5V
RG
-48V
Primary
+
+
DC/DC
Supply Gnd
-
+1.8V
+1.8V
Circuits
RG
12 Analog Inputs
10uF
VDD
0.1uF
OE/EN
VDD VDDINP
VMON1
HVOUT1
VMON2
HVOUT2
VMON3
HVOUT3
VMON4
HVOUT4
VMON5
OUT5
VMON6 ispPAC-POWR1208 OUT6
VMON7
OUT7
VMON8
OUT8
Power Sequence
VMON9
Comp1
Controller
VMON10
Comp2
VMON11
Comp3
VMON12
Comp4
CLK
Comp5
Comp6
RESET
Comp7
IN1
Comp8
IN2
POR
CREF
U
IN3
IN4
1-27
DC/DC Supply
or Regulator
OE/EN
DC/DC Supply
or Regulator
3.3V
EN
Digital
Logic
3.3V
EN
0.1uF
Digital
Logic
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Software-Based Design Environment
Design Entry Software
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All functions within the ispPAC-POWR1208 are controlled through a Windows-based software development tool
called PAC-Designer. PAC-Designer is an easy-to-use graphical user interface (Figure 1-17) that allows the user to
set up the ispPAC-POWR1208 to perform given functions, such as timed sequences for power supply and monitor
trip points for the voltage monitor inputs. The software tool gives the user control over how the device drives the
outputs and the functional configurations for all I/O pins. User-friendly dialog boxes are provided to set and edit all
of the analog features of the ispPAC-POWR1208. An extension to the schematic screen is the LogiBuilder design
environment (Figure 1-18) that is used to enter and edit control sequences. Again, user-friendly dialog boxes are
provided in this window to help the designer to quickly implement sequences that take advantage of the powerful
built-in PLD. Once the configurations are chosen and the sequence has been described by the utilities, the device
is ready to program. A standard JTAG interface is used to program the E2CMOS memory. PAC-Designer software
supports downloading the device through the PC’s parallel port. The ispPAC-POWR1208 can be reprogrammed
using the software and ispDOWNLOAD® Cable assembly, to adjust for variations in supply timing, sequencing or
scaling of voltage monitor inputs.
Figure 1-17. PAC-Designer Schematic Screen
The user interface (Figure 1-17) provides access to various internal function blocks within the ispPAC-POWR1208
device.
Analog Inputs: Accesses the programmable threshold trip-points for the comparators and pin naming conventions.
U
Digital Inputs: Digital input naming configurations and digital inputs feed into the internal PLD for the sequence
controller.
Sequence Controller: Incorporates a PLD architecture for designing the state machine to control the order and
functions associated with the user-defined power-up sequence/monitor and control.
1-28
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
FET Drivers: Allows the user to define ramp rates by controlling the current driven to the gate of the external FETs.
Maximum voltage levels and pin names are also set using this functional block. The four FET driver outputs
HVOUT1-4 can also be configured as open-drain digital logic outputs.
Logic Outputs: These pins are configured and assigned in the Logic Output Functional Block. The four digital outputs are open-drain and require a pull-up resistor.
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Internal Clock: The internal clock configuration and clock prescaler values are user-programmable, as well as the
four internal programmable timers used for sequence delay.
User Electronic Signature (UES): Stores 16 bits of ID or board information in non-volatile E2CMOS.
Figure 1-18. PAC-Designer LogiBuilder Screen
Programming of the ispPAC-POWR1208 is accomplished using the Lattice ispDOWNLOAD Cable. This cable connects to the parallel port of a PC and is driven through the PAC-Designer software. The software controls the JTAG
TAP interface and shifts in the JEDEC data bits that set the configuration of all the analog and digital circuitry that
the user has defined during the design process.
Power to the device must be set at 3.0V to 5.5V during programming, once the programming steps have been completed, the power supply to the ispPAC-POWR1208 can be set from 2.5V to 5V. Once programmed, the on-chip
non-volatile E2CMOS bits hold the entire design configuration for the digital circuits, analog circuits and trip points
for comparators etc. Upon powering the device up, the non-volatile E2CMOS bits control the device configuration. If
design changes need to be made such as adjusting comparator trip points or changes to the digital logic functions,
the device is simply re-programmed using the ispDOWNLOAD Cable.
Design Simulation Capability
U
Support for functional simulation of the control sequence is provided using the software tools Waveform Editor and
Waveform Viewer. Both applications are spawned from the LogiBuilder environment of PAC-Designer. The simulation engine combines the design file with a stimulus file (edited by the user with Waveform Editor) to produce an
output file that can be observed with the Waveform Viewer (Figure 1-19).
1-29
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
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Figure 1-19. PAC-Designer Functional Simulation Screen
In-System Programming
The ispPAC-POWR1208 is an in-system programmable device. This is accomplished by integrating all E2CMOS
configuration memory and control logic on-chip. Programming is performed through a 4-wire, IEEE 1149.1 compliant serial JTAG interface. Once a device is programmed, all configuration information is stored on-chip, in non-volatile E2CMOS memory cells. The specifics of the IEEE 1149.1 serial interface and all ispPAC-POWR1208
instructions are described in the JTAG interface section of this data sheet.
User Electronic Signature
The User Electronic Signature (UES), allows the designer to include identification bits or serial numbers inside the
device, stored in E2CMOS memory. The ispPAC-POWR1208 contains 16 UES bits that can be configured by the
user to store unique data such as ID codes, revision numbers or inventory control codes.
Electronic Security
An Electronic Security Fuse (ESF) bit is provided to prevent unauthorized readout of the E2CMOS bit pattern. Once
programmed, this cell prevents further access to the functional user bits in the device. This cell can only be erased
by reprogramming the device; this way the original configuration cannot be examined or copied once programmed.
Usage of this feature is optional.
Production Programming Support
Once a final configuration is determined, an ASCII format JEDEC file can be created using the PAC-Designer software. Devices can then be ordered through the usual supply channels with the user’s specific configuration already
preloaded into the devices. By virtue of its standard interface, compatibility is maintained with existing production
programming equipment, giving customers a wide degree of freedom and flexibility in production planning.
Part Number
Description
PAC-SYSTEM POWR1208
Complete system kit, evaluation board, ispDOWNLOAD Cable and software
ispPAC-POWR1208-EV
Evaluation board only, with components, fully assembled
Evaluation Fixture
U
The ispPAC-POWR1208 Design Kit includes an engineering prototype board that can be connected to the parallel
port of a PC using a Lattice ispDOWNLOAD cable. It demonstrates proper layout techniques for the ispPACPOWR1208 and can be used in real time to check circuit operation as part of the design process. LEDs are supplied to debug designs without involving test equipment. Input and output connections as well as a “breadboard”
circuit area are provided to speed debugging of the circuit. The board includes an area for prototyping other circuits
1-30
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
U
SE D AL
L
I
S
i
FO sp C D
E
O
P
R A N V
N C TI IC
EW -P N ES
O UE
D W D
ES R
1
IG 01
N 4
S /A
and interconnect areas with pads for pins or cables. The user can check out designs on the hardware and make
necessary changes to the design for the function required.
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Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Package Diagrams
44-Pin TQFP (Dimensions in Millimeters)
PIN 1 INDICATOR
0.20 C A-B
D 44X
SE D AL
L
I
S
i
FO sp C D
E
O
P
R A N V
N C TI IC
EW -P N ES
O UE
D W D
ES R
1
IG 01
N 4
S /A
D
3
A
E1
E
B
e
3
D
8
D1
3
TOP VIEW
4X
0.20 H A-B
D
BOTTOM VIEW
SIDE VIEW
SEE DETAIL 'A'
b
0.20 M C A-B
SEATING PLANE
C
GAUGE PLANE
H
D
A
A2
0.25
B
LEAD FINISH
b
0.10 C
B
0.20 MIN.
A1
c1
c
0-7∞
L
1.00 REF.
b
DETAIL 'A'
1
BASE METAL
SECTION B-B
NOTES:
1.
DIMENSIONING AND TOLERANCING PER ANSI Y14.5 - 1982.
2.
ALL DIMENSIONS ARE IN MILLIMETERS.
3.
DATUMS A, B AND D TO BE DETERMINED AT DATUM PLANE H.
4.
DIMENSIONS D1 AND E1 DO NOT INCLUDE MOLD PROTRUSION.
ALLOWABLE MOLD PROTRUSION IS 0.254 MM ON D1 AND E1
DIMENSIONS.
MIN.
NOM.
MAX.
A
-
-
1.60
A1
0.05
-
0.15
A2
1.35
1.40
1.45
SYMBOL
D
12.00 BSC
D1
10.00 BSC
E
12.00 BSC
E1
5. THE TOP OF PACKAGE MAY BE SMALLER THAN THE BOTTOM
OF THE PACKAGE BY 0.15 MM.
L
10.00 BSC
0.45
0.60
0.75
N
44
SECTION B-B:
THESE DIMENSIONS APPLY TO THE FLAT SECTION OF THE
LEAD BETWEEN 0.10 AND 0.25 MM FROM THE LEAD TIP.
e
0.80 BSC
b
0.30
0.37
0.45
7.
A1 IS DEFINED AS THE DISTANCE FROM THE SEATING PLANE
TO THE LOWEST POINT ON THE PACKAGE BODY.
b1
0.30
0.35
0.40
c
0.09
0.15
0.20
8.
EXACT SHAPE OF EACH CORNER IS OPTIONAL.
c1
0.09
0.13
0.16
U
6.
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Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
Part Number Description
ispPAC-POWR1208 - 01XX44X
Device Family
Operating Temperature Range
I = Industrial (-40°C to +85°C)
E = Automotive (-40°C to +125°C)
SE D AL
L
I
S
i
FO sp C D
E
O
P
R A N V
N C TI IC
EW -P N ES
O UE
D W D
ES R
1
IG 01
N 4
S /A
Device Number
Package
T = 44-pin TQFP
TN = Lead-Free 44-pin TQFP
Performance Grade
01 = Standard
ispPAC-POWR1208 Ordering Information
Conventional Packaging
Industrial
Part Number
Package
Pins
TQFP
44
Package
Pins
TQFP
44
ispPAC-POWR1208-01T44I
Automotive
Part Number
ispPAC-POWR1208-01T44E
Lead-Free Packaging
Lead-Free Industrial
Part Number
ispPAC-POWR1208-01TN44I
Package
Pins
TQFP
44
Lead-Free Automotive
Part Number
U
ispPAC-POWR1208-01TN44E
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Package
Pins
TQFP
44
Lattice Semiconductor
ispPAC-POWR1208 Data Sheet
1
2
3
4
5
35
37
36
38
39
40
41
42
34
33
32
31
30
29
VMON2
VMON1
TMS
TDI
TRST
TDO
GND
CLK
POR
TCK
COMP1
SE D AL
L
I
S
i
FO sp C D
E
O
P
R A N V
N C TI IC
EW -P N ES
O UE
D W D
ES R
1
IG 01
N 4
S /A
HVOUT4
HVOUT3
HVOUT2
HVOUT1
VDD
IN1
IN2
IN3
IN4
RESET
VDDINP
43
44
VMON12
VMON11
VMON10
VMON9
VMON8
CREF
VMON7
VMON6
VMON5
VMON4
VMON3
Package Options
6
7
8
9
10
11
ispPAC-POWR1208
44-pin TQFP
28
27
26
25
24
23
12 13 14 15 16 17 18 19 20 21 22
COMP2
COMP3
COMP4
COMP5
COMP6
COMP7
COMP8
OUT8
OUT7
OUT6
OUT5
Revision History
Date
Version
—
—
September 2003
03.1
Change Summary
Previous Lattice releases.
Added 125°C Automotive Range -40°C to +125°C to Features bullets.
Added VMON tempco for 125°C 76PPM to Voltage Monitors table.
IsinkHVout for open drain mode 4mA max to Digital Specifications table.
Isinkout max added for logic outputs OUT5-8 and comparators COMP18 20mA Max (Digital Specifications table).
Spec added for Isinktotal Total combined sink current from all
OUT,HVOUT,COMP 80mA (Digital Specifications table).
Automotive range added to Part Number Description section.
TN suffix added for lead free packaging, Part Number Description section.
Automotive part number added in the Ordering Information section.
January 2004
04.0
Ordering part number added for "Lead Free" packaging, Ordering Information section.
August 2004
04.1
Add R/C network to RESET pin in Application Block Diagram to accomodate hot-swapping.
U
Edited note 7 in Pin Descriptions table to support hot-swapping.
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