CYPRESS CY7C60223-PXC

CY7C601xx
CY7C602xx
enCoRe™ II Low Voltage
Microcontroller
Features
• enCoRe™ II Low Voltage (enCoRe II LV)—“enhanced
Component Reduction”
— Internal crystalless oscillator with support for optional
external clock or external crystal or resonator.
— Configurable IO for real-world interface without external
components
• Enhanced 8-bit microcontroller
•
•
•
•
Improved output drivers to reduce EMI
Operating voltage from 2.7V to 3.6VDC
Operating temperature from 0–70°C
Available in 24/40-pin PDIP, 24-pin SOIC, 24-pin
QSOP/SSOP, 28-pin SSOP and 48-pin SSOP.
• Advanced development tools based on Cypress PSoC®
tools
• Industry-standard programmer support
Applications
— Harvard architecture
— M8C CPU speed can be up to 12 MHz or sourced by an
external crystal, resonator, or clock signal
• Internal memory
The CY7C601xx/CY7C602xx is targeted for the following
applications:
• PC Wireless HID devices
— 256 bytes of RAM
— Mice (optomechanical, optical, trackball)
— 8 Kbytes of Flash including EEROM emulation
• Low power consumption
— Typically 2.25 mA at 3 MHz
— 5 µA sleep
• In-system reprogrammability
— Keyboards
— Presenter tools
• Gaming
— Joysticks
— Gamepad
• General purpose wireless applications
— Allows easy firmware update
• General-purpose I/O ports
— Remote controls
— Up to 36 General Purpose I/O (GPIO) pins
— Barcode scanners
— High current drive on GPIO pins. Configurable 8- or 50mA/pin current sink on designated pins
— Each GPIO port supports high-impedance inputs, configurable pull-up, open drain output, CMOS/TTL inputs, and
CMOS output
— Maskable interrupts on all I/O pins
• SPI serial communication
— Master or slave operation
— Configurable up to 2-Mbit/second transfers.
— Supports half duplex single data line mode for optical
sensors
• 2-channel 8-bit or 1-channel 16-bit capture timer registers.
Capture timer registers store both rising and falling edge
times
— Two registers each for two input pins
— Separate registers for rising and falling edge capture
— Simplifies interface to RF inputs for wireless applications
• Internal low-power wake-up timer during suspend mode
•
•
•
•
— Periodic wake-up with no external components
Programmable Interval Timer interrupts
Reduced RF emissions at 27 MHz and 96 MHz
Watchdog timer (WDT)
Low voltage detection with user-selectable threshold
voltages
Cypress Semiconductor Corporation
Document 38-16016 Rev. *C
•
— POS terminal
— Consumer electronics
— Toys
Introduction
The enCoRe II LV family brings the features and benefits of the
enCoRe II to non-USB applications. The enCoRe II family has
an integrated oscillator that eliminates the external crystal or
resonator, reducing overall cost. Other external components,
such as wake-up circuitry, are also integrated into this chip.
The enCoRe II LV is a low-voltage, low-cost 8-bit Flashprogrammable microcontroller
The enCoRe II LV features up to 36 general-purpose I/O
(GPIO) pins. The I/O pins are grouped into five ports (Port 0 to
4). The pins on Port 0 and Port 1 may each be configured
individually while the pins on Ports 2, 3, and 4 may only be
configured as a group. Each GPIO port supports highimpedance inputs, configurable pull up, open drain output,
CMOS/TTL inputs, and CMOS output with up to five pins that
support programmable drive strength of up to 50 mA sink
current. Additionally, each I/O pin can be used to generate a
GPIO interrupt to the microcontroller. Each GPIO port has its
own GPIO interrupt vector with the exception of GPIO Port 0.
GPIO Port 0 has in addition to the port interrupt vector, three
dedicated pins that have independent interrupt vectors
(P0.2–P0.4).
198 Champion Court
•
San Jose, CA 95134-1709
•
408-943-2600
Revised October 23, 2006
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CY7C601xx
CY7C602xx
The enCoRe II LV features an internal oscillator. Optionally, an
external 1 MHz to 24 MHz crystal can be used to provide a
higher precision reference. The enCoRe II LV also supports
external clock
The enCoRe II LV has 8 Kbytes of Flash for user’s code and
256 bytes of RAM for stack space and user variables.
In addition, enCoRe II LV includes a Watchdog timer, a
vectored interrupt controller, a 16-bit Free-Running Timer with
Capture registers and a 12-bit Programmable Interval Timer.
The Power-on reset circuit detects when power is applied to
the device, resets the logic to a known state, and begins
executing instructions at Flash address 0x0000. When power
falls below a programmable trip voltage it generates a reset or
may be configured to generate an interrupt. There is a Lowvoltage detect circuit that detects when VCC drops below a
programmable trip voltage and it may be configurable to
generate a LVD interrupt to inform the processor about the
low-voltage event. POR and LVD share the same interrupt;
there is no separate interrupt for each. The Watchdog timer
can be used to ensure the firmware never gets stalled in an
infinite loop.
The microcontroller supports 17 maskable interrupts in the
vectored interrupt controller. All interrupts can be masked.
Interrupt sources include LVR/POR, a programmable interval
timer, a nominal 1.024-ms programmable output from the Free
Running Timer, two capture timers, five GPIO Ports, three
GPIO pins, two SPI, a 16-bit free-running timer wrap and an
internal wakeup timer interrupt. The wakeup timer causes
periodic interrupts when enabled. The capture timers interrupt
whenever a new timer value is saved due to a selected GPIO
edge event. A total of eight GPIO interrupts support both TTL
or CMOS thresholds. For additional flexibility, on the edgesensitive GPIO pins, the interrupt polarity is programmable to
be either rising or falling.
The free-running timer generates an interrupt at 1024-µs rate.
It can also generate an interrupt when the free-running counter
overflow occurs—every 16.384 ms. The timer can be used to
measure the duration of an event under firmware control by
reading the timer at the start and at the end of an event, then
calculating the difference between the two values. The two 8bit capture timer registers save a programmable 8-bit range of
the free-running timer when a GPIO edge occurs on the two
capture pins (P0.5, P0.6). The two 8-bit capture registers can
be ganged into a single 16-bit capture register.
The enCoRe II LV supports in-system programming by using
the P1.0 and P1.1 pins as the serial programming mode
interface.
Conventions
In this document, bit positions in the registers are shaded to
indicate which members of the enCoRe II LV family implement
the bits.
Available in all enCoRe II LV family members
CY7C601xx only
Logic Block Diagram
Figure 1. CY7C601xx/CY7C602xx Block Diagram
Interrupt
Control
4 SPI/GPIO
Pins
16 Extended
I/O Pins
16 GPIO
Pins
Wakeup
Timer
Internal
12 MHz
Oscillator
M8C CPU
Clock
Control
POR /
Low-Voltage
Detect
Flash
8K Byte
12-bit Timer
Capture
Timers
Watchdog
Timer
Vdd
Crystal
Oscillator
CY7C601xx only
RAM
256 Byte
Document 38-16016 Rev. *C
Page 2 of 62
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CY7C601xx
CY7C602xx
Packages/Pinouts
Figure 2. Package Configurations
Top View
CY7C60223
24-pin PDIP
P3.0
P3.1
SCLK/P1.4
SMOSI/P1.5
SMISO/P1.6
P1.7
NC
NC
P0.7
TIO1/P0.6
TIO0/P0.5
INT2/P0.4
1
2
3
4
5
6
7
8
9
10
11
12
24
23
22
21
20
19
18
17
16
15
14
13
P1.3/SSEL
P1.2
VDD
P1.1
P1.0
VSS
P2.0
P2.1
P0.0/CLKIN
P0.1/CLKOUT
P0.2/INT0
P0.3/INT1
1
2
3
4
5
6
7
8
9
10
11
12
13
14
28
27
26
25
24
23
22
21
20
19
18
17
16
15
NC
P0.7
TIO1/P0.6
TIO0/P0.5
INT2/P0.4
INT1/P0.3
INT0/P0.2
CLKOUT\P0.1
CLKIN\P0.0
P2.1
P2.0
VSS
1
2
3
4
5
6
7
8
9
10
11
12
24
23
22
21
20
19
18
17
16
15
14
13
NC
P1.7
P1.6/SMISO
P1.5/SMOSI
P1.4/SCLK
P3.1
P3.0
P1.3/SSEL
P1.2
VDD
P1.1
P1.0
VSS
P3.7
P3.6
P3.5
P3.4
P1.7
P1.6/SMISO
P1.5/SMOSI
P1.4/SCLK
P1.3/SSEL
P1.2
VDD
P1.1
P1.0
Document 38-16016 Rev. *C
VDD
P4.1
P4.0
P2.7
P2.6
P2.5
P2.4
P2.3
P2.2
P2.1
P2.0
P0.7
T1O1/P0.6
TIO0/P0.5
INT2/P0.4
INT1/P0.3
INT0/P0.2
CLKOUT/P0.1
CLKIN/P0.0
VSS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
NC
P0.7
TIO1/P0.6
TIO0/P0.5
INT2/P0.4
INT1/P0.3
INT0/P0.2
CLKOUT\P0.1
CLKIN\P0.0
P2.1
P2.0
NC
1
2
3
4
5
6
7
8
9
10
11
12
P1.7
P1.6/SMISO
P1.5/SMOSI
P1.4/SCLK
P3.1
P3.0
P1.3/SSEL
P1.2
VDD
P1.1
P1.0
VSS
24
23
22
21
20
19
18
17
16
15
14
13
CY7C60123
48-pin SSOP
CY7C60123
40-pin PDIP
CY7C60113
28-pin SSOP
VDD
P2.7
P2.6
P2.5
P2.4
P0.7
TIO1/P0.6
TIO0/P0.5
INT2/P0.4
INT1/P0.3
INT0/P0.2
CLKOUT/P0.1
CLKIN/P0.0
VSS
CY7C60223
24-pin QSOP
CY7C60223
24-pin SOIC
VSS
P4.3
P4.2
P3.7
P3.6
P3.5
P3.4
P3.3
P3.2
P3.1
P3.0
P1.7
P1.6/SMISO
P1.5/SMOSI
P1.4/SCLK
P1.3/SSEL
P1.2
VDD
P1.1
P1.0
NC
NC
NC
NC
VDD
P4.1
P4.0
P2.7
P2.6
P2.5
P2.4
P2.3
P2.2
P2.1
P2.0
P0.7
TIO1/P0.6
TIO0/PO.5
INT2/P0.4
INT1/P0.3
INT0/P0.2
CLKOUT/P0.1
CLKIN/P0.0
VSS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
NC
NC
NC
NC
VSS
P4.3
P4.2
P3.7
P3.6
P3.5
P3.4
P3.3
P3.2
P3.1
P3.0
P1.7
P1.6/SMISO
P1.5/SMOSI
P1.4/SCLK
P1.3/SSEL
P1.2
VDD
P1.1
P1.0
Page 3 of 62
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CY7C601xx
CY7C602xx
Pin Assignments
Table 1. Pin Assignments
48
40
28
24
24
SSOP PDIP SSOP QSOP SOIC
7
24
PDIP
3
Name
P4.0
6
2
P4.1
42
38
P4.2
43
39
P4.3
34
30
19
18
1
35
31
20
19
2
36
32
37
33
38
34
24
P3.4
39
35
25
P3.5
40
36
26
P3.6
41
37
27
P3.7
P3.0
Description
GPIO Port 4—configured as a group (nibble)
GPIO Port 3—configured as a group (byte)
P3.1
P3.2
P3.3
15
11
11
11
18
P2.0
14
10
10
10
17
P2.1
13
9
P2.2
12
8
P2.3
GPIO Port 2—configured as a group (byte)
11
7
5
P2.4
10
6
4
P2.5
9
5
3
P2.6
8
4
2
P2.7
25
21
15
14
13
20
P1.0
GPIO Port 1 bit 0
26
22
16
15
14
21
P1.1
GPIO Port 1 bit 1
28
24
18
17
16
23
P1.2
GPIO Port 1 bit 2
29
25
19
18
17
24
P1.3/SSEL
GPIO Port 1 bit 3—Configured individually.
Alternate function is SSEL signal of the SPI bus
30
26
20
21
20
3
P1.4/SCLK
GPIO Port 1 bit 4—Configured individually.
Alternate function is SCLK signal of the SPI bus
31
27
21
22
21
4
P1.5/SMOSI
GPIO Port 1 bit 5—Configured individually.
Alternate function is SMOSI signal of the SPI bus
32
28
22
23
22
5
P1.6/SMISO
GPIO Port 1 bit 6—Configured individually.
Alternate function is SMISO signal of the SPI bus
33
29
23
24
23
6
P1.7
GPIO Port 1 bit 7—Configured individually. TTL voltage threshold
23
19
13
9
9
16
P0.0/CLKIN
GPIO Port 0 bit 0—Configured individually.
On CY7C601xx, optional Clock In when external oscillator is
disabled or external oscillator input when external oscillator is
enabled.
On CY7C602xx, oscillator input when configured as Clock In
If this pin is used as a General Purpose output it will draw
current. This pin should be configured as an input to reduce
current draw.
Document 38-16016 Rev. *C
Page 4 of 62
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CY7C601xx
CY7C602xx
Table 1. Pin Assignments (continued)
48
40
28
24
24
SSOP PDIP SSOP QSOP SOIC
24
PDIP
Name
Description
22
18
12
8
8
15
P0.1/CLKOUT GPIO Port 0 bit 1—Configured individually
On CY7C601xx, optional clock out when external oscillator is
disabled or external oscillator output drive when external oscillator is enabled.
On CY7C602xx, oscillator output when configured as Clock Out.
If this pin is used as a General Purpose output it will draw
current. This pin should be configured as an input to reduce
current draw.
21
17
11
7
7
14
P0.2/INT0
GPIO port 0 bit 2—Configured individually
Optional rising edge interrupt INT0
20
16
10
6
6
13
P0.3/INT1
GPIO port 0 bit 3—Configured individually
Optional rising edge interrupt INT1
19
15
9
5
5
12
P0.4/INT2
GPIO port 0 bit 4—Configured individually
Optional rising edge interrupt INT2
18
14
8
4
4
11
P0.5/TIO0
GPIO port 0 bit 5—Configured individually
Alternate function Timer capture inputs or Timer output TIO0
17
13
7
3
3
10
P0.6/TIO1
GPIO port 0 bit 6—Configured individually
Alternate function Timer capture inputs or Timer output TIO1
16
12
6
2
2
9
P0.7
GPIO port 0 bit 7—Configured individually
1,2,3,
4
1
1
7
NC
No connect
45,46,
47,48
12
24
8
NC
No connect
VDD
Power
VSS
Ground
5
1
17
27
23
1
16
15
22
44
40
14
–
–
–
24
20
28
13
12
19
Document 38-16016 Rev. *C
Page 5 of 62
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CY7C601xx
CY7C602xx
Register Summary
enCoRe II LV Register Summary
Addr
Name
7
6
5
4
3
2
1
0
R/W
Default
00
P0DATA
P0.7
P0.6/TIO1
P0.5/TIO0
P0.4/INT2
P0.3/INT1
P0.2/INT0
P0.1/
CLKOUT
P0.0/CLKIN
bbbbbbbb
00000000
01
P1DATA
P1.7
P1.4/SCLK
P1.3/SSEL
P1.2
P1.1
P1.0
bbbbbbbb
00000000
02
P2DATA
P2.7–P2.2
P2.1–P2.0
bbbbbbbb
00000000
03
P3DATA
P3.7–P3.2
P3.1–P3.0
bbbbbbbb
00000000
04
P4DATA
05
P00CR
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull-up
Enable
06
P01CR
CLK Output
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
07–09
P02CR–
P04CR
Int Act Low
TTL Thresh
Reserved
0A–0B
P05CR–
P06CR
TIO Output
Int Enable
Int Act Low
TTL Thresh
0C
P07CR
Reserved
Int Enable
Int Act Low
TTL Thresh
0D
P10CR
Reserved
Int Enable
Int Act Low
0E
P11CR
Reserved
Int Enable
Int Act Low
0F
P12CR
CLK Output
Int Enable
Int Act Low
TTL
Threshold
10
P13CR
Reserved
Int Enable
Int Act Low
11–13
P14CR–
P16CR
SPI Use
Int Enable
14
P17CR
Reserved
15
P2CR
16
17
P1.6/SMISO P1.5/SMOSI
Reserved
Reserved
P4.3–P4.0
----bbbb
00000000
Output
Enable
-bbbbbbb
00000000
Pull-up
Enable
Output
Enable
bbbbbbbb
00000000
Open Drain
Pull-up
Enable
Output
Enable
--bb-bbb
00000000
Reserved
Open Drain
Pull-up
Enable
Output
Enable
bbbb-bbb
00000000
Reserved
Open Drain
Pull-up
Enable
Output
Enable
-bbb-bbb
00000000
Output
Enable
-bb----b
00000000
Reserved
Reserved
Open Drain
Reserved
Output
Enable
-bb--b-b
00000000
Reserved
Open Drain
Pull-up
Enable
Output
Enable
bbbb-bbb
00000000
Reserved
High Sink
Open Drain
Pull-up
Enable
Output
Enable
-bb-bbbb
00000000
Int Act Low
Reserved
High Sink
Open Drain
Pull-up
Enable
Output
Enable
bbb-bbbb
00000000
Int Enable
Int Act Low
Reserved
High Sink
Open Drain
Pull-up
Enable
Output
Enable
-bb-bbbb
00000000
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull-up
Enable
Output
Enable
-bbbbbbb
00000000
P3CR
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull-up
Enable
Output
Enable
-bbbbbbb
00000000
P4CR
Reserved
Int Enable
Int Act Low
TTL Thresh
Reserved
Open Drain
Pull-up
Enable
Output
Enable
-bbb-bbb
00000000
20
FRTMRL
Free Running Timer [7:0]
bbbbbbbb
00000000
21
FRTMRH
Free Running Timer [15:8]
bbbbbbbb
00000000
22
TCAP0R
Capture 0 Rising [7:0]
rrrrrrrr
00000000
23
TCAP1R
Capture 1 Rising [7:0]
rrrrrrrr
00000000
24
TCAP0F
Capture 0 Falling [7:0]
rrrrrrrr
00000000
25
TCAP1F
Capture 1 Falling [7:0]
rrrrrrrr
00000000
26
PITMRL
Prog Interval Timer [7:0]
rrrrrrrr
00000000
27
PITMRH
28
PIRL
29
PIRH
2A
TMRCR
2B
Reserved
Prog Interval Timer [11:8]
Prog Interval [7:0]
Reserved
First Edge
Hold
Prog Interval [11:8]
8-bit capture Prescale
Cap0 16bit
Enable
TCAPINTE
Reserved
Cap1 Fall
Active
Cap1 Rise
Active
Cap0 Fall
Active
2C
TCAPINTS
Reserved
Cap1 Fall
Active
Cap1 Rise
Active
Cap0 Fall
Active
30
CPUCLKCR
31
TMRCLKCR
32
CLKIOCR
Reserved
34
IOSCTR
foffset[2:0]
TCAPCLK Divider
Document 38-16016 Rev. *C
TCAPCLK Select
XOSC
Select
ITMRCLK Divider
XOSC
Enable
EFTB
Disabled
Gain[4:0]
00000000
00000000
----bbbb
00000000
bbbbb---
00000000
Cap0 Rise
Active
----bbbb
00000000
Cap0 Rise
Active
----bbbb
00000000
CPU
CLK Select
-------b
00000000
Reserved
Reserved
----rrrr
bbbbbbbb
ITMRCLK Select
bbbbbbbb
10001111
CLKOUT Select
---bbbbb
00000000
bbbbbbbb
000ddddd
Page 6 of 62
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CY7C601xx
CY7C602xx
enCoRe II LV Register Summary (continued)
Addr
Name
35
XOSCTR
36
LPOSCTR
3C
SPIDATA
3D
SPICR
7
6
5
4
3
32-kHz Low
Power
Reserved
32-kHz Bias Trim [1:0]
Swap
LSB First
Comm Mode
Reserved
2
XOSC XGM [2:0]
1
0
Reserved
Mode
32-kHz Freq Trim [3:0]
SPIData[7:0]
DA
INT_CLR0 GPIO Port 1 Sleep Timer
INT1
GPIO Port 0
DB
INT_CLR1
TCAP0
DC
INT_CLR2
Reserved
DE
INT_MSK3
ENSWINT
DF
INT_MSK2
Reserved
E1
INT_MSK1
TCAP0
Prog Interval 1-ms Timer
Int Enable
Timer
Int Enable
Int Enable
E0
INT_MSK0 GPIO Port 1 Sleep Timer
Int Enable Int Enable
CPOL
CPHA
SPI Receive
SPI Transmit
Prog Interval 1-ms Timer
Timer
SCLK Select
INT0
POR/LVD
Reserved
GPIO Port 4 GPIO Port 3 GPIO Port 2
Reserved
GPIO Port 4 GPIO Port 3 GPIO Port 2
Int Enable
Int Enable
Int Enable
Reserved
SPI Receive
Int Enable
---bbb-b
000ddddd
b-bbbbbb
d-dddddd
bbbbbbbb
00000000
bbbbbbbb
00000000
bbbbbbbb
00000000
bbb-----
00000000
00000000
16-bit
Counter
Wrap
TCAP1
-bbb-bbb
r-------
00000000
INT2
Int Enable
16-bit
Counter
Wrap Int
Enable
TCAP1
Int Enable
-bbb-bbb
00000000
bbb-----
00000000
bbbbbbbb
00000000
Reserved
GPIO Port 0
Int Enable
Default
INT2
Reserved
INT1
Int Enable
R/W
SPI Transmit
Int Enable
INT0
Int Enable
POR/LVD
Int Enable
E2
INT_VC
Pending Interrupt [7:0]
bbbbbbbb
00000000
E3
RESWDT
Reset Watchdog Timer [7:0]
wwwwwww
w
00000000
--
CPU_A
Temporary Register T1 [7:0]
--------
00000000
--
CPU_X
X[7:0]
--------
00000000
--
CPU_PCL
Program Counter [7:0]
--------
00000000
--
CPU_PCH
Program Counter [15:8]
--------
00000000
--
CPU_SP
F7
CPU_F
FF
CPU_SCR
1E0
OSC_CR0
Stack Pointer [7:0]
Reserved
GIES
Reserved
Reserved
1E3
LVDCR
Reserved
1EB
ECO_TR
Sleep Duty Cycle [1:0]
1E4
VLTCMP
WDRS
No Buzz
--------
00000000
XIO
Super
Carry
Zero
Global IE
---brbbb
00000010
PORS
Sleep
Reserved
Reserved
Stop
r-ccb--b
00010100
CPU Speed [2:0]
--bbbbbb
00000000
VM[2:0]
--bb-bbb
00000000
bb------
00000000
------rr
00000000
Sleep Timer [1:0]
PORLEV[1:0]
Reserved
Reserved
Reserved
Note: In the R/W column,
LVD
PPOR
Table 2. CPU Registers and Register Name
b = Both Read and Write
Register
Register Name
r = Read Only
Flags
CPU_F
w = Write Only
Program Counter
CPU_PC
c = Read/Clear
Accumulator
CPU_A
d = calibration value. Should not change during normal use
Stack Pointer
CPU_SP
CPU Architecture
Index
CPU_X
This family of microcontrollers is based on a high performance,
8-bit, Harvard architecture microprocessor. Five registers
control the primary operation of the CPU core. These registers
are affected by various instructions, but are not directly accessible through the register space by the user.
The 16-bit Program Counter Register (CPU_PC) allows for
direct addressing of the full eight Kbytes of program memory
space.
The Accumulator Register (CPU_A) is the general-purpose
register that holds the results of instructions that specify any
of the source addressing modes.
The Index Register (CPU_X) holds an offset value that is used
in the indexed addressing modes. Typically, this is used to
address a block of data within the data memory space.
Document 38-16016 Rev. *C
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shift operations. The manner in which each flag is changed is
dependent upon the instruction being executed (i.e., AND,
OR, XOR). See Table 19.
The Stack Pointer Register (CPU_SP) holds the address of the
current top-of-stack in the data memory space. It is affected by
the PUSH, POP, LCALL, CALL, RETI, and RET instructions,
which manage the software stack. It can also be affected by
the SWAP and ADD instructions.
CPU Registers
The Flag Register (CPU_F) has three status bits: Zero Flag bit
[1]; Carry Flag bit [2]; Supervisory State bit [3]. The Global
Interrupt Enable bit [0] is used to globally enable or disable
interrupts. The user cannot manipulate the Supervisory State
status bit [3]. The flags are affected by arithmetic, logic, and
Flags Register
The Flags Register can only be set or reset with logical
instruction.
Table 3. CPU Flags Register (CPU_F) [R/W]
Bit #
7
Field
6
5
Reserved
4
3
2
1
0
XIO
Super
Carry
Zero
Global IE
Read/Write
–
–
–
R/W
R
RW
RW
RW
Default
0
0
0
0
0
0
1
0
Bit [7:5]: Reserved
Bit 4: XIO
Set by the user to select between the register banks.
0 = Bank 0
1 = Bank 1
Bit 3: Super
Indicates whether the CPU is executing user code or Supervisor Code. (This code cannot be accessed directly by the user.)
0 = User Code
1 = Supervisor Code
Bit 2: Carry
Set by CPU to indicate whether there has been a carry in the previous logical/arithmetic operation.
0 = No Carry
1 = Carry
Bit 1: Zero
Set by CPU to indicate whether there has been a zero result in the previous logical/arithmetic operation.
0 = Not Equal to Zero
1 = Equal to Zero
Bit 0: Global IE
Determines whether all interrupts are enabled or disabled.
0 = Disabled
1 = Enabled
Note: This register is readable with explicit address 0xF7. The OR F, expr and AND F, expr must be used to set and clear the
CPU_F bits.
Accumulator Register
Table 4. CPU Accumulator Register (CPU_A)
Bit #
7
6
5
Field
4
3
2
1
0
CPU Accumulator [7:0]
Read/Write
–
–
–
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
Bit [7:0]: CPU Accumulator [7:0]
8-bit data value holds the result of any logical/arithmetic instruction that uses a source addressing mode.
Document 38-16016 Rev. *C
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Index Register
Table 5. CPU X Register (CPU_X)
Bit #
7
6
5
4
Field
3
2
1
0
X [7:0]
Read/Write
–
–
–
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
2
1
0
Bit [7:0]: X [7:0]
8-bit data value holds an index for any instruction that uses an indexed addressing mode.
Stack Pointer Register
Table 6. CPU Stack Pointer Register (CPU_SP)
Bit #
7
6
5
4
Field
3
Stack Pointer [7:0]
Read/Write
–
–
–
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
4
3
2
1
0
Bit [7:0]: Stack Pointer [7:0]
8-bit data value holds a pointer to the current top-of-stack.
CPU Program Counter High Register
Table 7. CPU Program Counter High Register (CPU_PCH)
Bit #
7
6
5
Field
Program Counter [15:8]
Read/Write
–
–
–
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
4
3
2
1
0
Bit [7:0]: Program Counter [15:8]
8-bit data value holds the higher byte of the program counter.
CPU Program Counter Low Register
Table 8. CPU Program Counter Low Register (CPU_PCL)
Bit #
7
6
5
Field
Program Counter [7:0]
Read/Write
–
–
–
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Program Counter [7:0]
8-bit data value holds the lower byte of the program counter.
Addressing Modes
Source Immediate
The result of an instruction using this addressing mode is
placed in the A register, the F register, the SP register, or the
X register, which is specified as part of the instruction opcode.
Operand 1 is an immediate value that serves as a source for
the instruction. Arithmetic instructions require two sources; the
Document 38-16016 Rev. *C
second source is the A, X, SP, or F register specified in the
opcode. Instructions using this addressing mode are two bytes
in length.
Table 9. Source Immediate
Opcode
Instruction
Operand 1
Immediate Value
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Examples
Examples
ADD
A,
7
;In this case, the immediate value of 7 is added
with the Accumulator and the result is placed in
the Accumulator.
MOV
X,
8
;In this case, the immediate value of 8 is moved
to the X register.
AND
F,
9
ADD
A,
[X+7]
;In this case, the value in the memory
location at address X + 7 is added
with the Accumulator, and the result
is placed in the Accumulator.
MOV
X,
REG[X+8]
;In this case, the value in the register
space at address X + 8 is moved to
the X register.
;In this case, the immediate value of 9 is logically ANDed with the F register and the result is
placed in the F register.
Destination Direct
Source Direct
The result of an instruction using this addressing mode is
placed in either the A register or the X register, which is
specified as part of the instruction opcode. Operand 1 is an
address that points to a location in either the RAM memory
space or the register space that is the source for the
instruction. Arithmetic instructions require two sources; the
second source is the A register or X register specified in the
opcode. Instructions using this addressing mode are two bytes
in length.
The result of an instruction using this addressing mode is
placed within either the RAM memory space or the register
space. Operand 1 is an address that points to the location of
the result. The source for the instruction is either the A register
or the X register, which is specified as part of the instruction
opcode. Arithmetic instructions require two sources; the
second source is the location specified by Operand 1. Instructions using this addressing mode are two bytes in length.
Table 12.Destination Direct
Opcode
Opcode
Instruction
Operand 1
Instruction
Table 10.Source Direct
Operand 1
Source Address
Destination Address
Examples
ADD
[7],
A
;In this case, the value in the memory
location at address 7 is added with
the Accumulator, and the result is
placed in the memory location at
address 7. The Accumulator is
unchanged.
MOV
REG[8],
A
;In this case, the Accumulator is
moved to the register space location
at address 8. The Accumulator is
unchanged.
Examples
ADD
A,
[7]
;In this case, the value in the RAM memory location at address 7 is added with
the Accumulator, and the result is placed
in the Accumulator.
MOV
X,
REG[8]
;In this case, the value in the register
space at address 8 is moved to the X
register.
Source Indexed
Destination Indexed
The result of an instruction using this addressing mode is
placed in either the A register or the X register, which is
specified as part of the instruction opcode. Operand 1 is added
to the X register forming an address that points to a location in
either the RAM memory space or the register space that is the
source for the instruction. Arithmetic instructions require two
sources; the second source is the A register or X register
specified in the opcode. Instructions using this addressing
mode are two bytes.
The result of an instruction using this addressing mode is
placed within either the RAM memory space or the register
space. Operand 1 is added to the X register forming the
address that points to the location of the result. The source for
the instruction is the A register. Arithmetic instructions require
two sources; the second source is the location specified by
Operand 1 added with the X register. Instructions using this
addressing mode are two bytes in length.
Table 13.Destination Indexed
Table 11.Source Indexed
Opcode
Instruction
Opcode
Operand 1
Operand 1
Instruction
Destination Index
Source Index
Example
ADD
Document 38-16016 Rev. *C
[X+7],
A
;In this case, the value in the memory
location at address X+7 is added with the
Accumulator and the result is placed in
the memory location at address X+7. The
Accumulator is unchanged.
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Table 16.Destination Direct Source Direct
Destination Direct Source Immediate
The result of an instruction using this addressing mode is
placed within either the RAM memory space or the register
space. Operand 1 is the address of the result. The source for
the instruction is Operand 2, which is an immediate value.
Arithmetic instructions require two sources; the second source
is the location specified by Operand 1. Instructions using this
addressing mode are three bytes in length.
Opcode
Operand 1
Instruction
Operand 2
Destination Address
Source Address
Example
MOV
[7],
[8]
;In this case, the value in the memory location
at address 8 is moved to the memory location
at address 7.
Table 14.Destination Direct Source Immediate
Opcode
Instruction
Operand 1
Operand 2
Destination Address
Immediate Value
Examples
ADD [7],
5
;In this case, value in the memory location
at address 7 is added to the immediate
value of 5, and the result is placed in the
memory location at address 7.
MOV REG[8],
6
;In this case, the immediate value of 6 is
moved into the register space location at
address 8.
Source Indirect Post Increment
The result of an instruction using this addressing mode is
placed in the Accumulator. Operand 1 is an address pointing
to a location within the memory space, which contains an
address (the indirect address) for the source of the instruction.
The indirect address is incremented as part of the instruction
execution. This addressing mode is only valid on the MVI
instruction. The instruction using this addressing mode is two
bytes in length. Refer to the PSoC Designer: Assembly
Language User Guide for further details on MVI instruction.
Table 17.Source Indirect Post Increment
Opcode
Destination Indexed Source Immediate
Instruction
The result of an instruction using this addressing mode is
placed within either the RAM memory space or the register
space. Operand 1 is added to the X register to form the
address of the result. The source for the instruction is Operand
2, which is an immediate value. Arithmetic instructions require
two sources; the second source is the location specified by
Operand 1 added with the X register. Instructions using this
addressing mode are three bytes in length.
Table 15.Destination Indexed Source Immediate
Opcode
Instruction
Operand 1
Destination Index
Operand 2
Immediate Value
Examples
ADD
[X+7],
5
;In this case, the value in the memory location at address X+7 is
added with the immediate value of
5, and the result is placed in the
memory location at address X+7.
MOV
REG[X+8],
6
;In this case, the immediate value of
6 is moved into the location in the
register space at address X+8.
Destination Direct Source Direct
The result of an instruction using this addressing mode is
placed within the RAM memory. Operand 1 is the address of
the result. Operand 2 is an address that points to a location in
the RAM memory that is the source for the instruction. This
addressing mode is only valid on the MOV instruction. The
instruction using this addressing mode is three bytes in length.
Document 38-16016 Rev. *C
Operand 1
Source Address Address
Example
MVI
A,
[8]
;In this case, the value in the memory location
at address 8 is an indirect address. The
memory location pointed to by the Indirect
address is moved into the Accumulator. The
indirect address is then incremented.
Destination Indirect Post Increment
The result of an instruction using this addressing mode is
placed within the memory space. Operand 1 is an address
pointing to a location within the memory space, which contains
an address (the indirect address) for the destination of the
instruction. The indirect address is incremented as part of the
instruction execution. The source for the instruction is the
Accumulator. This addressing mode is only valid on the MVI
instruction. The instruction using this addressing mode is two
bytes in length.
Table 18.Destination Indirect Post Increment
Opcode
Operand 1
Instruction
Destination Address Address
Example
MVI
[8],
A
;In this case, the value in the memory
location at address 8 is an indirect;address. The Accumulator is moved
into the memory location pointed to by
the indirect address. The indirect
address is then incremented.
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Instruction Set Summary
The instruction set is summarized in Table 19 numerically and serves as a quick reference. If more information is needed, the
Instruction Set Summary tables are described in detail in the PSoC Designer Assembly Language User Guide (available on the
www.cypress.com web site).
Bytes
Flags
Cycles
Instruction Format
Opcode Hex
Bytes
Flags
Cycles
Instruction Format
Opcode Hex
Bytes
Cycles
Opcode Hex
Table 19.Instruction Set Summary Sorted Numerically by Opcode Order[1, 2]
Instruction Format
Flags
00 15
1 SSC
2D
8
2 OR [X+expr], A
Z
5A
5
2 MOV [expr], X
01
4
2 ADD A, expr
C, Z
2E
9
3 OR [expr], expr
Z
5B
4
1 MOV A, X
02
6
2 ADD A, [expr]
C, Z
2F 10
3 OR [X+expr], expr
Z
5C
4
1 MOV X, A
03
7
2 ADD A, [X+expr]
C, Z
30
9
1 HALT
5D
6
2 MOV A, reg[expr]
Z
04
7
2 ADD [expr], A
C, Z
31
4
2 XOR A, expr
Z
5E
7
2 MOV A, reg[X+expr]
Z
05
8
2 ADD [X+expr], A
C, Z
32
6
2 XOR A, [expr]
Z
5F 10
3 MOV [expr], [expr]
06
9
Z
3 ADD [expr], expr
C, Z
33
7
2 XOR A, [X+expr]
Z
60
5
2 MOV reg[expr], A
07 10
3 ADD [X+expr], expr
C, Z
34
7
2 XOR [expr], A
Z
61
6
2 MOV reg[X+expr], A
08
4
1 PUSH A
35
8
2 XOR [X+expr], A
Z
62
8
3 MOV reg[expr], expr
09
4
2 ADC A, expr
C, Z
36
9
3 XOR [expr], expr
Z
63
9
3 MOV reg[X+expr], expr
0A
6
2 ADC A, [expr]
C, Z
37 10
3 XOR [X+expr], expr
Z
64
4
1 ASL A
C, Z
0B
7
2 ADC A, [X+expr]
C, Z
38
5
2 ADD SP, expr
65
7
2 ASL [expr]
C, Z
0C
7
2 ADC [expr], A
C, Z
39
5
2 CMP A, expr
66
8
2 ASL [X+expr]
C, Z
0D
8
2 ADC [X+expr], A
C, Z
3A
7
2 CMP A, [expr]
67
4
1 ASR A
C, Z
0E
9
3 ADC [expr], expr
C, Z
3B
8
2 CMP A, [X+expr]
68
7
2 ASR [expr]
C, Z
0F 10
3 ADC [X+expr], expr
C, Z
3C
8
3 CMP [expr], expr
69
8
2 ASR [X+expr]
C, Z
10
4
1 PUSH X
3D
9
3 CMP [X+expr], expr
6A
4
1 RLC A
C, Z
11
4
2 SUB A, expr
C, Z
3E 10
2 MVI A, [ [expr]++ ]
6B
7
2 RLC [expr]
C, Z
12
6
2 SUB A, [expr]
C, Z
3F 10
2 MVI [ [expr]++ ], A
6C
8
2 RLC [X+expr]
C, Z
13
7
2 SUB A, [X+expr]
C, Z
40
4
1 NOP
6D
4
1 RRC A
C, Z
14
7
2 SUB [expr], A
C, Z
41
9
3 AND reg[expr], expr
Z
6E
7
2 RRC [expr]
C, Z
15
8
2 SUB [X+expr], A
C, Z
42 10
3 AND reg[X+expr], expr
Z
6F
8
2 RRC [X+expr]
C, Z
16
9
3 SUB [expr], expr
C, Z
43
3 OR reg[expr], expr
Z
70
4
2 AND F, expr
C, Z
17 10
3 SUB [X+expr], expr
C, Z
44 10
3 OR reg[X+expr], expr
Z
71
4
2 OR F, expr
C, Z
18
5
1 POP A
45
3 XOR reg[expr], expr
Z
72
4
2 XOR F, expr
C, Z
19
4
2 SBB A, expr
3 XOR reg[X+expr], expr
Z
73
4
1 CPL A
Z
C, Z
9
9
46 10
if (A=B) Z=1
if (A<B) C=1
Z
Z
Notes
1. Interrupt routines take 13 cycles before execution resumes at interrupt vector table.
2. The number of cycles required by an instruction is increased by one for instructions that span 256-byte boundaries in the Flash memory space.
Document 38-16016 Rev. *C
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Bytes
Flags
Cycles
Instruction Format
Opcode Hex
Bytes
Flags
Cycles
Instruction Format
Opcode Hex
Bytes
Cycles
Opcode Hex
Table 19.Instruction Set Summary Sorted Numerically by Opcode Order[1, 2] (continued)
Instruction Format
Flags
1A
6
2 SBB A, [expr]
C, Z
47
8
3 TST [expr], expr
Z
74
4
1 INC A
C, Z
1B
7
2 SBB A, [X+expr]
C, Z
48
9
3 TST [X+expr], expr
Z
75
4
1 INC X
C, Z
1C
7
2 SBB [expr], A
C, Z
49
9
3 TST reg[expr], expr
Z
76
7
2 INC [expr]
C, Z
1D
8
2 SBB [X+expr], A
C, Z
4A 10
3 TST reg[X+expr], expr
Z
77
8
2 INC [X+expr]
C, Z
1E
9
3 SBB [expr], expr
C, Z
4B
5
1 SWAP A, X
Z
78
4
1 DEC A
C, Z
1F 10
3 SBB [X+expr], expr
C, Z
4C
7
2 SWAP A, [expr]
Z
79
4
1 DEC X
C, Z
20
5
1 POP X
4D
7
2 SWAP X, [expr]
7A
7
2 DEC [expr]
C, Z
21
4
2 AND A, expr
Z
4E
5
1 SWAP A, SP
7B
8
2 DEC [X+expr]
C, Z
22
6
2 AND A, [expr]
Z
4F
4
1 MOV X, SP
23
7
2 AND A, [X+expr]
Z
50
4
2 MOV A, expr
24
7
2 AND [expr], A
Z
51
5
2 MOV A, [expr]
25
8
2 AND [X+expr], A
Z
52
6
2 MOV A, [X+expr]
26
9
Z
7C 13
3 LCALL
Z
7D
7
3 LJMP
Z
7E 10
1 RETI
Z
7F
8
1 RET
5
2 JMP
3 AND [expr], expr
Z
53
5
2 MOV [expr], A
8x
27 10
3 AND [X+expr], expr
Z
54
6
2 MOV [X+expr], A
9x 11
2 CALL
28 11
1 ROMX
Z
55
8
3 MOV [expr], expr
Ax
5
2 JZ
29
4
2 OR A, expr
Z
56
9
3 MOV [X+expr], expr
Bx
5
2 JNZ
2A
6
2 OR A, [expr]
Z
57
4
2 MOV X, expr
Cx
5
2 JC
2B
7
2 OR A, [X+expr]
Z
58
6
2 MOV X, [expr]
Dx
5
2 JNC
2C
7
2 OR [expr], A
Z
59
7
2 MOV X, [X+expr]
Ex
7
2 JACC
Fx 13
Document 38-16016 Rev. *C
2 INDEX
C, Z
Z
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Memory Organization
Flash Program Memory Organization
Figure 3. Program Memory Space with Interrupt Vector Table
after reset
Address
16-bit PC
0x0000
Program execution begins here after a reset
0x0004
POR/LVD
0x0008
INT0
0x000C
SPI Transmitter Empty
0x0010
SPI Receiver Full
0x0014
GPIO Port 0
0x0018
GPIO Port 1
0x001C
INT1
0x0020
Reserved
0x0024
Reserved
0x0028
Reserved
0x002C
Reserved
0x0030
Reserved
0x0034
1-ms Interval timer
0x0038
Programmable Interval Timer
0x003C
Timer Capture 0
0x0040
Timer Capture 1
0x0044
16-bit Free Running Timer Wrap
0x0048
INT2
0x004C
Reserved
0x0050
GPIO Port 2
0x0054
GPIO Port 3
0x0058
GPIO Port 4
0x005C
Reserved
0x0060
Reserved
0x0064
Sleep Timer
0x0068
Program Memory begins here (if below interrupts not used,
program memory can start lower)
0x1FFF
Document 38-16016 Rev. *C
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Data Memory Organization
The CY7C601xx/CY7C602xx microcontrollers provide up to 256 bytes of data RAM
Figure 4. Data Memory Organization
after reset
Address
8-bit PSP
0x00
Top of RAM Memory
Stack begins here and grows upward
0xFF
Flash
This section describes the Flash block of the enCoRe II LV.
Much of the user-visible Flash functionality, including
programming and security, are implemented in the M8C
Supervisory Read Only Memory (SROM). enCoRe II LV Flash
has an endurance of 1000 erase/write cycles and a 10-year
data retention capability.
Flash Programming and Security
All Flash programming is performed by code in the SROM. The
registers that control the Flash programming are only visible
to the M8C CPU when it is executing out of SROM. This makes
it impossible to read, write, or erase the Flash by bypassing
the security mechanisms implemented in the SROM.
Customer firmware can only program the Flash via SROM
calls. The data or code images can be sourced via any
interface with the appropriate support firmware. This type of
programming requires a ‘boot-loader’—a piece of firmware
resident on the Flash. For safety reasons this boot-loader
should not be overwritten during firmware rewrites.
The Flash provides four extra auxiliary rows that are used to
hold Flash block protection flags, boot time calibration values,
configuration tables, and any device values. The routines for
accessing these auxiliary rows are documented in the SROM
section. The auxiliary rows are not affected by the device
erase function.
programming mode and then to use the test queue to issue
Flash access functions in the SROM.
SROM
The SROM holds code that is used to boot the part, calibrate
circuitry, and perform Flash operations (Table 20 lists the
SROM functions). The functions of the SROM may be
accessed in normal user code or operating from Flash. The
SROM exists in a separate memory space from user code.
The SROM functions are accessed by executing the Supervisory System Call instruction (SSC), which has an opcode of
00h. Prior to executing the SSC the M8C’s accumulator needs
to be loaded with the desired SROM function code from
Table 20. Undefined functions will cause a HALT if called from
user code. The SROM functions are executing code with calls;
therefore, the functions require stack space. With the
exception of Reset, all of the SROM functions have a
parameter block in SRAM that must be configured before
executing the SSC. Table 21 lists all possible parameter block
variables. The meaning of each parameter, with regards to a
specific SROM function, is described later in this chapter
.
Table 20.SROM Function Codes
Function Code
Function Name
Stack Space
00h
SWBootReset
0
01h
ReadBlock
7
In-System Programming
02h
WriteBlock
10
enCoRe II LV devices enable this type of in-system
programming by using the P1.0 and P1.1 pins as the serial
programming mode interface. This allows an external
controller to cause the enCoRe II LV part to enter serial
03h
EraseBlock
9
05h
EraseAll
11
Document 38-16016 Rev. *C
06h
TableRead
3
07h
CheckSum
3
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CY7C602xx
Two important variables that are used for all functions are
KEY1 and KEY2. These variables are used to help discriminate between valid SSCs and inadvertent SSCs. KEY1 must
always have a value of 3Ah, while KEY2 must have the same
value as the stack pointer when the SROM function begins
execution. This would be the Stack Pointer value when the
SSC opcode is executed, plus three. If either of the keys do
not match the expected values, the M8C will halt (with the
exception of the SWBootReset function). The following code
puts the correct value in KEY1 and KEY2. The code starts with
a halt, to force the program to jump directly into the setup code
and not run into it.
halt
SSCOP: mov [KEY1], 3ah
mov X, SP
mov A, X
add A, 3
mov [KEY2], A
Table 21.SROM Function Parameters
loops through the number of Flash macros in the product,
executing the following sequence: erase, bulk program all
zeros, erase. After all the user space in all the Flash macros
are erased, a second loop erases and then programs each
protection block with zeros.
SROM Function Descriptions
SWBootReset Function
The SROM function, SWBootReset, is the function that is
responsible for transitioning the device from a reset state to
running user code. The SWBootReset function is executed
whenever the SROM is entered with an M8C accumulator
value of 00h: the SRAM parameter block is not used as an
input to the function. This will happen, by design, after a
hardware reset, because the M8C's accumulator is reset to
00h or when user code executes the SSC instruction with an
accumulator value of 00h. The SWBootReset function will not
execute when the SSC instruction is executed with a bad key
value and a non-zero function code. An enCoRe II LV device
will execute the HALT instruction if a bad value is given for
either KEY1 or KEY2.
Key1/Counter/Return Code
0,F8h
The SWBootReset function verifies the integrity of the
calibration data by way of a 16-bit checksum, before releasing
the M8C to run user code.
Key2/TMP
0,F9h
ReadBlock Function
BlockID
0,FAh
Pointer
0,FBh
The ReadBlock function is used to read 64 contiguous bytes
from Flash: a block.
Clock
0,FCh
Mode
0,FDh
Delay
0,FEh
PCL
0,FFh
Variable Name
SRAM Address
Return Codes
The SROM also features Return Codes and Lockouts.
The first thing this function does is to check the protection bits
and determine if the desired BLOCKID is readable. If read
protection is turned on, the ReadBlock function will exit setting
the accumulator and KEY2 back to 00h. KEY1 will have a
value of 01h, indicating a read failure. If read protection is not
enabled, the function will read 64 bytes from the Flash using
a ROMX instruction and store the results in SRAM using an
MVI instruction. The first of the 64 bytes will be stored in SRAM
at the address indicated by the value of the POINTER
parameter. When the ReadBlock completes successfully the
accumulator, KEY1 and KEY2 will all have a value of 00h.
Return codes aid in the determination of success or failure of
a particular function. The return code is stored in KEY1’s
position in the parameter block. The CheckSum and
TableRead functions do not have return codes because
KEY1’s position in the parameter block is used to return other
data.
Table 23.ReadBlock Parameters
KEY1
0,F8h
3Ah
Table 22.SROM Return Codes
KEY2
0,F9h
Stack Pointer value, when SSC is
executed
BLOCKID
0,FAh
Flash block number
POINTER
0,FBh
First of 64 addresses in SRAM
where returned data should be
stored
Return Code
Description
00h
Success
01h
Function not allowed due to level of protection
on block
02h
Software reset without hardware reset
03h
Fatal error, SROM halted
Read, write, and erase operations may fail if the target block
is read or write protected. Block protection levels are set
during device programming.
The EraseAll function overwrites data in addition to leaving the
entire user Flash in the erase state. The EraseAll function
Document 38-16016 Rev. *C
Name
Address
Description
WriteBlock Function
The WriteBlock function is used to store data in the Flash. Data
is moved 64 bytes at a time from SRAM to Flash using this
function. The first thing the WriteBlock function does is to
check the protection bits and determine if the desired
BLOCKID is writable. If write protection is turned on, the WriteBlock function will exit setting the accumulator and KEY2 back
to 00h. KEY1 will have a value of 01h, indicating a write failure.
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The configuration of the WriteBlock function is straightforward.
The BLOCKID of the Flash block, where the data is stored,
must be determined and stored at SRAM address FAh.
Table 25.EraseBlock Parameters
The SRAM address of the first of the 64 bytes to be stored in
Flash must be indicated using the POINTER variable in the
parameter block (SRAM address FBh). Finally, the CLOCK
and DELAY value must be set correctly. The CLOCK value
determines the length of the write pulse that will be used to
store the data in the Flash. The CLOCK and DELAY values are
dependent on the CPU speed and must be set correctly. Refer
to “Clocking” Section for additional information.
KEY1
0,F8h
3Ah
KEY2
0,F9h
Stack Pointer value, when SSC is
executed
BLOCKID
0,FAh
Flash block number (00h–7Fh)
CLOCK
0,FCh
Clock Divider used to set the erase
pulse width
DELAY
0,FEh
For a CPU speed of 12 MHz set to
56h
Name
Address
Table 24.WriteBlock Parameters
Name
Address
Description
KEY1
0,F8h
3Ah
KEY2
0,F9h
Stack Pointer value, when SSC is
executing
BLOCK ID
0,FAh
8KB Flash block number (00h–7Fh)
4KB Flash block number (00h–3Fh)
3KB Flash block number (00h–2Fh)
POINTER
0,FBh
First 64 addresses in SRAM where
the data to be stored in Flash is
located prior to calling WriteBlock
CLOCK
0,FCh
Clock Divider used to set the write
Pulse width
DELAY
0,FEh
For a CPU speed of 12 MHz set to 56h
EraseBlock Function
The EraseBlock function is used to erase a block of 64
contiguous bytes in Flash. The first thing the EraseBlock
function does is to check the protection bits and determine if
the desired BLOCKID is writable. If write protection is turned
on, the EraseBlock function will exit setting the accumulator
and KEY2 back to 00h. KEY1 will have a value of 01h,
indicating a write failure. The EraseBlock function is only
useful as the first step in programming. Erasing a block will not
cause data in a block to be one hundred percent unreadable.
If the objective is to obliterate data in a block, the best method
is to perform an EraseBlock followed by a WriteBlock of all
zeros.
To set up the parameter block for the EraseBlock function,
correct key values must be stored in KEY1 and KEY2. The
block number to be erased must be stored in the BLOCKID
variable and the CLOCK and DELAY values must be set based
on the current CPU speed.
Description
ProtectBlock Function
The enCoRe II LV devices offer Flash protection on a blockby-block basis. Table 26 lists the protection modes available.
In the table, ER and EW are used to indicate the ability to
perform external reads and writes. For internal writes, IW is
used. Internal reading is always permitted by way of the
ROMX instruction. The ability to read by way of the SROM
ReadBlock function is indicated by SR. The protection level is
stored in two bits according to Table 26. These bits are bit
packed into the 64 bytes of the protection block. Therefore,
each protection block byte stores the protection level for four
Flash blocks. The bits are packed into a byte, with the lowest
numbered block’s protection level stored in the lowest
numbered bits Table 26.
The first address of the protection block contains the
protection level for blocks 0 through 3; the second address is
for blocks 4 through 7. The 64th byte will store the protection
level for blocks 252 through 255.
Table 26.Protection Modes
Mode
Settings
Description
Marketing
00b
SR ER EW IW Unprotected
Unprotected
01b
SR ER EW IW Read protect
Factory upgrade
10b
SR ER EW IW Disable external Field upgrade
write
11b
SR ER EW IW Disable internal
write
7
6
Block n+3
5
4
Block n+2
3
Full protection
2
Block n+1
1
0
Block n
The level of protection is only decreased by an EraseAll, which
places zeros in all locations of the protection block. To set the
level of protection, the ProtectBlock function is used. This
function takes data from SRAM, starting at address 80h, and
ORs it with the current values in the protection block. The
result of the OR operation is then stored in the protection
block. The EraseBlock function does not change the
protection level for a block. Because the SRAM location for the
protection data is fixed and there is only one protection block
per Flash macro, the ProtectBlock function expects very few
variables in the parameter block to be set prior to calling the
function. The parameter block values that must be set, besides
the keys, are the CLOCK and DELAY values.
Document 38-16016 Rev. *C
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Table 27.ProtectBlock Parameters
Name
Address
Description
Table 29.Table Read Parameters
Name
Address
Description
KEY1
0,F8h
3Ah
KEY1
0,F8h
3Ah
KEY2
0,F9h
Stack Pointer value when SSC is
executed
KEY2
0,F9h
Stack Pointer value when SSC is
executed
CLOCK
0,FCh
Clock Divider used to set the write
pulse width
BLOCKID 0,FAh
DELAY
0,FEh
For a CPU speed of 12 MHz set to 56h
EraseAll Function
The table space for the enCoRe II LV is simply a 64-byte row
broken up into eight tables of eight bytes. The tables are
numbered zero through seven. All user and hidden blocks in
the enCoRe II LV parts consist of 64 bytes.
The EraseAll function performs a series of steps that destroy
the user data in the Flash macros and resets the protection
block in each Flash macro to all zeros (the unprotected state).
The EraseAll function does not affect the three hidden blocks
above the protection block, in each Flash macro. The first of
these four hidden blocks is used to store the protection table
for its eight Kbytes of user data.
An internal table holds the Silicon ID and returns the Revision
ID. The Silicon ID is returned in SRAM, while the Revision ID
is returned in the CPU_A and CPU_X registers. The Silicon ID
is a value placed in the table by programming the Flash and is
controlled by Cypress Semiconductor Product Engineering.
The Revision ID is hard-coded into the SROM. The Revision
ID is discussed in more detail later in this section.
The EraseAll function begins by erasing the user space of the
Flash macro with the highest address range. A bulk program
of all zeros is then performed on the same Flash macro, to
destroy all traces of the previous contents. The bulk program
is followed by a second erase that leaves the Flash macro in
a state ready for writing. The erase, program, erase sequence
is then performed on the next lowest Flash macro in the
address space if it exists. Following the erase of the user
space, the protection block for the Flash macro with the
highest address range is erased. Following the erase of the
protection block, zeros are written into every bit of the
protection table. The next lowest Flash macro in the address
space then has its protection block erased and filled with
zeros.
An internal table holds alternate trim values for the device and
returns a one-byte internal revision counter. The internal
revision counter starts out with a value of zero and is incremented each time one of the other revision numbers is not
incremented. It is reset to zero each time one of the other
revision numbers is incremented. The internal revision count
is returned in the CPU_A register. The CPU_X register will
always be set to FFh when trim values are read. The BLOCKID
value, in the parameter block, is used to indicate which table
should be returned to the user. Only the three least significant
bits of the BLOCKID parameter are used by TableRead
function for the enCoRe II LV. The upper five bits are ignored.
When the function is called, it transfers bytes from the table to
SRAM addresses F8h–FFh.
The end result of the EraseAll function is that all user data in
the Flash is destroyed and the Flash is left in an unprogrammed state, ready to accept one of the various write
commands. The protection bits for all user data are also reset
to the zero state.
The M8C’s A and X registers are used by the TableRead
function to return the die’s Revision ID. The Revision ID is a
16-bit value hard-coded into the SROM that uniquely identifies
the die’s design.
The parameter block values that must be set, besides the
keys, are the CLOCK and DELAY values.
Table 28.EraseAll Parameters
Name
Address
Description
KEY1
0,F8h
3Ah
KEY2
0,F9h
Stack Pointer value when SSC is
executed
CLOCK
0,FCh
Clock Divider used to set the write pulse
width
DELAY
0,FEh
For a CPU speed of 12 MHz set to 56h
Checksum Function
The Checksum function calculates a 16-bit checksum over a
user-specifiable number of blocks, within a single Flash macro
(Bank) starting from block zero. The BLOCKID parameter is
used to pass in the number of blocks to calculate the
checksum over. A BLOCKID value of 1 will calculate the
checksum of only block 0, while a BLOCKID value of 0 will
calculate the checksum of all 256-user blocks. The 16-bit
checksum is returned in KEY1 and KEY2. The parameter
KEY1 holds the lower eight bits of the checksum and the
parameter KEY2 holds the upper eight bits of the checksum.
The checksum algorithm executes the following sequence of
three instructions over the number of blocks times 64 to be
checksummed.
TableRead Function
romx
The TableRead function gives the user access to part-specific
data stored in the Flash during manufacturing. It also returns
a Revision ID for the die (not to be confused with the Silicon
ID).
add [KEY1], A
Document 38-16016 Rev. *C
Table number to read
adc [KEY2], 0
Page 18 of 62
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Table 30.Checksum Parameters
Name
Address
Table 31.Oscillator Trim Values vs. Voltage Settings
Description
KEY1
0,F8h
3Ah
KEY2
0,F9h
Stack Pointer value when SSC is
executed
BLOCKID
0,FAh
Supervisory FLASH
User Row Address
Number of Flash blocks to calculate
checksum on
Function
0xC094
24-MHz IOSCTR @ 3.30V
0xC095
24-MHz IOSCTR @ 3.00V
0xC096
24-MHz IOSCTR @ 2.85V
0xC097
24-MHz IOSCTR @ 2.70V
0xC098
32-kHz [email protected]
Clocking
0xC099
32-kHz [email protected]
The enCoRe II LV internal oscillator outputs two frequencies,
the Internal 24 MHz Oscillator and the 32 kHz Low-power
Oscillator.
0xC09A
32-kHz [email protected]
0xC09B
32-kHz [email protected]
The Internal 24 MHz Oscillator is designed such that it may be
trimmed to an output frequency of 24 MHz over temperature
and voltage variation. The Internal 24 MHz Oscillator accuracy
is 24 MHz –22% to +10% (between 0° and 70°C). No external
components are required to achieve this level of accuracy.
When using the 32 kHz oscillator the PITMRL/H should be
read until 2 consecutive readings match before
sending/receiving data. The following firmware example
assumes the developer is interested in the lower byte of the
PIT.
Firmware is responsible for selecting the correct trim values
from the User row to match the power supply voltage in the
end application and writing the values to the trim registers
IOSCTR and LPOSCTR.
Read_PIT_counter:
The internal low-speed oscillator of nominally 32 kHz provides
a slow clock source for the enCoRe II LV in suspend mode,
particularly to generate a periodic wake-up interrupt and also
to provide a clock to sequential logic during power-up and
power-down events when the main clock is stopped. In
addition, this oscillator can also be used as a clocking source
for the Interval Timer clock (ITMRCLK) and Capture Timer
clock (TCAPCLK). The 32 kHz Low-power Oscillator can
operate in low-power mode or can provide a more accurate
clock in normal mode. The Internal 32 kHz Low-power Oscillator accuracy ranges from –53.12% to +56.25%. The 32 kHz
low power oscillator can be calibrated against the internal 24
MHz oscillator or another timing source if desired.
mov A, reg[PITMRL]
enCoRe II LV provides the ability to load new trim values for
the 24-MHz oscillator based on voltage. This allows Vdd to be
monitored and have firmware trim the oscillator based on
voltage present. The IOSCTR register is used to set trim
values for the 24-MHz oscillator. enCoRe II LV is initialized with
3.30V trim values at power-on, then firmware is responsible for
transferring the correct set of trim values to the trim registers
to match the application’s actual Vdd. The 32 kHz oscillator
generally does not require trim adjustments vs. voltage but
trim values for the 32 kHz are also stored in Supervisory ROM.
mov A, [59h]
mov A, reg[PITMRL]
mov [57h], A
mov [58h],A
mov [59h], A
mov A, reg[PITMRL]
mov [60h], A
;;;Start comparison
mov A,[60h]
mov X, [59h]
sub A, [59h]
jz done
mov X, [58h]
sub A, [58h]
jz done
mov X, [57h]
;;;correct data is in memory location 57h
done:
mov [57h], X
ret
The CY7C601xx part can optionally be sourced from an
external crystal oscillator. The external clock driving on CLKIN
range is from 187 KHz to 24 MHz.
Clock Architecture Description
The enCoRe II LV clock selection circuitry allows the selection
of independent clocks for the CPU, Interval Timers and
Capture Timers.
Document 38-16016 Rev. *C
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On the CY7C601xx, the external oscillator can be sourced by
the crystal oscillator or when the crystal oscillator is disabled it
is sourced directly from the CLKIN pin. The external crystal
oscillator is fed through the EFTB block, which can optionally
be bypassed.
CPU Clock
The CPU clock, CPUCLK, can be sourced from the external
crystal oscillator, the Internal 24 MHz Oscillator, or the Internal
32 kHz Low-power Oscillator. The selected clock source can
optionally be divided by 2n-1 where n is 0–7 (see Table 33).
When it is not being used by the external crystal oscillator, the
CLKOUT pin can be driven from one of many sources. This is
used for test and can also be used in some applications. The
sources that can drive the CLKOUT are:
• CLKIN after the optional EFTB filter
• Internal 24 MHz Oscillator
• Internal 32 kHz Oscillator
• CPUCLK after the programmable divider
Figure 5. CPU Clock Block Diagram
XOSC
SEL
EN
P0.1
CLKOUT
XTAL OSC
1-24MHz
P0.0
CLKIN
EFTB
CY7C601xx only
CLK_EXT
MUX
CY7C601xx
only
Crystal Oscillator Disabled
LP OSC
32-KHz
CLK_32KHz
CPUCLK
SEL
CLK_EXT
SCALE
(divide by 2n, n = 0-5,7)
CLK_CPU
Doubler
CLK_HS
MUX
CLK_24MHz
Document 38-16016 Rev. *C
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Table 32.CPU Clock Config (CPUCLKCR) [0x30] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Reserved
CPUCLK Select
Read/Write
–
–
–
–
–
–
–
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:1]: Reserved
Bit 0: CPU CLK Select
0 = Internal 24 MHz Oscillator.
1 = External crystal oscillator—External crystal oscillator on CLKIN and CLKOUT if the external crystal oscillator is enabled,
CLKIN input if the external crystal oscillator is disabled.
Note: the CPU speed selection is configured using the OSC_CR0 Register (Table 6.)
Table 33.OSC Control 0 (OSC_CR0) [0x1E0] [R/W]
Bit #
7
Field
6
5
Reserved
4
No Buzz
3
2
Sleep Timer [1:0]
1
0
CPU Speed [2:0]
Read/Write
–
–
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:6]: Reserved
Bit 5: No Buzz
During sleep (the Sleep bit is set in the CPU_SCR Register—Table 39), the LVD and POR detection circuit is turned on periodically to detect any POR and LVD events on the VCC pin (the Sleep Duty Cycle bits in the ECO_TR are used to control the duty
cycle—Table 43). To facilitate the detection of POR and LVD events, the No Buzz bit is used to force the LVD and POR detection
circuit to be continuously enabled during sleep. This results in a faster response to an LVD or POR event during sleep at the
expense of a slightly higher than average sleep current. Obtaining the absolute lowest power usage in sleep mode requires the
No Buzz bit be clear.
0 = The LVD and POR detection circuit is turned on periodically as configured in the Sleep Duty Cycle.
1 = The Sleep Duty Cycle value is overridden. The LVD and POR detection circuit is always enabled.
Note: The periodic Sleep Duty Cycle enabling is independent with the sleep interval shown in the Sleep [1:0] bits below.
Bit [4:3]: Sleep Timer [1:0]
Sleep Timer
[1:0]
Sleep Timer Clock
Sleep Period
Frequency (Nominal) (Nominal)
Watchdog Period
(Nominal)
00
512 Hz
1.95 ms
6 ms
01
64 Hz
15.6 ms
47 ms
10
8 Hz
125 ms
375 ms
11
1 Hz
1 sec
3 sec
Note: Sleep intervals are approximate.
Bit [2:0]: CPU Speed [2:0]
The enCoRe II LV may operate over a range of CPU clock speeds. The reset value for the CPU Speed bits is zero; therefore,
the default CPU speed is 3 MHz.
CPU Speed
[2:0]
CPU when Internal
Oscillator is selected
External Clock
000
3 MHz (Default)
Clock In/8
001
6 MHz
Clock In/4
010
12 MHz
Clock In/2
011
Reserved
Reserved
100
1.5 MHz
Clock In/16
101
750 KHz
Clock In/32
110
187 KHz
Clock In/128
111
Reserved
Reserved
Document 38-16016 Rev. *C
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Table 34.Clock I/O Config (CLKIOCR) [0x32] [R/W]
Bit #
7
6
5
Reserved
Field
4
3
2
XOSC
Select
XOSC
Enable
EFTB
Disabled
1
0
CLKOUT Select
Read/Write
–
–
–
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:5]: Reserved
Bit 4: XOSC Select
This bit, when set, selects the external crystal oscillator clock as clock source of external clock. Care needs to be taken while
selecting the crystal oscillator clock. First enable the crystal oscillator and wait for few cycles, which is oscillator stabilization
period. Then select the crystal clock as clock source. Similarly, while deselect crystal clock, first deselect crystal clock as clock
source then disable the crystal oscillator
0 = Not select external crystal oscillator clock
1 = Select the external crystal oscillator clock
Bit 3: XOSC Enable
This bit is only available on the CY7C601xx
This bit when set enables the external crystal oscillator. The external crystal oscillator shares pads CLKIN and CLKOUT with
two GPIOs—P0.0 and P0.1, respectively. When the external crystal oscillator is enabled, the CLKIN signal comes from the
external crystal oscillator block and the output enables on the GPIOs for P0.0 and P0.1 are disabled, eliminating the possibility
of contention. When the external crystal oscillator is disabled the source for CLKIN signal comes from the P0.0 GPIO input.
0 = Disable the external oscillator
1 = Enable the external oscillator
Note: The external crystal oscillator start-up time takes up to 2 ms.
Bit 2: EFTB Disabled
This bit is only available on the CY7C601xx.
0 = Enable the EFTB filter
1 = Disable the EFTB filter, causing CLKIN to bypass the EFTB filter
Bit [1:0]: CLKOUT Select
0 0 = Internal 24 MHz Oscillator
0 1 = External crystal oscillator – external crystal oscillator on CLKIN and CLKOUT if the external crystal oscillator is enabled,
CLKIN input if the external oscillator is disabled.
1 0 = Internal 32 kHz Low-power Oscillator
1 1 = CPUCLK
Interval Timer Clock (ITMRCLK)
The Interval Timer clock (ITMRCLK), can be sourced from the
external crystal oscillator, the Internal 24 MHz Oscillator, the
Internal 32 kHz Low-power Oscillator, or the Timer Capture
clock. A programmable prescaler of 1, 2, 3, 4 then divides the
selected source. The 12-bit Programmable Interval Timer is a
simple down counter with a programmable reload value. It
provides a 1-µs resolution by default. When the down counter
reaches zero, the next clock is spent reloading. The reload
value can be read and written while the counter is running, but
care should be taken to ensure that the counter does not
unintentionally reload while the 12-bit reload value is only
partially stored—i.e., between the two writes of the 12-bit
value. The Programmable interval timer generates an interrupt
to the CPU on each reload.
Document 38-16016 Rev. *C
The parameters to be set will show up on the device editor
view of PSoC Designer once you place the enCoRe II LV timer
user module. The parameters are PITIMER_Source and
PITIMER_Divider. The PITIMER_Source is the clock to the
timer and the PITIMER_Divider is the value the clock is divided
by.
The interval register (PITMR) holds the value that is loaded
into the PIT counter on terminal count.
The Programmable Interval Timer resolution is configurable.
For example:
TCAPCLK divide by x of CPU clock (for example TCAPCLK
divide by 2 of a 24 MHz CPU clock will give a frequency of
12 MHz)
ITMRCLK divide by x of TCAPCLK (for example, ITMRCLK
divide by 3 of TCAPCLK is 4 MHz so resolution is 0.25 µs)
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Figure 6. Programmable Interval Timer Block Diagram
Configuration
Status and
Control
System Clock
12-bit reload
value
12-bit down
counter
Clock Timer
12-bit reload
control
Interrupt
Controller
Timer Capture Clock (TCAPCLK)
The Timer Capture clock (TCAPCLK) can be sourced from the external crystal oscillator, the Internal 24 MHz Oscillator or the
Internal 32 kHz Low-power Oscillator. A programmable prescaler of 2, 4, 6, or 8 then divides the selected source.
Figure 7. Timer Capture Block Diagram
System Clock
Configuration Status
and Control
Captimer Clock
16-bit counter
Prescale Mux
Capture Registers
1ms
timer
Overflow
Interrupt
Capture0 Int
Capture1 Int
Interrupt Controller
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Table 35.Timer Clock Config (TMRCLKCR) [0x31] [R/W]
Bit #
7
Field
TCAPCLK Divider
6
5
4
TCAPCLK Select
3
2
1
ITMRCLK Divider
0
ITMRCLK Select
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
1
0
0
0
1
1
1
1
Bit [7:6]: TCAPCLK Divider [1:0]
TCAPCLK Divider controls the TCAPCLK divisor.
0 0 = Divider Value 2
0 1 = Divider Value 4
1 0 = Divider Value 6
1 1 = Divider Value 8
Bit [5:4]: TCAPCLK Select
The TCAPCLK Select field controls the source of the TCAPCLK.
0 0 = Internal 24 MHz Oscillator
0 1 = External crystal oscillator—external crystal oscillator on CLKIN and CLKOUT if the external crystal oscillator is enabled,
CLKIN input if the external crystal oscillator is disabled (the XOSC Enable bit of the CLKIOCR Register is cleared—Table 34.)
1 0 = Internal 32 kHz Low-power Oscillator
1 1 = TCAPCLK Disabled
Note: The 1024-µs interval timer is based on the assumption that TCAPCLK is running at 4 MHz. Changes in TCAPCLK
frequency will cause a corresponding change in the 1024-µs interval timer frequency.
Bit [3:2]: ITMRCLK Divider
ITMRCLK Divider controls the ITMRCLK divisor.
0 0 = Divider value of 1
0 1 = Divider value of 2
1 0 = Divider value of 3
1 1 = Divider value of 4
Bit [1:0]: ITMRCLK Select
0 0 = Internal 24 MHz Oscillator
0 1 = External crystal oscillator—external crystal oscillator on CLKIN and CLKOUT if the external crystal oscillator is enabled,
CLKIN input if the external crystal oscillator is disabled.
1 0 = Internal 32 kHz Low-power Oscillator
1 1 = TCAPCLK
Note: Changing the source of TMRCLK requires that both the source and destination clocks be running. Attempting to change
the clock source away from TCAPCLK after that clock has been stopped will not be successful.
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Internal Clock Trim
Table 36.IOSC Trim (IOSCTR) [0x34] [R/W]
Bit #
7
6
Field
5
4
3
foffset[2:0]
2
1
0
Gain[4:0]
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
D
D
D
D
D
The IOSC Calibrate register is used to calibrate the internal oscillator. The reset value is undefined but during boot the SROM
writes a calibration value that is determined during manufacturing test. The “D” indicates that the default value is trimmed to
24 MHz @ 3.30V at power on.
Bit [7:5]: foffset [2:0]
This value is used to trim the frequency of the internal oscillator. These bits are not used in factory calibration and will be zero.
Setting each of these bits causes the appropriate fine offset in oscillator frequency.
foffset bit 0 = 7.5 kHz
foffset bit 1 = 15 kHz
foffset bit 2 = 30 kHz
Bit [4:0]: Gain [4:0]
The effective frequency change of the offset input is controlled through the gain input. A lower value of the gain setting increases
the gain of the offset input. This value sets the size of each offset step for the internal oscillator. Nominal gain change
(KHz/offsetStep) at each bit, typical conditions (24 MHz operation):
Gain bit 0 = –1.5 kHz
Gain bit 1 = –3.0 kHz
Gain bit 2 = –6 kHz
Gain bit 3 = –12 kHz
Gain bit 4 = –24 kHz
External Clock Trim
Table 37.XOSC Trim (XOSCTR) [0x35] [R/W]
Bit #
7
6
Field
5
4
Reserved
3
2
XOSC XGM [2:0]
1
0
Reserved
Mode
Read/Write
–
–
–
R/W
R/W
R/W
–
R/W
Default
0
0
0
D
D
D
–
D
This register is used to calibrate the external crystal oscillator. The reset value is undefined but during boot the SROM writes a
calibration value that is determined during manufacturing test. This is the meaning of ‘D’ in the Default field.
Bit [7:5]: Reserved
Bit [4:2]: XOSC XGM [2:0]
Amplifier transconductance setting. The Xgm settings are recommended for resonators with frequencies of interest for the
enCoRe II LV as below:
Resonator
XGM Setting
Worst Case R (Ohms)
6 MHz Crystal
001
403
12 MHz Crystal
011
201
Reserved
111
-
6 MHz Ceramic
001
70.4
12 MHz Ceramic
011
41
Bit 1: Reserved
Bit 0: Mode
0 = Oscillator Mode
1 = Fixed Maximum Bias test Mode
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LPOSC Trim
Table 38.LPOSC Trim (LPOSCTR) [0x36] [R/W]
Bit #
7
6
Field
32 kHz Low
Power
Reserved
5
4
3
Read/Write
R/W
–
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
–
D
D
D
D
D
D
32 kHz Bias Trim [1:0]
2
1
0
32 kHz Freq Trim [3:0]
This register is used to calibrate the 32 kHz Low-speed Oscillator. The reset value is undefined but during boot the SROM writes
a calibration value that is determined during manufacturing test. This is the meaning of ‘D’ in the Default field. The trim value can
be adjusted vs. voltage as noted in Table 32.
Bit 7: 32 kHz Low Power
0 = The 32 kHz Low-speed Oscillator operates in normal mode.
1 = The 32 kHz Low-speed Oscillator operates in a low-power mode. The oscillator continues to function normally but with reduced
accuracy.
Bit 6: Reserved
Bit [5:4]: 32 kHz Bias Trim [1:0]
These bits control the bias current of the low-power oscillator.
0 0 = Mid bias
0 1 = High bias
1 0 = Reserved
1 1 = Reserved
Important Note: Do not program the 32 kHz Bias Trim [1:0] field with the reserved 10b value as the oscillator does not oscillate
at all corner conditions with this setting.
Bit [3:0]: 32 kHz Freq Trim [3:0]
These bits are used to trim the frequency of the low-power oscillator.
CPU Clock During Sleep Mode
Reset
When the CPU enters sleep mode the CPUCLK Select (Bit 0,
Table 32) is forced to the Internal Oscillator, and the oscillator
is stopped. When the CPU comes out of sleep mode it is
running on the internal oscillator. The internal oscillator
recovery time is three clock cycles of the Internal 32 kHz Lowpower Oscillator.
The microcontroller supports two types of resets: Power-on
Reset (POR) and Watchdog Reset (WDR). When reset is
initiated, all registers are restored to their default states and all
interrupts are disabled.
If the system requires the CPU to run off the external clock
after awaking from sleep mode, firmware will need to switch
the clock source for the CPU. If the external clock source is the
external oscillator and the oscillator is disabled, firmware will
need to enable the external oscillator, wait for it to stabilize,
and then change the clock source.
The occurrence of a reset is recorded in the System Status and
Control Register (CPU_SCR). Bits within this register record
the occurrence of POR and WDR Reset, respectively. The
firmware can interrogate these bits to determine the cause of
a reset.
The microcontroller resumes execution from Flash address
0x0000 after a reset. The internal clocking mode is active after
a reset, until changed by user firmware.
Note: The CPU clock defaults to 3 MHz (Internal 24 MHz
Oscillator divide-by-8 mode) at POR to guarantee operation at
the low VCC that might be present during the supply ramp.
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Table 39.System Status and Control Register (CPU_SCR) [0xFF] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
GIES
Reserved
WDRS
PORS
Sleep
Reserved
Reserved
Stop
Read/Write
R
–
R/C[3]
R/C[3]
R/W
–
–
R/W
Default
0
0
0
1
0
1
0
0
The bits of the CPU_SCR register are used to convey status and control of events for various functions of an enCoRe II LV device.
Bit 7: GIES
The Global Interrupt Enable Status bit is a read only status bit and its use is discouraged. The GIES bit is a legacy bit, which
was used to provide the ability to read the GIE bit of the CPU_F register. However, the CPU_F register is now readable. When
this bit is set, it indicates that the GIE bit in the CPU_F register is also set which, in turn, indicates that the microprocessor will
service interrupts.
0 = Global interrupts disabled
1 = Global interrupt enabled
Bit 6: Reserved
Bit 5: WDRS
The WDRS bit is set by the CPU to indicate that a WDR event has occurred. The user can read this bit to determine the type of
reset that has occurred. The user can clear but not set this bit.
0 = No WDR
1 = A WDR event has occurred
Bit 4: PORS
The PORS bit is set by the CPU to indicate that a POR event has occurred. The user can read this bit to determine the type of
reset that has occurred. The user can clear but not set this bit.
0 = No POR
1 = A POR event has occurred. (Note that WDR events will not occur until this bit is cleared.)
Bit 3: SLEEP
Set by the user to enable CPU sleep state. CPU will remain in sleep mode until any interrupt is pending. The Sleep bit is covered
in more detail in the Sleep Mode section.
0 = Normal operation
1 = Sleep
Bit [2:1]: Reserved
Bit 0: STOP
This bit is set by the user to halt the CPU. The CPU will remain halted until a reset (WDR, POR, or external reset) has taken
place. If an application wants to stop code execution until a reset, the preferred method would be to use the HALT instruction
rather than writing to this bit.
0 = Normal CPU operation
1 = CPU is halted (not recommended)
Power-On Reset
POR occurs every time the power to the device is switched on.
POR is released when the supply is typically 2.6V for the
upward supply transition, with typically 50 mV of hysteresis
during the power on transient. Bit 4 of the System Status and
Control Register (CPU_SCR) is set to record this event (the
register contents are set to 00010000 by the POR). After a
POR, the microprocessor is held off for approximately 20 ms
for the VCC supply to stabilize before executing the first
instruction at address 0x00 in the Flash. If the VCC voltage
drops below the POR downward supply trip point, POR is
reasserted. The VCC supply needs to ramp linearly from 0 to
VCC in less than 200 ms.
Important: The PORS status bit is set at POR and can only
be cleared by the user, and cannot be set by firmware.
Watchdog Timer Reset
The user has the option to enable the WDT. The WDT is
enabled by clearing the PORS bit. Once the PORS bit is
cleared, the WDT cannot be disabled. The only exception to
this is if a POR event takes place, which will disable the WDT.
The sleep timer is used to generate the sleep time period and
the Watchdog time period. The sleep timer uses the Internal
32 kHz Low-power Oscillator system clock to produce the
sleep time period. The user can program the sleep time period
using the Sleep Timer bits of the OSC_CR0 Register
(Table 33). When the sleep time elapses (sleep timer
overflows), an interrupt to the Sleep Timer Interrupt Vector will
be generated.
The Watchdog Timer period is automatically set to be three
counts of the Sleep Timer overflows. This represents between
two and three sleep intervals depending on the count in the
Sleep Timer at the previous WDT clear. When this timer
reaches three, a WDR is generated.
The user can either clear the WDT, or the WDT and the Sleep
Timer. Whenever the user writes to the Reset WDT Register
(RES_WDT), the WDT will be cleared. If the data that is written
is the hex value 0x38, the Sleep Timer will also be cleared at
the same time.
Note
3. ‘C = Clear. This bit can only be cleared by the user and cannot be set by firmware.
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Table 40.Reset Watchdog Timer (RESWDT) [0xE3] [W]
Bit #
7
6
5
Field
4
3
2
1
0
Reset Watchdog Timer [7:0]
Read/Write
W
W
W
W
W
W
W
W
Default
0
0
0
0
0
0
0
0
Any write to this register will clear the Watchdog Timer, a write of 0x38 will also clear the Sleep Timer.
Bit [7:0]: Reset Watchdog Timer [7:0]
Sleep Mode
sleep instruction is executed before the interrupt service
routine (if enabled).
The CPU can only be put to sleep by the firmware. This is
accomplished by setting the Sleep bit in the System Status and
Control Register (CPU_SCR). This stops the CPU from
executing instructions, and the CPU will remain asleep until an
interrupt comes pending, or there is a reset event (either a
Power-on Reset, or a Watchdog Timer Reset).
The Sleep interrupt allows the microcontroller to wake up
periodically and poll system components while maintaining
very low average power consumption. The Sleep interrupt
may also be used to provide periodic interrupts during nonsleep modes.
The Low-voltage Detection circuit (LVD) drops into fully
functional power-reduced states, and the latency for the LVD
is increased. The actual latency can be traded against power
consumption by changing Sleep Duty Cycle field of the
ECO_TR Register.
Sleep Sequence
The Internal 32 kHz Low-speed Oscillator remains running.
Prior to entering suspend mode, firmware can optionally
configure the 32 kHz Low-speed Oscillator to operate in a lowpower mode to help reduce the over all power consumption
(using the 32 kHz Low Power bit, Table 38). This will help save
approximately 5 µA; however, the trade off is that the 32 kHz
Low-speed Oscillator will be less accurate (–53.12% to
+56.25% deviation).
All interrupts remain active. Only the occurrence of an interrupt
will wake the part from sleep. The Stop bit in the System Status
and Control Register (CPU_SCR) must be cleared for a part
to resume out of sleep. The Global Interrupt Enable bit of the
CPU Flags Register (CPU_F) does not have any effect. Any
unmasked interrupt will wake the system up. As a result, any
interrupts not intended for waking should be disabled through
the Interrupt Mask Registers.
When the CPU enters sleep mode the CPUCLK Select (Bit 1,
Table 32) is forced to the Internal Oscillator. The internal oscillator recovery time is three clock cycles of the Internal 32 kHz
Low-power Oscillator. The Internal 24 MHz Oscillator restarts
immediately on exiting Sleep mode. If the external crystal
oscillator is used, firmware will need to switch the clock source
for the CPU.
Unlike the Internal 24 MHz Oscillator, the external oscillator is
not automatically shut-down during sleep. Systems that need
the external oscillator disabled in sleep mode will need to
disable the external oscillator prior to entering sleep mode. In
systems where the CPU runs off the external oscillator,
firmware will need to switch the CPU to the internal oscillator
prior to disabling the external oscillator.
On exiting sleep mode, once the clock is stable and the delay
time has expired, the instruction immediately following the
Document 38-16016 Rev. *C
The SLEEP bit is an input into the sleep logic circuit. This
circuit is designed to sequence the device into and out of the
hardware sleep state. The hardware sequence to put the
device to sleep is shown in Figure 8 and is defined as follows.
1. Firmware sets the SLEEP bit in the CPU_SCR0 register.
The Bus Request (BRQ) signal to the CPU is immediately
asserted. This is a request by the system to halt CPU operation at an instruction boundary. The CPU samples BRQ
on the positive edge of CPUCLK.
2. Due to the specific timing of the register write, the CPU
issues a Bus Request Acknowledge (BRA) on the following
positive edge of the CPU clock. The sleep logic waits for
the following negative edge of the CPU clock and then
asserts a system-wide Power Down (PD) signal. In Figure 8
the CPU is halted and the system-wide power down signal
is asserted.
3. The system-wide PD (power down) signal controls several
major circuit blocks: The Flash memory module, the internal
24-MHz oscillator, the EFTB filter and the bandgap voltage
reference. These circuits transition into a zero power state.
The only operational circuits on chip are the Low Power
oscillator, the bandgap refresh circuit, and the supply
voltage monitor (POR/LVD) circuit.
The external crystal oscillator on enCoRe II LV devices is not
automatically powered down when the CPU enters the sleep
state. Firmware must explicitly disable the external crystal
oscillator in order to reduce power to levels specified.
Note: To achieve the lowest possible power consumption
during suspend/sleep, the following conditions must be
observed in addition to considerations for the sleep timer and
external crystal oscillator:
• All GPIOs must be set to outputs and driven low
• The port pins P1.0 and P1.1 should be configured as inputs
with their pull ups enabled.
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Figure 8. Sleep Timing
Firmware write to SCR
SLEEP bit causes an
immediate BRQ
CPU captures
BRQ on next
CPUCLK edge
CPU
responds
with a BRA
On the falling edge of
CPUCLK, PD is asserted.
The 24/48 MHz system clock
is halted; the Flash and
bandgap are powered down
CPUCLK
IOW
SLEEP
BRQ
BRA
PD
Wakeup Sequence
Once asleep, the only event that can wake the system up is
an interrupt. The global interrupt enable of the CPU flag
register does not need to be set. Any unmasked interrupt will
wake the system up. It is optional for the CPU to actually take
the interrupt after the wakeup sequence. The wakeup
sequence is synchronized to the 32 kHz clock for purposes of
sequencing a startup delay, to allow the Flash memory module
enough time to power up before the CPU asserts the first read
access. Another reason for the delay is to allow the oscillator,
Bandgap, and LVD/POR circuits time to settle before actually
being used in the system. As shown in Figure 9, the wakeup
sequence is as follows:
1. The wakeup interrupt occurs and is synchronized by the
negative edge of the 32 kHz clock.
2. At the following positive edge of the 32 kHz clock, the
system wide PD signal is negated. The Flash memory
Document 38-16016 Rev. *C
module, internal oscillator, EFTB, and bandgap circuit are
all powered up to a normal operating state.
3. At the following positive edge of the 32 kHz clock, the
current values for the precision POR and LVD have settled
and are sampled.
4. At the following negative edge of the 32 kHz clock (after
about 15 µs nominal), the BRQ signal is negated by the
sleep logic circuit. On the following CPUCLK, BRA is
negated by the CPU and instruction execution resumes.
Note that in Figure 9 fixed function blocks, such as Flash,
internal oscillator, EFTB, and bandgap, have about 15 µs
start up. The wakeup times (interrupt to CPU operational)
will range from 75 µs to 105 µs.
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Figure 9. Wakeup Timing
S le e p T im e r o r G P IO
in te rru p t o ccu rs
In te rru p t is d o u b le sa m p le d
b y 3 2 K clo ck a n d P D is
n e g a te d to syste m
C P U is re sta rte d
a fte r 9 0 m s (n o m in a l)
CLK32K
IN T
SLEEP
PD
BANDGAP
ENABLE
SAM PLE
SAM PLE
L V D /P O R
CPUCLK/
2 4M H z
(N o t to S ca le )
BRQ
BRA
CPU
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Low-Voltage Detect Control
Table 41.Low-voltage Control Register (LVDCR) [0x1E3] [R/W]
Bit #
7
Field
6
5
Reserved
4
PORLEV[1:0]
3
2
Reserved
1
0
VM[2:0]
Read/Write
–
–
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register controls the configuration of the Power-on Reset/Low-voltage Detection circuit. This register can only be accessed
in the second bank of I/O space. This requires setting the XIO bit in the CPU flags register.
Bit [7:6]: Reserved
Bit [5:4]: PORLEV[1:0]
This field controls the level below which the precision power-on-reset (PPOR) detector generates a reset.
0 0 = 2.7V Range (trip near 2.6V)
0 1 = 3V Range (trip near 2.9V)
1 0 = Reserved
1 1 = PPOR will not generate a reset, but values read from the Voltage Monitor Comparators Register (Table 42) give the internal
PPOR comparator state with trip point set to the 3V range setting.
Bit 3: Reserved
Bit [2:0]: VM[2:0]
This field controls the level below which the low-voltage-detect trips—possibly generating an interrupt and the level at which the
Flash is enabled for operation.
LVD Trip Point (V)
VM[2:0]
Min.
Max.
000
2.69
2.72
2.7
001
2.90
2.94
2.92
010
3.00
3.04
3.02
011
3.10
3.15
3.13
100
Typical
Reserved
101
Reserved
110
Reserved
111
Reserved
POR Compare State
Table 42.Voltage Monitor Comparators Register (VLTCMP) [0x1E4] [R]
Bit #
7
6
5
Field
4
3
2
Reserved
1
0
LVD
PPOR
Read/Write
–
–
–
–
–
–
R
R
Default
0
0
0
0
0
0
0
0
This read-only register allows reading the current state of the Low-voltage Detection and Precision-Power-On-Reset comparators.
Bit [7:2]: Reserved
Bit 1: LVD
This bit is set to indicate that the low-voltage-detect comparator has tripped, indicating that the supply voltage has gone below
the trip point set by VM[2:0] (See Table 41.)
0 = No low-voltage-detect event
1= A low-voltage-detect has tripped
Bit 0: PPOR
This bit is set to indicate that the precision-power-on-reset comparator has tripped, indicating that the supply voltage is below
the trip point set by PORLEV[1:0].
0 = No precision-power-on-reset event
1= A precision-power-on-reset event has occurred
Note: This register can only be accessed in the second bank of I/O space. This requires setting the XIO bit in the CPU flags
register.
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ECO Trim Register
Table 43.ECO (ECO_TR) [0x1EB] [R/W]
Bit #
Field
7
6
5
4
3
Sleep Duty Cycle [1:0]
2
1
0
Reserved
Read/Write
R/W
R/W
–
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
This register controls the ratios (in numbers of 32 kHz clock periods) of “on” time versus “off” time for LVD and POR detection
circuit.
Bit [7:6]: Sleep Duty Cycle [1:0]
0 0 = 128 periods of the Internal 32 kHz Low-speed Oscillator
0 1 = 512 periods of the Internal 32 kHz Low-speed Oscillator
1 0 = 32 periods of the Internal 32 kHz Low-speed Oscillator
1 1 = 8 periods of the Internal 32 kHz Low-speed Oscillator
Note: This register can only be accessed in the second bank of I/O space. This requires setting the XIO bit in the CPU flags
register.
General Purpose I/O Ports
Port Data Registers
P0 Data
Table 44.P0 Data Register (P0DATA)[0x00] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
P0.7
P0.6/TIO1
P0.5/TIO0
P0.4/INT2
P0.3/INT1
P0.2/INT0
P0.1/CLKOUT
P0.0/CLKIN
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register contains the data for Port 0. Writing to this register sets the bit values to be output on output enabled pins. Reading
from this register returns the current state of the Port 0 pins.
Bit 7: P0.7 Data
Bit [6:5]: P0.6–P0.5 Data/TIO1 and TIO0
Beside their use as the P0.6–P0.5 GPIOs, these pins can also be used for the alternate functions as the Capture Timer input or
Timer output pins (TIO1 and TIO0). To configure the P0.5 and P0.6 pins, refer to the P0.5/TIO0–P0.6/TIO1 Configuration Register
(Table 52.)
Bit [4:2]: P0.4–P0.2 Data/INT2–INT0
Beside their use as the P0.4–P0.2 GPIOs, these pins can also be used for the alternate functions as the Interrupt pins
(INT0–INT2). To configure the P0.4–P0.2 pins, refer to the P0.2/INT0–P0.4/INT2 Configuration Register (Table 51)
Bit 1: P0.1/CLKOUT
Beside its use as the P0.1 GPIO, this pin can also be used for the alternate function as the CLK OUT pin. To configure the P0.1
pin, refer to the P0.1/CLKOUT Configuration Register (Table 50.)
Bit 0: P0.0/CLKIN
Beside its use as the P0.0 GPIO, this pin can also be used for the alternate function as the CLKIN pin. To configure the P0.0
pin, refer to the P0.0/CLKIN Configuration Register (Table 49.)
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P1 Data
Table 45.P1 Data Register (P1DATA) [0x01] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
P1.7
P1.6/SMISO
P1.5/SMOSI
P1.4/SCLK
P1.3/SSEL
P1.2
P1.1
P1.0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register contains the data for Port 1. Writing to this register sets the bit values to be output on output enabled pins. Reading
from this register returns the current state of the Port 1 pins.
Bit 7: P1.7 Data
Bit [6:3]: P1.6–P1.3 Data/SPI Pins (SMISO, SMOSI, SCLK, SSEL)
Beside their use as the P1.6–P1.3 GPIOs, these pins can also be used for the alternate function as the SPI interface pins. To
configure the P1.6–P1.3 pins, refer to the P1.3–P1.6 Configuration Register (Table 57.)
Bit [2:0]: P1.2–P1.0
P2 Data
Table 46.P2 Data Register (P2DATA) [0x02] [R/W]
Bit #
7
6
5
Field
4
3
2
1
P2.7–P2.2
0
P2.1–P2.0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register contains the data for Port 2. Writing to this register sets the bit values to be output on output enabled pins. Reading
from this register returns the current state of the Port 2 pins.
Bit [7:2]: P2 Data [7:2]
Bit [1:0]: P2 Data [1:0]
P3 Data
Table 47.P3 Data Register (P3DATA) [0x03] [R/W]
Bit #
7
6
5
Field
4
3
2
1
P3.7–P3.2
0
P3.1–P3.0
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register contains the data for Port 3. Writing to this register sets the bit values to be output on output enabled pins. Reading
from this register returns the current state of the Port 3 pins.
Bit [7:2]: P3 Data [7:2]
Bit [1:0]: P3 Data [1:0]
P4 Data
Table 48.P4 Data Register (P4DATA) [0x04] [R/W]
Bit #
7
6
Field
5
4
3
2
Reserved
1
0
P4.3–P4.0
Read/Write
–
–
–
–
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register contains the data for Port 4. Writing to this register sets the bit values to be output on output-enabled pins. Reading
from this register returns the current state of the Port 2 pins.
Bit [7:4]: Reserved
Bit [3:0]: P4 Data [3:0]
P4.3–P4.0 only exist in the CY7C601xx
Document 38-16016 Rev. *C
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CY7C602xx
GPIO Port Configuration
When clear, the output can sink up to 8 mA.
All the GPIO configuration registers have common configuration controls. The following are the bit definitions of the GPIO
configuration registers. By default all GPIOs are configured as
inputs. In order to prevent the inputs from floating the pull up
resistors are enabled. Firmware will need to configure each of
the GPIOs prior to use.
On the CY7C601xx, only the P3.7, P2.7, P0.1, and P0.0 have
50-mA sink drive capability. Other pins have 8-mA sink drive
capability.
On the CY7C602xx, only the P1.7–P1.3 have 50-mA sink drive
capability. Other pins have 8-mA sink drive capability.
Open Drain
Int Enable
When set, the Int Enable bit allows the GPIO to generate interrupts. Interrupt generate can occur regardless of whether the
pin is configured for input or output. All interrupts are edge
sensitive, however for any interrupt that is shared by multiple
sources (i.e., Ports 2, 3, and 4) all inputs must be deasserted
before a new interrupt can occur.
When clear, the corresponding interrupt is disabled on the pin.
It is possible to configure GPIOs as outputs, enable the
interrupt on the pin and then to generate the interrupt by
driving the appropriate pin state. This is useful in test and may
find value in applications as well.
When set, the output on the pin is determined by the Port Data
Register. If the corresponding bit in the Port Data Register is
set, the pin is in high impedance state. If the corresponding bit
in the Port Data Register is clear, the pin is driven LOW.
When clear, the output is driven LOW or HIGH.
Pull Up Enable
When set the pin has a 7K pull up to VDD.
When clear, the pull- up is disabled.
Output Enable
When set, the output driver of the pin is enabled.
Int Act Low
When clear, the output driver of the pin is disabled.
When clear, the corresponding interrupt is active HIGH. When
set, the interrupt is active LOW. For P0.2–P0.4 Int act Low
causes interrupts to be active on the rising edge. Int act Low
set causes interrupts to be active on the falling edge.
For pins with shared functions there are some special cases.
TTL Thresh
When set, the input has TTL threshold. When clear, the input
has standard CMOS threshold.
Important Note: The GPIOs default to CMOS threshold.
User’s firmware needs to configure the threshold to TTL mode
if necessary.
P0.0(CLKIN) and P0.1(CLKOUT) can not be output enabled
when the crystal oscillator is enabled. Output enables for these
pins are overridden by XOSC Enable.
SPI Use
The
P1.3(SSEL),
P1.4(SCLK),
P1.5(SMOSI)
and
P1.6(SMISO) pins can be used for their dedicated functions or
for GPIO. To enable the pin for GPIO, clear the corresponding
SPI Use bit. The SPI function controls the output enable for its
dedicated function pins when their GPIO enable bit is clear.
High Sink
When set, the output can sink up to 50 mA.
Figure 10. GPIO Block Diagram
VCC
VREG
3.3V Drive
Pull-Up Enable
Output Enable
VREG
VCC
RUP
Open Drain
Port Data
Data Out
GPIO
PIN
High Sink
VREG GND
VCC GND
Data In
TTL Threshold
Document 38-16016 Rev. *C
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P0.0/CLKIN Configuration
Table 49.P0.0/CLKIN Configuration (P00CR) [0x05] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull-up Enable
Output Enable
Read/Write
–
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This pin is shared between the P0.0 GPIO use and the CLKIN pin for the external crystal oscillator. When the external oscillator
is enabled the settings of this register are ignored.
The alternate function of the pin as the CLKIN is only available in the CY7C601xx. When the external oscillator is enabled (the
XOSC Enable bit of the CLKIOCR Register is set—Table 34), the GPIO function of the pin is disabled.
The 50-mA sink drive capability is only available in the CY7C601xx. In the CY7C602xx, only 8-mA sink drive capability is available
on this pin regardless of the setting of the High Sink bit.
If this pin is used as a General Purpose output it will draw current. This pin should be configured as an input to reduce current draw.
P0.1/CLKOUT Configuration
Table 50.P0.1/CLKOUT Configuration (P01CR) [0x06] R/W]
Bit #
7
6
5
4
3
2
1
0
Field
CLK Output
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull-up Enable
Output Enable
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This pin is shared between the P0.1 GPIO use and the CLKOUT pin for the external crystal oscillator. When the external oscillator
is enabled the settings of this register are ignored. When CLK output is set, the internally selected clock is sent out onto
P0.1CLKOUT pin.
The alternate function of the pin as the CLKOUT is only available in the CY7C601xx. When the external oscillator is enabled
(the XOSC Enable bit of the CLKIOCR Register is set—Table 34), the GPIO function of the pin is disabled.
The 50-mA sink drive capability is only available in the CY7C601xx. In the CY7C602xx, only 8-mA sink drive capability is available
on this pin regardless of the setting of the High Sink bit.
If this pin is used as a General Purpose output it will draw current. This pin should be configured as an input to reduce current draw
Bit 7: CLK Output
0 = The clock output is disabled
1 = The clock selected by the CLK Select field (Bit [1:0] of the CLKIOCR Register—Table 34) is driven out to the pin
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P0.2/INT0–P0.4/INT2 Configuration
Table 51.P0.2/INT0–P0.4/INT2 Configuration (P02CR–P04CR) [0x07–0x09] [R/W]
Bit #
7
Field
6
Reserved
5
4
3
2
1
0
Int Act Low
TTL Thresh
Reserved
Open Drain
Pull-up Enable
Output Enable
Read/Write
–
–
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
These registers control the operation of pins P0.2–P0.4 respectively. These pins are shared between the P0.2–P0.4 GPIOs and
the INT0–INT2. The INT0–INT2 interrupts are different than all the other GPIO interrupts. These pins are connected directly to
the interrupt controller to provide three edge-sensitive interrupts with independent interrupt vectors. These interrupts occur on
a rising edge when Int act Low is clear and on a falling edge when Int act Low is set. These pins are enabled as interrupt sources
in the interrupt controller registers (Table 87 and Table 85).
To use these pins as interrupt inputs configure them as inputs by clearing the corresponding Output Enable. If the INT0–INT2
pins are configured as outputs with interrupts enabled, firmware can generate an interrupt by writing the appropriate value to the
P0.2, P0.3, and P0.4 data bits in the P0 Data Register.
Regardless of whether the pins are used as Interrupt or GPIO pins the Int Enable, Int act Low, TTL Threshold, Open Drain, and
Pull-up Enable bits control the behavior of the pin.
The P0.2/INT0–P0.4/INT2 pins are individually configured with the P02CR (0x07), P03CR (0x08), and P04CR (0x09) respectively.
Note: Changing the state of the Int Act Low bit can cause an unintentional interrupt to be generated. When configuring these
interrupt sources, it is best to follow the following procedure:
1. Disable interrupt source
2. Configure interrupt source
3. Clear any pending interrupts from the source
4. Enable interrupt source
P0.5/TIO0–P0.6/TIO1 Configuration
Table 52.P0.5/TIO0–P0.6/TIO1 Configuration (P05CR–P06CR) [0x0A–0x0B] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
TIO Output
Int Enable
Int Act Low
TTL Thresh
Reserved
Open Drain
Pull-up Enable
Output Enable
Read/Write
R/W
R/W
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
These registers control the operation of pins P0.5 through P0.6, respectively.
P0.5 and P0.6 are shared with TIO0 and TIO1, respectively. To use these pins as Capture Timer inputs, configure them as inputs
by clearing the corresponding Output Enable. To use TIO0 and TIO1 as Timer outputs, set the TIOx Output and Output Enable
bits. If these pins are configured as outputs and the TIO Output bit is clear, firmware can control the TIO0 and TIO1 inputs by
writing the value to the P0.5 and P0.6 data bits in the P0 Data Register.
Regardless of whether either pin is used as a TIO or GPIO pin the Int Enable, Int act Low, TTL Threshold, Open Drain, and Pullup Enable control the behavior of the pin.
TIO0(P0.5) when enabled outputs a positive pulse from the 1024-µs interval timer. This is the same signal that is used internally
to generate the 1024-µs timer interrupt. This signal is not gated by the interrupt enable state.
TIO1(P0.6) when enabled outputs a positive pulse from the programmable interval timer. This is the same signal that is used
internally to generate the programmable timer interval interrupt. This signal is not gated by the interrupt enable state.
The P0.5/TIO0 and P0.6/TIO1 pins are individually configured with the P05CR (0x0A) and P06CR (0x0B), respectively
P0.7 Configuration
Table 53.P0.7 Configuration (P07CR) [0x0C] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
TTL Thresh
Reserved
Open Drain
Pull-up Enable
Output Enable
Read/Write
–
R/W
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register controls the operation of pin P0.7
Document 38-16016 Rev. *C
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CY7C602xx
P1.0 Configuration
Table 54.P1.0 Configuration (P10CR) [0x0D] [R/W]
Bit #
7
6
5
Field
Reserved
Int Enable
Int Act Low
4
3
Read/Write
R/W
R/W
R/W
–
–
Default
0
0
0
0
0
2
1
0
P1.0 and P1.1
Pull Up Enable
Output Enable
–
–
R/W
0
0
0
Reserved
This register controls the operation of the P1.0 pin.
Bit1: P1.0 and P1.1 Pull Up Enable
0 = Disable the P1.0 and P1.1 pull up resistors
1 = Enable the internal pull up resistors for both the P1.0 and P1.1. Each of the P1.0 and P1.1 pins is pulled up with RUP1 (see
DC Characteristics on page 54)
Note: There is no 2-mA sourcing capability on this pin. The pin can only sink 5 mA at VOL3 (see DC Characteristics on page 54)
The P1.0 is an open drain only output. It can actively drive a signal low, but cannot actively drive a signal high.
P1.1 Configuration
Table 55.P1.1 Configuration (P11CR) [0x0E] [R/W]
Bit #
7
6
5
Field
Reserved
Int Enable
Int Act Low
4
3
Read/Write
–
R/W
R/W
–
–
Default
0
0
0
0
0
Reserved
2
1
0
Open Drain
Reserved
Output Enable
R/W
–
R/W
0
0
0
This register controls the operation of the P1.1 pin.
The pull up resistor on this pin is enabled by the P10CR Register
Note: There is no 2-mA sourcing capability on this pin. The pin can only sink 5 mA at VOL3 (see DC Characteristics on page 54)
P1.2 Configuration
Table 56.P1.2 Configuration (P12CR) [0x0F] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
CLK Output
Int Enable
Int Act Low
TTL Threshold
Reserved
Open Drain
Pull-up Enable
Output Enable
Read/Write
R/W
R/W
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register controls the operation of the P1.2
Bit 7: CLK Output
0 = The internally selected clock is not sent out onto P1.2 pin
1 = This CLK Output is used to observe connected external crystal oscillator clock connected in CY7C601xx. When CLK Output
is set, the internally selected clock is sent out onto P1.2 pin.
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P1.3 Configuration (SSEL)
Table 57.P1.3 Configuration (P13CR) [0x10] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
Reserved
High Sink
Open Drain
Pull Up Enable
Output Enable
Read/Write
–
R/W
R/W
–
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register controls the operation of the P1.3 pin.
The P1.3 GPIO’s threshold is always set to TTL.
When the SPI hardware is enabled, the output enable and output state of the pin is controlled by the SPI circuitry. When the SPI
hardware is disabled, the pin is controlled by the Output Enable bit and the corresponding bit in the P1 data register.
Regardless of whether the pin is used as an SPI or GPIO pin the Int Enable, Int act Low, High Sink, Open Drain, and Pull Up
Enable control the behavior of the pin.
The 50-mA sink drive capability is only available in the CY7C602xx. In the CY7C601xx, only 8-mA sink drive capability is available
on this pin regardless of the setting of the High Sink bit.
P1.4–P1.6 Configuration (SCLK, SMOSI, SMISO)
Table 58.P1.4–P1.6 Configuration (P14CR–P16CR) [0x11–0x13] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
SPI Use
Int Enable
Int Act Low
Reserved
High Sink
Open Drain
Pull Up Enable
Output Enable
Read/Write
R/W
R/W
R/W
–
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
These registers control the operation of pins P1.4–P1.6, respectively.
The P1.4–P1.6 GPIO’s threshold is always set to TTL.
When the SPI hardware is enabled, pins that are configured as SPI Use have their output enable and output state controlled by
the SPI circuitry. When the SPI hardware is disabled or a pin has its SPI Use bit clear, the pin is controlled by the Output Enable
bit and the corresponding bit in the P1 data register.
Regardless of whether any pin is used as an SPI or GPIO pin the Int Enable, Int act Low, High Sink, Open Drain, and Pull-up
Enable control the behavior of the pin.
The 50-mA sink drive capability is only available in the CY7C602xx. In the CY7C601xx, only 8-mA sink drive capability is available
on this pin regardless of the setting of the High Sink bit.
Bit 7: SPI Use
0 = Disable the SPI alternate function. The pin is used as a GPIO
1 = Enable the SPI function. The SPI circuitry controls the output of the pin
Important Note for Comm Modes 01 or 10 (SPI Master or SPI Slave, see Table 64):
When configured for SPI (SPI Use = 1 and Comm Modes [1:0] = SPI Master or SPI Slave mode), the input/output direction of
pins P1.3, P1.5, and P1.6 is set automatically by the SPI logic. However, pin P1.4's input/output direction is NOT automatically
set; it must be explicitly set by firmware. For SPI Master mode, pin P1.4 must be configured as an output; for SPI Slave mode,
pin P1.4 must be configured as an input.
P1.7 Configuration
Table 59. P1.7 Configuration (P17CR) [0x14] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
Reserved
High Sink
Open Drain
Pull Up Enable
Output Enable
Read/Write
–
R/W
R/W
–
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register controls the operation of pin P1.7.
The 50-mA sink drive capability is only available in the CY7C602xx. In the CY7C601xx, only 8-mA sink drive capability is available
on this pin regardless of the setting of the High Sink bit.
The P1.7 GPIO’s threshold is always set to TTL.
Document 38-16016 Rev. *C
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P2 Configuration
Table 60.P2 Configuration (P2CR) [0x15] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull Up Enable
Output Enable
Read/Write
–
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
In CY7C602xx this register controls the operation of pins P2.0–P2.1. In the CY7C601xx, this register controls the operation of
pins P2.0–P2.7.
The 50-mA sink drive capability is only available on pin P2.7 and only on the CY7C601xx. In the CY7C602xx, only 8-mA sink
drive capability is available on this pin regardless of the setting of the High Sink bit.
P3 Configuration
Table 61.P3 Configuration (P3CR) [0x16] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull Up Enable
Output Enable
Read/Write
–
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
In CY7C602xx this register controls the operation of pins P3.0–P3.1. In the CY7C601xx, this register controls the operation of
pins P3.0–P3.7.
The 50-mA sink drive capability is only available on pin P3.7 and only on the CY7C601xx. In the CY7C602xx, only 8-mA sink
drive capability is available on this pin regardless of the setting of the High Sink bit.
P4 Configuration
Table 62.P4 Configuration (P4CR) [0x17] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
Int Enable
Int Act Low
TTL Thresh
High Sink
Open Drain
Pull Up Enable
Output Enable
Read/Write
–
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
This register exists only in the CY7C601xx. This register controls the operation of pins P4.0–P4.3.
Document 38-16016 Rev. *C
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CY7C602xx
Serial Peripheral Interface (SPI)
The SPI Master/Slave Interface core logic runs on the SPI clock domain. The SPI clock is a divider off of the CPUCLK when in
Master Mode. SPI is a four-pin serial interface comprised of a clock, an enable, and two data pins.
Figure 11. SPI Block Diagram
Register Block
SCK Speed Sel
SCK Clock Generation
Master/Slave Sel
SCK Clock Select
SCK Polarity
SCK_OE
SCK Clock Phase/Polarity
Select
SCK Phase
SCK
SCK
Little Endian Sel
LE_SEL
GPIO Block
SS_N
SS_N
SPI State Machine
SS_N_OE
SS_N
Data (8 bit)
Load
MISO_OE
Output Shift Buffer
Empty
Master/Slave Set
MISO/MOSI
Crossbar
MISO
SCK
LE_SEL
Shift Buffer
MOSI_OE
MOSI
Data (8 bit)
Input Shift Buffer
Load
Full
Sclk Output Enable
Slave Select Output Enable
Master IN, Slave Out OE
Master Out, Slave In, OE
Document 38-16016 Rev. *C
SCK_OE
SS_N_OE
MISO_OE
MOSI_OE
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SPI Data Register
Table 63.SPI Data Register (SPIDATA) [0x3C] [R/W]
Bit #
7
6
5
4
Field
3
2
1
0
SPIData[7:0]
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
When read, this register returns the contents of the receive buffer. When written, it loads the transmit holding register.
Bit [7:0]: SPI Data [7:0]
When an interrupt occurs to indicate to firmware that an byte of receive data is available, or the transmitter holding register is
empty, firmware has 7 SPI clocks to manage the buffers—to empty the receiver buffer, or to refill the transmit holding register.
Failure to meet this timing requirement will result in incorrect data transfer.
SPI Configure Register
Table 64.SPI Configure Register (SPICR) [0x3D] [R/W]
Bit #
7
6
Field
Swap
LSB First
5
Read/Write
R/W
R/W
R/W
Default
0
0
0
4
3
2
CPOL
CPHA
R/W
R/W
R/W
R/W
R/W
0
0
0
0
0
Comm Mode
1
0
SCLK Select
Bit 7: Swap
0 = Swap function disabled
1 = The SPI block swaps its use of SMOSI and SMISO. Among other things, this can be useful in implementing single wire SPIlike communications.
Bit 6: LSB First
0 = The SPI transmits and receives the MSB (Most Significant Bit) first
1 = The SPI transmits and receives the LSB (Least Significant Bit) first.
Bit [5:4]: Comm Mode [1:0]
0 0: All SPI communication disabled
0 1: SPI master mode
1 0: SPI slave mode
1 1: Reserved
Bit 3: CPOL
This bit controls the SPI clock (SCLK) idle polarity.
0 = SCLK idles low
1 = SCLK idles high
Bit 2: CPHA
The Clock Phase bit controls the phase of the clock on which data is sampled. Table 65 below shows the timing for the various
combinations of LSB First, CPOL, and CPHA.
Bit [1:0]: SCLK Select
This field selects the speed of the master SCLK. When in master mode, SCLK is generated by dividing the base CPUCLK
Important Note for Comm Modes 01b or 10b (SPI Master or SPI Slave):
When configured for SPI, (SPI Use = 1 – Table 58), the input/output direction of pins P1.3, P1.5, and P1.6 is set automatically
by the SPI logic. However, pin P1.4's input/output direction is NOT automatically set; it must be explicitly set by firmware. For
SPI Master mode, pin P1.4 must be configured as an output; for SPI Slave mode, pin P1.4 must be configured as an input.
Document 38-16016 Rev. *C
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CY7C602xx
Table 65.SPI Mode Timing vs. LSB First, CPOL and CPHA
LSB
First
0
CPHA CPOL
0
Diagram
0
SCLK
SSEL
D AT A
0
0
X
MSB
B it 7
B it 6
B it 5
B it 4
B it 3
B it 2
X
LSB
1
SC LK
SSEL
DAT A
0
1
X
MSB
B it 7
B it 6
B it 5
B it 4
B it 3
B it 2
X
LSB
0
SC LK
SSEL
DAT A
0
1
X
MSB
B it 7
B it 6
B it 5
B it 4
B it 3
B it 2
LS B
X
X
MS B
B it 7
B it 6
B it 5
B it 4
B it 3
B it 2
LSB
X
1
SC L K
SSEL
D AT A
1
0
0
SCLK
SSEL
DAT A
1
0
X
LSB
B it 2
B it 3
B it 4
B it 5
B it 6
B it 7
MS B
X
X
LSB
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
MSB
X
1
SCLK
SSEL
DAT A
1
1
0
SCLK
SSEL
DAT A
1
1
X
LSB
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
MSB
X
X
LSB
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
MSB
X
1
SC LK
SSEL
DAT A
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clock. The 16-bit free-running counter is used as the time-base
for timer captures and can also be used as a general timebase by software.
Table 66.SPI SCLK Frequency
SCLK CPUCLK
Select Divisor
SCLK Frequency when
CPUCLK = 12 MHz
00
6
2 MHz
Registers
01
12
1 MHz
Free-running Counter
The 16 bit free-running counter is clocked by the Timer
Capture Clock (TCAPCLK). It can be read in software for use
as a general-purpose time base. When the low-order byte is
read, the high-order byte is registered. Reading the high-order
byte reads this register allowing the CPU to read the 16-bit
value atomically (loads all bits at one time). The free-running
timer generates an interrupt at 1024-µs rate when clocked by
a 4 MHz source. It can also generate an interrupt when the
free-running counter overflow occurs—every 16.384 ms (with
a 4 MHz source). This allows extending the length of the timer
in software.
10
48
250 kHz
11
96
125 kHz
SPI Interface Pins
The SPI interface uses the P1.3–P1.6 pins. These pins are
configured using the P1.3 and P1.4–P1.6 Configuration.
Timer Registers
All timer functions of the enCoRe II LV are provided by a single
timer block. The timer block is asynchronous from the CPU
Figure 12. 16-bit Free Running Counter Block Diagram
Overflow
Interrupt/W rap
Interrupt
Tim er Capture
C lock
16-bit Free
Running Counter
1024-µs
Tim er
Interrupt
Table 67.Free-running Timer Low-order Byte (FRTMRL) [0x20] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Free Running Timer [7:0]
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Free-running Timer [7:0]
This register holds the low-order byte of the 16-bit free-running timer. Reading this register causes the high-order byte to be
moved into a holding register allowing an automatic read of all 16 bits simultaneously.
For reads, the actual read occurs in the cycle when the low order is read. For writes the actual time the write occurs is the cycle
when the high order is written.
When reading the Free-running Timer, the low-order byte should be read first and the high-order second. When writing, the loworder byte should be written first then the high-order byte.
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Table 68.Free-running Timer High-order Byte (FRTMRH) [0x21] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Free Running Timer [15:8]
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Free-running Timer [15:8]
When reading the Free-running Timer, the low-order byte should be read first and the high-order second. When writing, the loworder byte should be written first then the high-order byte.
configured in this way, the capture 1 resisters hold the high
order byte of the 16-bit timer capture value. Each of the four
capture registers can be programmed to generate an interrupt
when it is loaded.
Time Capture
enCoRe II LV has two 8-bit captures. Each capture has
separate register for the rising and falling time. The two 8-bit
captures can be configured as a single 16-bit capture. When
Figure 13. Time Capture Block Diagram
Programmable
Interval Timer
External
Clock
Internal
24-MHz
Oscillator
Timer Capture
Clock Output
(4-MHz Default)
Source Control and
Configuration
Internal
Low Power
32-KHz
Oscillator
16-bit Free
Running Counter
Table 69.Timer Configuration (TMRCR) [0x2A] [R/W]
Bit #
7
Field
First Edge Hold
6
5
4
Read/Write
R/W
R/W
R/W
R/W
R/W
–
–
–
Default
0
0
0
0
0
0
0
0
8-bit Capture Prescale [2:0]
3
2
Cap0 16-bit
Enable
1
0
Reserved
Bit 7: First Edge Hold
The First Edge Hold function applies to all four-capture timers.
0 = The time of the most recent edge is held in the Capture Timer Data Register. If multiple edges have occurred since reading
the capture timer, the time for the most recent one will be read.
1 = The time of the first occurrence of an edge is held in the Capture Timer Data Register until the data is read. Subsequent
edges are ignored until the Capture Timer Data Register is read.
Bit [6:4]: 8-bit Capture Prescale [2:0]
This field controls which 8 bits of the 16 Free Running Timer are captured when in bit mode.
0 0 0 = capture timer[7:0]
0 0 1 = capture timer[8:1]
0 1 0 = capture timer[9:2]
0 1 1 = capture timer[10:3]
1 0 0 = capture timer[11:4]
1 0 1 = capture timer[12:5]
1 1 0 = capture timer[13:6]
1 1 1 = capture timer[14:7]
Bit 3: Cap0 16-bit Enable
0 = Capture 0 16-bit mode is disabled
1 = Capture 0 16-bit mode is enabled. Capture 1 is disabled and the Capture 1 rising and falling registers are used as an extension
to the Capture 0 registers—extending them to 16 bits.
Bit [2:0]: Reserved
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Table 70.Capture Interrupt Enable (TCAPINTE) [0x2B] [R/W]
Bit #
7
6
Field
5
4
Reserved
3
2
1
0
Cap1 Fall
Enable
Cap1 Rise
Enable
Cap0 Fall
Enable
Cap0 Rise
Enable
Read/Write
–
–
–
–
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
4
3
2
1
0
Bit [7:4]: Reserved
Bit 3: Cap1 Fall Enable
0 = Disable the capture 1 falling edge interrupt
1 = Enable the capture 1 falling edge interrupt
Bit 2: Cap1 Rise Enable
0 = Disable the capture 1 rising edge interrupt
1 = Enable the capture 1 rising edge interrupt
Bit 1: Cap0 Fall Enable
0 = Disable the capture 0 falling edge interrupt
1 = Enable the capture 0 falling edge interrupt
Bit 0: Cap0 Rise Enable
0 = Disable the capture 0 rising edge interrupt
1 = Enable the capture 0 rising edge interrupt
Table 71.Timer Capture 0 Rising (TCAP0R) [0x22] [R/W]
Bit #
7
6
5
Field
Capture 0 Rising [7:0]
Read/Write
R
R
R
R
R
R
R
R
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Capture 0 Rising [7:0]
This register holds the value of the Free-running Timer when the last rising edge occurred on the TCAP0 input. When Capture 0
is in 8-bit mode, the bits that are stored here are selected by the Prescale [2:0] bits in the Timer Configuration register. When
Capture 0 is in 16-bit mode this register holds the lower order 8 bits of the 16-bit timer.
Table 72.Timer Capture 1 Rising (TCAP1R) [0x23] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Capture 1 Rising [7:0]
Read/Write
R
R
R
R
R
R
R
R
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Capture 1 Rising [7:0]
This register holds the value of the Free-running Timer when the last rising edge occurred on the TCAP1 input. The bits that are
stored here are selected by the Prescale [2:0] bits in the Timer Configuration register. When Capture 0 is in 16-bit mode this
register holds the high-order 8 bits of the 16-bit timer from the last Capture 0 rising edge. When Capture 0 is in 16-bit mode this
register will be loaded with the high-order 8 bits of the 16-bit timer on TCAP0 rising edge.
Table 73.Timer Capture 0 Falling (TCAP0F) [0x24] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Capture 0 Falling [7:0]
Read/Write
R
R
R
R
R
R
R
R
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Capture 0 Falling [7:0]
This register holds the value of the Free-running Timer when the last falling edge occurred on the TCAP0 input. When Capture
0 is in 8-bit mode, the bits that are stored here are selected by the Prescale [2:0] bits in the Timer Configuration register. When
Capture 0 is in 16-bit mode this register holds the lower order 8 bits of the 16-bit timer.
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Table 74.Timer Capture 1 Falling (TCAP1F) [0x25] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Capture 1 Falling [7:0]
Read/Write
R
R
R
R
R
R
R
R
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Capture 1 Falling [7:0]
This register holds the value of the Free-running Timer when the last falling edge occurred on the TCAP1 input. The bits that
are stored here are selected by the Prescale [2:0] bits in the Timer Configuration register. When capture 0 is in 16-bit mode this
register holds the high-order 8 bits of the 16-bit timer from the last Capture 0 falling edge. When Capture 0 is in 16-bit mode this
register will be loaded with high-order 8 bits of the 16-bit timer on TCAP0 falling edge.
‘
Table 75.Capture Interrupt Status (TCAPINTS) [0x2C] [R/W]
Bit #
7
6
Field
5
4
Reserved
3
2
1
0
Cap1 Fall
Active
Cap1 Rise
Active
Cap0 Fall
Active
Cap0 Rise
Active
Read/Write
–
–
–
–
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
These four bits contains the status bits for the four timer captures for the four timer block capture interrupt sources. Writing any
of these bits with 1 clears that interrupt.
Bit [7:4]: Reserved
Bit 3: Cap1 Fall Active
0 = No event
1 = A falling edge has occurred on Cap1
Bit 2: Cap1 Rise Active
0 = No event
1 = A rising edge has occurred on Cap1
Bit 1: Cap0 Fall Active
0 = No event
1 = A falling edge has occurred on Cap0
Bit 0: Cap0 Rise Active
0 = No event
1 = A rising edge has occurred on Cap0
Note: The interrupt status bits must be cleared by firmware to enable subsequent interrupts. This is achieved by writing a ‘1’ to
the corresponding Interrupt status bit.
Programmable Interval Timer
Table 76.Programmable Interval Timer Low (PITMRL) [0x26] [R]
Bit #
7
6
5
Field
4
3
2
1
0
Prog Interval Timer [7:0]
Read/Write
R
R
R
R
R
R
R
R
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Prog Interval Timer [7:0]
This register holds the low order-byte of the 12-bit programmable interval timer. Reading this register causes the high-order byte
to be moved into a holding register allowing an automatic read of all 12 bits simultaneously.
Table 77.Programmable Interval Timer High (PITMRH) [0x27] [R]
Bit #
7
6
Field
5
4
3
Reserved
2
1
0
Prog Interval Timer [11:8]
Read/Write
--
--
--
--
R
R
R
R
Default
0
0
0
0
0
0
0
0
Bit [7:4]: Reserved
Bit [3:0]: Prog Internal Timer [11:8]
This register holds the high order nibble of the 12-bit programmable interval timer. Reading this register returns the high order
nibble of the 12-bit timer at the instant that the low order byte was last read.
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Table 78.Programmable Interval Reload Low (PIRL) [0x28] [R/W]
Bit #
7
6
5
Field
4
3
2
1
0
Prog Interval [7:0]
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:0]: Prog Interval [7:0]
This register holds the lower 8 bits of the timer. While writing into the 12-bit reload register, write lower byte first then the higher nibble.
Table 79.Programmable Interval Reload High (PIRH) [0x29] [R/W]
Bit #
7
6
Field
5
4
3
Reserved
2
1
0
Prog Interval[11:8]
Read/Write
--
--
--
--
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
Bit [7:4]: Reserved
Bit [3:0]: Prog Interval [11:8]
This register holds the higher 4 bits of the timer. While writing into the 12-bit reload register, write lower byte first then the higher
nibble.
Figure 14. Timer Functional Timing Diagram
clk_captimer
16-bit free
running counter
clk_sys
capture0
cap0_rise
cap0_fall
capture1
cap1_rise
cap1_fall
cap0_rise_reg
cap0_fall_reg
cap1_rise_reg
cap1_fall_reg
Timing diagrams when cap0 is in 8 bit mode
cap1_rise_reg
cap1_fall_reg
Timing diagrams when cap0 is in 16 bit mode
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Figure 15. 16-bit Free Running Counter Loading Timing Diagram
clk_sys
write
valid
addr
write data
FRT reload
ready
Clk Timer
12b Prog Timer
12b reload
interrupt
12-bit programmable timer load timing
Capture timer
clk
16b free running
counter load
16b free
running counter
00A0 00A1 00A2 00A3 00A4 00A5 00A6 00A7 00A8 00A9 00AB 00AC 00AD 00AE 00AF 00B0 00B1 00B2 ACBE ACBF ACC0
16-bit free running counter loading timing
Figure 16. Memory Mapped Registers Read/Write Timing Diagram
clk_sys
rd_wrn
Valid
Addr
rdata
wdata
Memory mapped registers Read/Write timing diagram
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Interrupt Controller
Table 80.Interrupt Priorities, Address, Name (continued)
The interrupt controller and its associated registers allow the
user’s code to respond to an interrupt from almost every
functional block in the enCoRe II LV devices. The registers
associated with the interrupt controller allow to be disabled
either globally or individually. The registers also provide a
mechanism by which a user may clear all pending and posted
interrupts, or clear individual posted or pending interrupts.
Interrupt
Priority
Interrupt
Address
16
0040h
17
0044h
16-bit Free Running Timer Wrap
18
0048h
INT2
19
004Ch
Reserved
Table 80 lists all interrupts and the priorities that are available
in the enCoRe II LV devices.
20
0050h
GPIO Port 2
21
0054h
GPIO Port 3
Table 80.Interrupt Priorities, Address, Name
22
0058h
GPIO Port 4
23
005Ch
Reserved
24
0060h
Reserved
25
0064h
Sleep Timer
Name
Timer Capture 1
Interrupt
Priority
Interrupt
Address
0
0000h
Reset
1
0004h
POR/LVD
2
0008h
INT0
Architectural Description
3
000Ch
SPI Transmitter Empty
4
0010h
SPI Receiver Full
5
0014h
GPIO Port 0
An interrupt is posted when its interrupt conditions occur. This
results in the flip-flop in Figure 17 clocking in a ‘1’. The
interrupt will remain posted until the interrupt is taken or until
it is cleared by writing to the appropriate INT_CLRx register.
6
0018h
GPIO Port 1
7
001Ch
INT1
8
0020h
Reserved
Name
A posted interrupt is not pending unless it is enabled by setting
its interrupt mask bit (in the appropriate INT_MSKx register).
All pending interrupts are processed by the Priority Encoder to
determine the highest priority interrupt which will be taken by
the M8C if the Global Interrupt Enable bit is set in the CPU_F
register.
9
0024h
Reserved
10
0028h
Reserved
11
002Ch
Reserved
12
0030h
Reserved
13
0034h
1-mS Interval timer
14
0038h
Programmable Interval Timer
15
003Ch
Timer Capture 0
Disabling an interrupt by clearing its interrupt mask bit (in the
INT_MSKx register) does not clear a posted interrupt, nor
does it prevent an interrupt from being posted. It simply
prevents a posted interrupt from becoming pending.
Nested interrupts can be accomplished by reenabling interrupts inside an interrupt service routine. To do this, set the IE
bit in the Flag Register. A block diagram of the enCoRe II LV
Interrupt Controller is shown in Figure 17.
Figure 17. Interrupt Controller Block Diagram
Priority
Encoder
Interrupt Taken
or
Interrupt Vector
INT_CLRx Write
Posted
Interrupt
Pending
Interrupt
D
... ...
R
1
Interrupt
Request
Q
Interrupt
Source
(Timer,
GPIO, etc.)
M8C Core
CPU_F[0]
GIE
INT_MSKx
Mask Bit Setting
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5. The ISR executes. Note that interrupts are disabled since
GIE = 0. In the ISR, interrupts can be re-enabled if desired
by setting GIE = 1 (care must be taken to avoid stack
overflow).
6. The ISR ends with a RETI instruction which restores the
Program Counter and Flag registers (CPU_PC and
CPU_F). The restored Flag register re-enables interrupts,
since GIE = 1 again.
7. Execution resumes at the next instruction, after the one that
occurred before the interrupt. However, if there are more
pending interrupts, the subsequent interrupts will be
processed before the next normal program instruction.
Interrupt Processing
The sequence of events that occur during interrupt processing
is as follows:
1. An interrupt becomes active, either because:
a. The interrupt condition occurs (e.g., a timer expires).
b. A previously posted interrupt is enabled through an
update of an interrupt mask register.
c. An interrupt is pending and GIE is set from 0 to 1 in the
CPU Flag register.
2. The current executing instruction finishes.
3. The internal interrupt is dispatched, taking 13 cycles. During
this time, the following actions occur:
Interrupt Latency
a. The MSB and LSB of Program Counter and Flag
registers (CPU_PC and CPU_F) are stored onto the
program stack by an automatic CALL instruction (13
cycles) generated during the interrupt acknowledge
process.
b. The PCH, PCL, and Flag register (CPU_F) are stored
onto the program stack (in that order) by an automatic
CALL instruction (13 cycles) generated during the
interrupt acknowledge process.
c. The CPU_F register is then cleared. Since this clears the
GIE bit to 0, additional interrupts are temporarily
disabled.
d. The PCH (PC[15:8]) is cleared to zero.
e. The interrupt vector is read from the interrupt controller
and its value placed into PCL (PC[7:0]). This sets the
program counter to point to the appropriate address in
the interrupt table (e.g., 0004h for the POR/LVD
interrupt).
4. Program execution vectors to the interrupt table. Typically,
a LJMP instruction in the interrupt table sends execution to
the user's Interrupt Service Routine (ISR) for this interrup0t.
The time between the assertion of an enabled interrupt and the
start of its ISR can be calculated from the following equation.
Latency = Time for current instruction to finish + Time for
internal interrupt routine to execute + Time for LJMP
instruction in interrupt table to execute.
For example, if the 5-cycle JMP instruction is executing when
an interrupt becomes active, the total number of CPU clock
cycles before the ISR begins would be as follows:
(1 to 5 cycles for JMP to finish) + (13 cycles for interrupt
routine) + (7 cycles for LJMP) = 21 to 25 cycles.
In the example above, at 12 MHz, 25 clock cycles take 2.08 µs.
Interrupt Registers
Interrupt Clear Register
The Interrupt Clear Registers (INT_CLRx) are used to enable
the individual interrupt sources’ ability to clear posted interrupts.
When an INT_CLRx register is read, any bits that are set
indicates an interrupt has been posted for that hardware
resource. Therefore, reading these registers gives the user the
ability to determine all posted interrupts.
Table 81. Interrupt Clear 0 (INT_CLR0) [0xDA] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
GPIO Port 1
Sleep Timer
INT1
GPIO Port 0
SPI Receive
SPI Transmit
INT0
POR/LVD
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
When reading this register,
0 = There’s no posted interrupt for the corresponding hardware
1 = Posted interrupt for the corresponding hardware present
Writing a ‘0’ to the bits will clear the posted interrupts for the corresponding hardware. Writing a ‘1’ to the bits AND to the ENSWINT
(Bit 7 of the INT_MSK3 Register) will post the corresponding hardware interrupt.
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Table 82. Interrupt Clear 1 (INT_CLR1) [0xDB] [R/W]
Bit #
7
6
5
Field
TCAP0
Prog Interval
Timer
1-ms Programmable Interrupt
4
3
Read/Write
R/W
R/W
R/W
–
–
Default
0
0
0
0
0
2
1
0
–
–
–
0
0
0
Reserved
When reading this register,
0 = There’s no posted interrupt for the corresponding hardware
1 = Posted interrupt for the corresponding hardware present
Writing a ‘0’ to the bits will clear the posted interrupts for the corresponding hardware. Writing a ‘1’ to the bits AND to the ENSWINT
(Bit 7 of the INT_MSK3 Register) will post the corresponding hardware interrupt.
Table 83.Interrupt Clear 2 (INT_CLR2) [0xDC] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
GPIO Port 4
GPIO Port 3
GPIO Port 2
Reserved
INT2
16-bit Counter
Wrap
TCAP1
Read/Write
–
R/W
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
When reading this register,
0 = There’s no posted interrupt for the corresponding hardware
1 = Posted interrupt for the corresponding hardware present
Writing a ‘0’ to the bits will clear the posted interrupts for the corresponding hardware. Writing a ‘1’ to the bits AND to the ENSWINT
(Bit 7 of the INT_MSK3 Register) will post the corresponding hardware interrupt.
The Enable Software Interrupt (ENSWINT) bit in INT_MSK3[7]
determines the way an individual bit value written to an
INT_CLRx register is interpreted. When is cleared, writing 1's
to an INT_CLRx register has no effect. However, writing 0's to
an INT_CLRx register, when ENSWINT is cleared, will cause
the corresponding interrupt to clear. If the ENSWINT bit is set,
any 0's written to the INT_CLRx registers are ignored.
However, 1's written to an INT_CLRx register, while ENSWINT
is set, will cause an interrupt to post for the corresponding
interrupt.
Interrupt Mask Registers
The Interrupt Mask Registers (INT_MSKx) are used to enable
the individual interrupt sources’ ability to create pending interrupts.
There are four Interrupt Mask Registers (INT_MSK0,
INT_MSK1, INT_MSK2, and INT_MSK3) which may be
referred to in general as INT_MSKx. If cleared, each bit in an
INT_MSKx register prevents a posted interrupt from becoming
a pending interrupt (input to the priority encoder). However, an
interrupt can still post even if its mask bit is zero. All INT_MSKx
bits are independent of all other INT_MSKx bits.
Software interrupts can aid in debugging interrupt service
routines by eliminating the need to create system level interactions that are sometimes necessary to create a hardwareonly interrupt.
If an INT_MSKx bit is set, the interrupt source associated with
that mask bit may generate an interrupt that will become a
pending interrupt.
Table 84.Interrupt Mask 3 (INT_MSK3) [0xDE] [R/W]
Bit #
7
Field
ENSWINT
6
5
4
Read/Write
R
–
–
–
Default
0
0
0
0
3
2
1
0
–
–
–
–
0
0
0
0
Reserved
Bit 7: Enable Software Interrupt (ENSWINT)
0= Disable. Writing 0's to an INT_CLRx register, when ENSWINT is cleared, will cause the corresponding interrupt to clear.
1= Enable. Writing 1's to an INT_CLRx register, when ENSWINT is set, will cause the corresponding interrupt to post.
Bit [6:0]: Reserved
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Table 85.Interrupt Mask 2 (INT_MSK2) [0xDF] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
Reserved
GPIO Port 4
Int Enable
GPIO Port 3
Int Enable
GPIO Port 2
Int Enable
Reserved
INT2
Int Enable
16-bit Counter
Wrap Int Enable
TCAP1
Int Enable
Read/Write
–
R/W
R/W
R/W
–
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
4
3
2
1
0
Bit 7: Reserved
Bit 6: GPIO Port 4 Interrupt Enable
0 = Mask GPIO Port 4 interrupt
1 = Unmask GPIO Port 4 interrupt
Bit 5: GPIO Port 3 Interrupt Enable
0 = Mask GPIO Port 3 interrupt
1 = Unmask GPIO Port 3 interrupt
Bit 4: GPIO Port 2 Interrupt Enable
0 = Mask GPIO Port 2 interrupt
1 = Unmask GPIO Port 2 interrupt
Bit 3: Reserved
Bit 2: INT2 Interrupt Enable
0 = Mask INT2 interrupt
1 = Unmask INT2 interrupt
Bit 1: 16-bit Counter Wrap Interrupt Enable
0 = Mask 16-bit Counter Wrap interrupt
1 = Unmask 16-bit Counter Wrap interrupt
Bit 0: TCAP1 Interrupt Enable
0 = Mask TCAP1 interrupt
1 = Unmask TCAP1 interrupt
Table 86.Interrupt Mask 1 (INT_MSK1) [0xE1] [R/W]
Bit #
7
6
5
Field
TCAP0
Int Enable
Prog Interval
Timer
Int Enable
1-ms Timer
Int Enable
Read/Write
R/W
R/W
R/W
–
–
–
–
–
Default
0
0
0
0
0
0
0
0
Reserved
Bit 7: TCAP0 Interrupt Enable
0 = Mask TCAP0 interrupt
1 = Unmask TCAP0 interrupt
Bit 6: Prog Interval Timer Interrupt Enable
0 = Mask Prog Interval Timer interrupt
1 = Unmask Prog Interval Timer interrupt
Bit 5: 1-ms Timer Interrupt Enable
0 = Mask 1-ms interrupt
1 = Unmask 1-ms interrupt
Bit [4:0]: Reserved
Document 38-16016 Rev. *C
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Table 87. Interrupt Mask 0 (INT_MSK0) [0xE0] [R/W]
Bit #
7
6
5
4
3
2
1
0
Field
GPIO Port 1
Int Enable
Sleep Timer
Int Enable
INT1
Int Enable
GPIO Port 0
Int Enable
SPI Receive
Int Enable
SPI Transmit
Int Enable
INT0
Int Enable
POR/LVD
Int Enable
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
3
2
1
0
Bit 7: GPIO Port 1 Interrupt Enable
0 = Mask GPIO Port 1 interrupt
1 = Unmask GPIO Port 1 interrupt
Bit 6: Sleep Timer Interrupt Enable
0 = Mask Sleep Timer interrupt
1 = Unmask Sleep Timer interrupt
Bit 5: INT1 Interrupt Enable
0 = Mask INT1 interrupt
1 = Unmask INT1 interrupt
Bit 4: GPIO Port 0 Interrupt Enable
0 = Mask GPIO Port 0 interrupt
1 = Unmask GPIO Port 0 interrupt
Bit 3: SPI Receive Interrupt Enable
0 = Mask SPI Receive interrupt
1 = Unmask SPI Receive interrupt
Bit 2: SPI Transmit Enable
0 = Mask SPI Transmit interrupt
1 = Unmask SPI Transmit interrupt
Bit 1: INT0 Interrupt Enable
0 = Mask INT0 interrupt
1 = Unmask INT0 interrupt
Bit 0: POR/LVD Interrupt Enable
0 = Mask POR/LVD interrupt
1 = Unmask POR/LVD interrupt
Interrupt Vector Clear Register
Table 88.Interrupt Vector Clear Register (INT_VC) [0xE2] [R/W]
Bit #
7
6
5
Field
4
Pending Interrupt [7:0]
Read/Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Default
0
0
0
0
0
0
0
0
The Interrupt Vector Clear Register (INT_VC) holds the interrupt vector for the highest priority pending interrupt when read, and
when written will clear all pending interrupts
Bit [7:0]: Pending Interrupt [7:0]
8-bit data value holds the interrupt vector for the highest priority pending interrupt. Writing to this register will clear all pending
interrupts.
Document 38-16016 Rev. *C
Page 53 of 62
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CY7C602xx
Absolute Maximum Ratings
Maximum Total Sink Output Current into Port 0
and 1 and Pins............................................................. 70 mA
Storage Temperature ................................. –65°C to +150°C
Maximum Total Source Output Current into GPIO Pins30 mA
Ambient Temperature with Power Applied ..... –0°C to +70°C
Supply Voltage on VCC Relative to VSS ......... –0.5V to +7.0V
Maximum On-chip Power Dissipation
on any GPIO Pin......................................................... 50 mW
DC Input Voltage................................ –0.5V to + VCC + 0.5V
Power Dissipation .................................................... 300 mW
DC Voltage Applied to Outputs in
High-Z State ....................................... –0.5V to + VCC + 0.5V
Static Discharge Voltage ............................................. 2200V
Latch-up Current ...................................................... 200 mA
DC Characteristics
Description
Parameter
Conditions
General
VCC1
Operating Voltage
CPU speed <= 12 MHz
TFP
Operating Temp
Flash Programming
ICC1
VCC Operating Supply Current
ICC2
VCC Operating Supply Current
ISB1
Standby Current
Min.
Typical
Max.
Unit
2.7
3.6
V
0
70
°C
CPU speed = 12 MHz
11
mA
CPU speed = 6 MHz
9
mA
Internal and External Oscillators,
Bandgap, Flash, CPU Clock, Timer
Clock all disabled
10
µA
2.7
V
Low-voltage Detect
VLVD
Low-voltage detect Trip Voltage
LVDCR [2:0] set to 000
2.681
General Purpose I/O Interface
RUP
Pull Up Resistance
4
12
KΩ
VICR
Input Threshold Voltage Low, CMOS
mode
Low to High edge
40%
65%
VCC
VICF
Input Threshold Voltage Low, CMOS
mode
High to Low edge
30%
55%
VCC
VHC
Input Hysteresis Voltage, CMOS Mode High to low edge
3%
10%
VCC
VILTTL
Input Low Voltage, TTL Mode
0.72
V
VIHTTL
Input HIGH Voltage, TTL Mode
1.6
V
VOL1
Output Low Voltage, High
Drive[4]
IOL1 = 50 mA
1.4
V
VOL2
Output Low Voltage, High Drive[4]
IOL1 = 25 mA
0.4
V
VOL3
Output Low Voltage, Low Drive
IOL2 = 8 mA
VOH
Output High Voltage[4]
IOH = 2 mA
0.8
VCC – 0.5
V
V
AC Characteristics
Parameter
Description
Conditions
Min.
Typical
Max.
Unit
Clock
TECLKDC
External Clock Duty Cycle
45
55
%
TECLK2
External Clock Frequency
1
24
MHz
GPIO Timing
TR_GPIO
Output Rise Time
Measured between 10 and 90%
Vdd/Vreg with 50 pF load
50
ns
TF_GPIO
Output Fall Time
Measured between 10 and 90%
Vdd/Vreg with 50 pF load
15
ns
Note
4. Available only on CY7C601xx P2.7, P3.7, P0.0, P0.1; CY7C602xx P1.3,P1.4,P1.5,P1.6,P1.7.
Document 38-16016 Rev. *C
Page 54 of 62
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CY7C602xx
AC Characteristics (continued)
Parameter
Description
Conditions
Min.
Typical
Max.
Unit
2
MHz
2.2
MHz
SPI Timing
TSMCK
SPI Master Clock Rate
TSSCK
SPI Slave Clock Rate
FCPUCLK/6
TSCKH
SPI Clock High Time
High for CPOL = 0, Low for CPOL = 1
125
ns
TSCKL
SPI Clock Low Time
Low for CPOL = 0, High for CPOL = 1
125
ns
TMDO
Master Data Output Time[5]
SCK to data valid
–25
TMDO1
Master Data Output Time,
First bit with CPHA = 0
Time before leading SCK edge
100
ns
TMSU
Master Input Data Setup time
50
ns
TMHD
Master Input Data Hold time
50
ns
TSSU
Slave Input Data Setup Time
50
ns
TSHD
Slave Input Data Hold Time
TSDO
Slave Data Output Time
SCK to data valid
100
ns
TSDO1
Slave Data Output Time,
First bit with CPHA = 0
Time after SS LOW to data valid
100
ns
TSSS
Slave Select Setup Time
Before first SCK edge
150
ns
TSSH
Slave Select Hold Time
After last SCK edge
150
ns
50
50
ns
ns
Figure 18. Clock Timing
TCYC
TCH
CLOCK
TCL
Figure 19. GPIO Timing Diagram
90%
GPIO Pin Output
Voltage
10%
TR_GPIO
TF_GPIO
Note
5. In Master mode first bit is available 0.5 SPICLK cycle before Master clock edge available on the SCLK pin.
Document 38-16016 Rev. *C
Page 55 of 62
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CY7C602xx
Figure 20. SPI Master Timing, CPHA = 1
SS
(SS is under firmware control in SPI Master mode)
TSCKL
SCK (CPOL=0)
TSCKH
SCK (CPOL=1)
TMDO
MSB
MOSI
MSB
MISO
LSB
LSB
TMSU TMHD
Figure 21. SPI Slave Timing, CPHA = 1
SS
TSSS
TSSH
TSCKL
SCK (CPOL=0)
TSCKH
SCK (CPOL=1)
MOSI
MSB
TSDO
MISO
Document 38-16016 Rev. *C
LSB
TSSU TSHD
MSB
LSB
Page 56 of 62
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CY7C602xx
Figure 22. SPI Master Timing, CPHA = 0
SS
(SS is under firmware control in SPI Master mode)
TSCKL
SCK (CPOL=0)
TSCKH
SCK (CPOL=1)
TMDO
TMDO1
MSB
MOSI
LSB
MSB
MISO
LSB
TMSU TMHD
Figure 23. SPI Slave Timing, CPHA = 0
SS
TSSH
TSSS
TSCKL
SCK (CPOL=0)
TSCKH
SCK (CPOL=1)
MSB
MOSI
LSB
TSSU TSHD
TSDO
TSDO1
MISO
Document 38-16016 Rev. *C
MSB
LSB
Page 57 of 62
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CY7C602xx
1
Ordering Information
Ordering Code
FLASH Size
RAM Size
Package Type
CY7C60123-PVXC
8K
256
48-SSOP
CY7C60123-PXC
8K
256
40-PDIP
CY7C60113-PVXC
8K
256
28-SSOP
CY7C60223-PXC
8K
256
24-PDIP
CY7C60223-SXC
8K
256
24-SOIC
CY7C60223-QXC
8K
256
24-QSOP
Package Diagrams
Figure 24. 24-Lead (300-Mil) SOIC S13
NOTE :
1. JEDEC STD REF MO-119
PIN 1 ID
2. BODY LENGTH DIMENSION DOES NOT INCLUDE MOLD PROTRUSION/END FLASH,BUT
DOES INCLUDE MOLD MISMATCH AND ARE MEASURED AT THE MOLD PARTING LINE.
12
1
MOLD PROTRUSION/END FLASH SHALL NOT EXCEED 0.010 in (0.254 mm) PER SIDE
3. DIMENSIONS IN INCHES
MIN.
MAX.
4. PACKAGE WEIGHT 0.65gms
0.291[7.391]
0.300[7.620]
*
0.394[10.007]
0.419[10.642]
13
24
PART #
S24.3 STANDARD PKG.
SZ24.3 LEAD FREE PKG.
0.026[0.660]
0.032[0.812]
SEATING PLANE
0.597[15.163]
0.615[15.621]
0.092[2.336]
0.105[2.667]
*
0.050[1.270]
TYP.
0.004[0.101]
0.0118[0.299]
*
0.004[0.101]
0.015[0.381]
0.050[1.270]
0.0091[0.231]
0.0125[0.317]
0.013[0.330]
0.019[0.482]
51-85025 *C
Document 38-16016 Rev. *C
Page 58 of 62
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CY7C602xx
Package Diagrams (continued)
Figure 25. 24-Lead (300-Mil) PDIP P13
51-85013-*B
Figure 26. 24-lead QSOP O241
0.033
REF.
12
0.228
1
PIN 1 ID
0.150
0.157
DIMENSIONS IN INCHES MIN.
MAX.
0.244
13
24
0.337
0.344
SEATING
PLANE
0.007
0.010
0.053
0.069
0.004
0.004
0.010
Document 38-16016 Rev. *C
0.008
0.012
0.025
BSC.
0.016
0.034
0°-8°
51-85055-*B
Page 59 of 62
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Package Diagrams (continued)
Figure 27. 28-Lead (5.3 mm) Shrunk Small Outline Package O28
51-85079-*C
Figure 28. 40-Lead (600-Mil) Molded DIP P17
51-85019-*A
Document 38-16016 Rev. *C
Page 60 of 62
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Package Diagrams (continued)
Figure 29. 48-Lead Shrunk Small Outline Package O48
51-85061-*C
PSoC is a registered trademark and enCoRe is a trademark of Cypress Semiconductor Corporation. All product and company
names mentioned in this document are the trademarks of their respective holders.
Document 38-16016 Rev. *C
Page 61 of 62
© Cypress Semiconductor Corporation, 2006. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use
of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be
used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its
products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress
products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges.
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Document History Page
Document Title: CY7C601/2xx enCoRe™ II Low Voltage Microcontroller
Document Number: 38-16016
Rev.
ECN No.
Issue Date
Orig. of
Change
**
327601
See ECN
BON
New data sheet
*A
400134
See ECN
BHA
Updated Power consumption values
Corrected Pin Assignment Table for 24 QSOP, 24 PDIP and 28 SSOP packages
Minor text changes for clarification purposes
Corrected INT_MSK0 and INT_MSK1 register address
Corrected register bit definitions
Corrected Protection Mode Settings in Table 10-7
Updated LVD Trip Point values
Added Block diagrams for Timer functional timing
Replaced TBD’s with actual values
Added SPI Block Diagram
Added Timing Block Diagrams
Removed CY7C60123 DIE from Figure 5-1
Removed CY7C60123-WXC from Section 22.0 Ordering Information
Updated internal 24 MHz Oscillator accuracy information
Added information on sending/receiving data when using 32 KHz oscillator
*B
505222
See ECN
TYJ
Minor text changes
GPIO capacitance and timing diagram included
Method to clear Capture Interrupt Status bit discussed
Sleep and Wakeup sequence documented
PIT Timer registers’ R/W capability corrected to read only
Modified Free Running Counter text in section 17.1.1
*C
524104
See ECN
Document 38-16016 Rev. *C
Description of Change
KKVTMP Change title from Wireless enCoRe II to enCoRe II Low Voltage
Page 62 of 62
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