ETC Z86E3116SEC

PRELIMINARY PRODUCT SPECIFICATION
1
Z86E30/E31/E40
1
Z8 4K OTP MICROCONTROLLER
FEATURES
Device
ROM
(KB)
RAM*
(Bytes)
I/O
Lines
Speed
(MHz)
Z86E30
Z86E31
Z86E40
4
2
4
237
125
236
24
24
32
16
16
16
■
Programmable OTP Options:
RC Oscillator
EPROM Protect
Auto Latch Disable
Permanently Enabled WDT
Crystal Oscillator Feedback Resistor Disable
RAM Protect
■
Low-Power Consumption: 60 mW
■
Fast Instruction Pointer: 0.75 µs
Note: *General-Purpose
■
Standard Temperature (VCC = 3.5V to 5.5V)
■
Extended Temperature (VCC = 4.5V to 5.5V)
■
Available Packages:
28-Pin DIP/SOIC/PLCC OTP (Z86E30/31 only)
40-Pin DIP OTP (Z86E40 only)
44-Pin PLCC/QFP OTP (Z86E40 only)
■
Two Standby Modes: STOP and HALT
■
Digital Inputs CMOS Levels, Schmitt-Triggered
■
Software Programmable Low EMI Mode
■
Software Enabled Watch-Dog Timer (WDT)
■
■
Push-Pull/Open-Drain Programmable on
Port 0, Port 1, and Port 2
Two Programmable 8-Bit Counter/Timers Each
with a 6-Bit Programmable Prescaler
■
Six Vectored, Priority Interrupts from Six
Different Sources
■
Two Comparators
■
On-Chip Oscillator that Accepts a Crystal, Ceramic
Resonator, LC, RC, or External Clock Drive
■
24/32 Input/Output Lines
■
Auto Latches
■
Auto Power-On Reset (POR)
GENERAL DESCRIPTION
The Z86E30/E31/E40 8-Bit One-Time Programmable
(OTP) Microcontrollers are members of Zilog's single-chip
Z8® MCU family featuring enhanced wake-up circuitry,
programmable Watch-Dog Timers, Low Noise EMI options, and easy hardware/software system expansion capability.
Four basic address spaces support a wide range of memory configurations. The designer has access to three additional control registers that allow easy access to register
mapped peripheral and I/O circuits.
DS97Z8X0502
For applications demanding powerful I/O capabilities, the
Z86E30/E31 have 24 pins, and the Z86E40 has 32 pins of
dedicated input and output. These lines are grouped into
four ports, eight lines per port, and are configurable under
software control to provide timing, status signals, and parallel I/O with or without handshake, and address/data bus
for interfacing external memory.
Notes: All signals with a preceding front slash, “/”, are
active Low. For example, B/W (WORD is active Low); B/W
(BYTE is active Low, only).
PRELIMINARY
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Power connections follow conventional descriptions below:
Connection
Circuit
Device
Power
VCC
VDD
Ground
GND
VSS
(E40 Only)
Output Input
VCC
GND
XTAL AS DS R/W RESET
Machine Timing
&
Instruction Control
Port 3
Counter/
Timers (2)
RESET
WDT, POR
ALU
FLAGS
Interrupt
Control
OTP
Two Analog
Comparators
Register
Pointer
Register File
Program
Counter
Port 0
Port 1
Port 2
4
I/O
(Bit Programmable)
4
Address or I/O
(Nibble Programmable)
8
Address/Data or I/O
(Byte Programmable)
(E40 Only)
Figure 1. Z86E30/E31/E40 Functional Block Diagram
2
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
D7 - 0
1
AD 11- 0
Z8 MCU
MSN
Port 3
AD 11- 0
Address
MUX
D7 - 0
AD 11- 0
EPROM
TEST ROM
Z8
Port 0
Data
MUX
D7 - 0
Z8
Port 2
OTP
Options
PGM + Test
Mode Logic
VPP
P33
EPM
P32
OE
P31
PGM
P30
CE
XT1
Figure 2. EPROM Programming Block Diagram
DS97Z8X0502
PRELIMINARY
3
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PIN IDENTIFICATION
Table 1. 40-Pin DIP Pin Identification
Standard Mode
R/W
P25
P26
P27
P04
P05
P06
P14
P15
P07
VCC
P16
P17
XTAL2
XTAL1
P31
P32
P33
P34
AS
1
40
40-Pin DIP
20
21
DS
P24
P23
P22
P21
P20
P03
P13
P12
GND
P02
P11
P10
P01
P00
P30
P36
P37
P35
RESET
Figure 3. 40-Pin DIP Pin Configuration
Standard Mode
4
Pin #
Symbol
Function
Direction
1
2–4
5–7
8–9
10
11
R/W
P25–P27
P04–P06
P14–P15
P07
VCC
Read/Write
Port 2, Pins 5,6,7
Port 0, Pins 4,5,6
Port 1, Pins 4,5
Port 0, Pin 7
Power Supply
Output
In/Output
In/Output
In/Output
In/Output
12–13
14
15
16–18
19
20
21
22
23
24
25
26–27
28–29
30
31
32–33
34
35–39
40
P16–P17
XTAL2
XTAL1
P31–P33
P34
AS
RESET
P35
P37
P36
P30
P00–P01
P10–P11
P02
GND
P12–P13
P03
P20–P24
DS
Port 1, Pins 6,7
Crystal Oscillator
Crystal Oscillator
Port 3, Pins 1,2,3
Port 3, Pin 4
Address Strobe
Reset
Port 3, Pin 5
Port 3, Pin 7
Port 3, Pin 6
Port 3, Pin 0
Port 0, Pins 0,1
Port 1, Pins 0,1
Port 0, Pin 2
Ground
Port 1, Pins 2,3
Port 0, Pin 3
Port 2, Pins 0,1,2,3,4
Data Strobe
In/Output
Output
Input
Input
Output
Output
Input
Output
Output
Output
Input
In/Output
In/Output
In/Output
PRELIMINARY
In/Output
In/Output
In/Output
Output
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
P20
P03
P13
P12
GND
GND
P02
P11
P10
P01
P00
1
6
1
40
39
7
44-Pin PLCC
17
29
28
18
P30
P36
P37
P35
RESET
R/RL
AS
P34
P33
P32
P31
P05
P06
P14
P15
P07
VCC
VCC
P16
P17
XTAL2
XTAL1
P21
P22
P23
P24
DS
NC
R/W
P25
P26
P27
P04
Figure 4. 44-Pin PLCC Pin Configuration
Standard Mode
Table 2. 44-Pin PLCC Pin Identification
Pin #
Symbol
Function
1–2
3–4
5
6–10
11
12
13
14–16
17–19
20–21
22
23–24
GND
P12–P13
P03
P20–P24
DS
NC
R/W
P25–P27
P04–P06
P14–P15
P07
VCC
Ground
Port 1, Pins 2,3
Port 0, Pin 3
Port 2, Pins 0,1,2,3,4
Data Strobe
No Connection
Read/Write
Port 2, Pins 5,6,7
Port 0, Pins 4,5,6
Port 1, Pins 4,5
Port 0, Pin 7
Power Supply
25–26
27
28
29–31
32
P16–P17
XTAL2
XTAL1
P31–P33
P34
Port 1, Pins 6,7
Crystal Oscillator
Crystal Oscillator
Port 3, Pins 1,2,3
Port 3, Pin 4
DS97Z8X0502
Direction
In/Output
In/Output
In/Output
Output
Output
In/Output
In/Output
In/Output
In/Output
Table 2. 44-Pin PLCC Pin Identification
Pin #
Symbol
Function
Direction
33
34
35
36
37
38
39
40–41
42–43
44
AS
R/RL
RESET
P35
P37
P36
P30
P00–P01
P10–P11
P02
Address Strobe
ROM/ROMless select
Reset
Port 3, Pin 5
Port 3, Pin 7
Port 3, Pin 6
Port 3, Pin 0
Port 0, Pins 0,1
Port 1, Pins 0,1
Port 0, Pin 2
Output
Input
Input
Output
Output
Output
Input
In/Output
In/Output
In/Output
In/Output
Output
Input
Input
Output
PRELIMINARY
5
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
P20
P03
P13
P12
GND
GND
P02
P11
P10
P01
P00
PIN IDENTIFICATION (Continued)
33
23
22
34
P21
P22
P23
P24
DS
NC
R/W
P25
P26
P27
P04
44-Pin QFP
12
11
44
P05
P06
P14
P15
P07
VCC
VCC
P16
P17
XTAL2
XTAL1
1
P30
P36
P37
P35
RESET
R/RL
AS
P34
P33
P32
P31
Figure 5. 44-Pin QFP Pin Configuration
Standard Mode
Table 3. 44-Pin QFP Pin Identification
Table 3. 44-Pin QFP Pin Identification
Pin #
Symbol
Function
Direction
Pin #
Symbol
Function
Direction
1–2
3–4
5
6–7
P05–P06
P14–P15
P07
VCC
Port 0, Pins 5,6
Port 1, Pins 4,5
Port 0, Pin 7
Power Supply
In/Output
In/Output
In/Output
P16–P17
XTAL2
XTAL1
P31–P33
P34
AS
R/RL
RESET
P35
P37
P36
P30
P00–P01
P10–P11
Port 1, Pins 6,7
Crystal Oscillator
Crystal Oscillator
Port 3, Pins 1,2,3
Port 3, Pin 4
Address Strobe
ROM/ROMless select
Reset
Port 3, Pin 5
Port 3, Pin 7
Port 3, Pin 6
Port 3, Pin 0
Port 0, Pin 0,1
Port 1, Pins 0,1
In/Output
Output
Input
Input
Output
Output
Input
Input
Output
Output
Output
Input
In/Output
In/Output
P02
GND
P12–P13
P03
P20–4
DS
NC
R/W
P25–P27
P04
Port 0, Pin 2
Ground
Port 1, Pins 2,3
Port 0, Pin 3
Port 2, Pins 0,1,2,3,4
Data Strobe
No Connection
Read/Write
Port 2, Pins 5,6,7
Port 0, Pin 4
In/Output
8–9
10
11
12–14
15
16
17
18
19
20
21
22
23–24
25–26
27
28–29
30–31
32
33–37
38
39
40
41–43
44
6
PRELIMINARY
In/Output
In/Output
In/Output
Output
Output
In/Output
In/Output
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Table 4. 40-Pin DIP Package Pin Identification
EPROM Mode
NC
D5
D6
D7
A4
A5
A6
NC
NC
A7
VCC
NC
NC
NC
CE
OE
EPM
VPP
A8
NC
1
40
40-Pin DIP
20
21
NC
D4
D3
D2
D1
D0
A3
NC
NC
GND
A2
NC
NC
A1
A0
PGM
A10
A11
A9
NC
Figure 6. 40-Pin DIP Pin Configuration
EPROM Mode
DS97Z8X0502
Pin #
Symbol
Function
1
2–4
5–7
8–9
10
11
NC
D5–D7
A4–A6
NC
A7
VCC
No Connection
Data 5,6,7
Address 4,5,6
No Connection
Address 7
Power Supply
12–14
15
16
17
18
NC
CE
OE
EPM
VPP
No Connection
Chip Select
Output Enable
EPROM Prog. Mode
Prog. Voltage
19
20–21
22
23
24
25
26–27
28–29
30
31
32–33
34
35–39
40
A8
NC
A9
A11
A10
PGM
A0–A1
NC
A2
GND
NC
A3
D0–D4
NC
Address 8
No Connection
Address 9
Address 11
Address 10
Prog. Mode
Address 0,1
No Connection
Address 2
Ground
No Connection
Address 3
Data 0,1,2,3,4
No Connection
PRELIMINARY
1
Direction
In/Output
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
In/Output
7
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
D0
A3
NC
NC
GND
GND
A2
NC
NC
A1
A0
PIN IDENTIFICATION (Continued)
6
1
40
39
7
44-Pin PLCC
17
29
28
18
PGM
A10
A11
A9
NC
NC
NC
A8
VPP
EPM
OE
A5
A6
NC
NC
A7
VCC
VCC
NC
NC
NC
CE
D1
D2
D3
D4
NC
NC
NC
D5
D6
D7
A4
Figure 7. 44-Pin PLCC Pin Configuration
EPROM Programming Mode
Table 5. 44-Pin PLCC Pin Configuration
EPROM Programming Mode
Pin #
Symbol
Function
1–2
3–4
5
6–10
11–13
14–16
17–19
20–21
22
23–24
GND
NC
A3
D0–D4
NC
D5–D7
A4–A6
NC
A7
VCC
Ground
No Connection
Address 3
Data 0,1,2,3,4
No Connection
Data 5,6,7
Address 4,5,6
No Connection
Address 7
Power Supply
25–27
28
29
30
NC
CE
OE
EPM
No Connection
Chip Select
Output Enable
EPROM Prog.
Mode
8
Direction
Input
In/Output
In/Output
Input
Input
Table 5. 44-Pin PLCC Pin Configuration
EPROM Programming Mode
Pin #
Symbol
Function
Direction
31
VPP
Prog. Voltage
Input
32
33–35
36
37
38
39
40–41
42–43
44
A8
NC
A9
A11
A10
PGM
A0,A1
NC
A2
Address 8
No Connection
Address 9
Address 11
Address 10
Prog. Mode
Address 0,1
No Connection
Address 2
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
D0
A3
NC
NC
GND
GND
A2
NC
NC
A1
A0
1
33
D1
D2
D3
D4
NC
NC
NC
D5
D6
D7
A4
23
22
34
44 -Pin QFP
12
11
44
A5
A6
NC
NC
NC
A7
VCC
VCC
NC
NC
CE
1
PGM
A10
A11
A9
NC
NC
NC
A8
VPP
EPM
OE
Figure 8. 44-Pin QFP Pin Configuration
EPROM Programming Mode
Table 6. 44-Pin QFP Pin Identification
EPROM Programming Mode
Table 6. 44-Pin QFP Pin Identification
EPROM Programming Mode
Pin #
Symbol
Function
Direction
Pin #
Symbol
Function
Direction
1–2
3–4
5
6–7
A5–A6
NC
A7
VCC
Address 5,6
No Connection
Address 7
Power Supply
Input
NC
CE
OE
EPM
14
VPP
No Connection
Chip Select
Output Enable
EPROM Prog.
Mode
Prog. Voltage
A0,A1
NC
A2
GND
NC
A3
D0–D4
NC
D5–D7
A4
Address 0,1
No Connection
Address 2
Ground
No Connection
Address 3
Data 0,1,2,3,4
No Connection
Data 5,6,7
Address 4
Input
8–10
11
12
13
23–24
25–26
27
28–29
30–31
32
33–37
38–40
41–43
44
15
16–18
19
20
21
22
A8
NC
A9
A11
A10
PGM
Address 8
No Connection
Address 9
Address 11
Address 10
Prog. Mode
DS97Z8X0502
Input
Input
Input
Input
Input
Input
Input
In/Output
In/Output
Input
Input
Input
Input
Input
Input
PRELIMINARY
9
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PIN IDENTIFICATION (Continued)
P25
P26
P27
P04
P05
P06
P07
VCC
XTAL2
XTAL1
P31
P32
P33
P34
1
28
28-Pin DIP
14
15
P24
P23
P22
P21
P20
P03
VSS
P02
P01
P00
P30
P36
P37
P35
D5
D6
D7
A4
A5
A6
A7
VCC
NC
CE
OE
EPM
VPP
A8
Figure 9. Standard Mode
28-Pin DIP/SOIC Pin Configuration
1
28
28-Pin DIP
14
15
D4
D3
D2
D1
D0
A3
VSS
A2
A1
A0
PGM
A10
A11
A9
Figure 10. EPROM Programming Mode
28-Pin DIP/SOIC Pin Configuration
Table 7. 28-Pin DIP/SOIC/PLCC
Pin Identification*
Function
Direction
1–3
4–7
8
P25–P27
P04–P07
VCC
Port 2, Pins 5,6,
In/Output
Port 0, Pins 4,5,6,7 In/Output
Power Supply
9
10
11–13
14–15
16
17
18
19–21
22
XTAL2
XTAL1
P31–P33
P34–P35
P37
P36
P30
P00–P02
VSS
Crystal Oscillator
Crystal Oscillator
Port 3, Pins 1,2,3
Port 3, Pins 4,5
Port 3, Pin 7
Port 3, Pin 6
Port 3, Pin 0
Port 0, Pins 0,1,2
Ground
Output
Input
Input
Output
Output
Output
Input
In/Output
23
24–28
P03
P20–P24
Port 0, Pin 3
Port 2, Pins
0,1,2,3,4
In/Output
In/Output
P04
P27
P26
P25
P24
P23
P22
Symbol
4
XXX
P05
P06
XXX
P07
XXX
VCC
XXX
XXX
XT2
XXX
XT1
XXX
P31
1
5
26
25
28-Pin PLCC
11
12
19
18
P21
XXX
XXX
P20
XXX
P03
XXX
V
SS
XXX
P02
XXX
P01
XXX
P00
P32
P33
P34
P35
P37
P36
P30
Pin #
Figure 11. Standard Mode
28-Pin PLCC Pin Configuration
10
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
A4
D7
D6
D5
D4
D3
D2
Table 8. 28-Pin EPROM
Pin Identification
4
1
5
26
25
28-Pin PLCC
19
18
D1
XXX
XXX
D0
XXX
A3
XXX
V
SS
XXX
A2
XXX
A1
XXX
A0
A8
A9
A11
A10
PGM
11
12
EPM
VPP
XXX
A5
XXX
A6
XXX
A7
VCC
XXX
XXX
NC
XXX
CE
XXX
OE
Figure 12. EPROM Programming Mode
28-Pin PLCC Pin Configuration
DS97Z8X0502
Pin #
Symbol
Function
Direction
1–3
4–7
8
D5–D7
A4–A7
VCC
Data 5,6,7
Address 4,5,6,7
Power Supply
In/Output
Input
9
10
11
12
NC
CE
OE
EPM
13
VPP
No connection
Chip Select
Output Enable
EPROM Prog.
Mode
Prog. Voltage
14–15
16
17
18
19–21
22
A8–A9
A11
A10
PGM
A0–A2
VSS
Address 8,9
Address 11
Address 10
Prog. Mode
Address 0,1,2
Ground
Input
Input
Input
Input
Input
23
24–28
A3
D0–D4
Address 3
Data 0,1,2,3,4
Input
In/Output
PRELIMINARY
1
Input
Input
Input
Input
11
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
ABSOLUTE MAXIMUM RATINGS
Parameter
Min
Max
Units
Ambient Temperature under Bias
Storage Temperature
Voltage on any Pin with Respect to VSS [Note 1]
–40
–65
–0.6
+105
+150
+7
C
C
V
Voltage on VDD Pin with Respect to VSS
–0.3
+7
V
Voltage on XTAL1 and RESET Pins with Respect to VSS [Note 2]
–0.6
VDD+1
V
Total Power Dissipation
Maximum Allowable Current out of VSS
1.21
220
W
mA
Maximum Allowable Current into VDD
180
mA
+600
+600
25
25
3 mA
µA
µA
mA
mA
Maximum Allowable Current into an Input Pin [Note 3]
Maximum Allowable Current into an Open-Drain Pin [Note 4]
Maximum Allowable Output Current Sinked by Any I/O Pin
Maximum Allowable Output Current Sourced by Any I/O Pin
Maximum Allowable Output Current Sinked by RESET Pin
–600
–600
Notes:
1. This applies to all pins except XTAL pins and where otherwise noted.
2. There is no input protection diode from pin to VDD.
3. This excludes XTAL pins.
4. Device pin is not at an output Low state.
Stresses greater than those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the
device at any condition above those indicated in the operational sections of these specifications is not implied. Exposure to absolute maximum rating conditions for an extended period may affect device reliability.
Total power dissipation should not exceed 1.2 W for the
package. Power dissipation is calculated as follows:
Total Power Dissipation = VDD x [ IDD – (sum of IOH) ]
+ sum of [ (VDD – VOH) x IOH ]
+ sum of (V0L x I0L)
STANDARD TEST CONDITIONS
The characteristics listed below apply for standard test
conditions as noted. All voltages are referenced to
Ground. Positive current flows into the referenced pin
(Test Load).
From Output
Under Test
150 pF
Figure 13. Test Load Diagram
12
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
CAPACITANCE
TA = 25°C, VCC = GND = 0V, f = 1.0 MHz; unmeasured pins returned to GND.
Parameter
Min
Max
0
0
0
12 pF
12 pF
12 pF
Input capacitance
Output capacitance
I/O capacitance
1
DC ELECTRICAL CHARACTERISTICS
TA= 0 °C to +70 °C
Sym
Parameter
VCC
Note [3]
Min
Max
Typical
@ 25°C
Units
Conditions
Notes
VCH
Clock Input High Voltage
3.5V
5.5V
0.7 VCC
0.7 VCC
VCC+0.3
VCC+0.3
1.8
2.5
V
V
Driven by External
Clock Generator
VCL
Clock Input Low Voltage
3.5V
4.5V
GND -0.3
GND -0.3
0.2 VCC
0.2 VCC
0.9
1.5
V
V
Driven by External
Clock Generator
VIH
Input High Voltage
3.5V
5.5V
0.7 VCC
0.7 VCC
VCC+0.3
VCC+0.3
2.5
2.5
V
V
VIL
Input Low Voltage
3.5V
5.5V
GND -0.3
GND -0.3
0.2 VCC
0.2 VCC
1.5
1.5
V
V
VOH
Output High Voltage
Low EMI Mode
3.5V
5.5V
VCC -0.4
VCC -0.4
3.3
4.8
V
V
IOH = – 0.5 mA
VOH1
Output High Voltage
3.5V
5.5V
VCC -0.4
VCC -0.4
3.3
4.8
V
V
IOH = -2.0 mA
IOH = -2.0 mA
VOL
Output Low Voltage
Low EMI Mode
3.5V
4.5V
0.4
0.4
0.2
0.2
V
V
IOL = 1.0 mA
IOL = 1.0 mA
VOL1
Output Low Voltage
3.5V
4.5V
0.4
0.4
0.1
0.1
V
V
IOL = + 4.0 mA
IOL = + 4.0 mA
8
8
VOL2
Output Low Voltage
3.5V
4.5V
1.2
1.2
0.5
0.5
V
V
IOL = + 12 mA
IOL = + 12 mA
8
8
VRH
Reset Input High
Voltage
3.5V
5.5V
.8 VCC
.8 VCC
VCC
VCC
1.7
2.1
V
V
VRL
Reset Input Low Voltage
3.5V
5.5V
GND -0.3
GND -0.3
0.2 VCC
0.2 VCC
1.3
1.7
V
V
VOLR
Reset Output Low
Voltage
3.5V
5.5V
0.6
0.6
0.3
0.2
V
V
VOFFSET
Comparator Input
Offset Voltage
Input Common Mode
Voltage Range
3.5V
4.5V
3.5V
5.5V
10
10
0
0
25
25
VCC -1.0V
VCC -1.0V
mV
mV
V
V
IIL
Input Leakage
3.5V
4.5V
-1
-1
2
2
0.032
0.032
µA
µA
VIN = 0V, VCC
VIN = 0V, VCC
IOL
Output Leakage
3.5V
4.5V
-1
-1
2
2
0.032
0.032
µA
µA
VIN = 0V, VCC
VIN = 0V, VCC
IIR
Reset Input Current
3.5V
4.5V
-20
-20
-130
-180
-65
-112
µA
µA
VICR
DS97Z8X0502
PRELIMINARY
13
IOL = 1.0 mA
IOL = 1.0 mA
10
10
13
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
DC ELECTRICAL CHARACTERISTICS (Continued)
TA= 0 °C to +70 °C
Sym
Parameter
ICC
Supply Current
ICC1
Standby Current
Halt Mode
VCC
Note [3]
Max
Typical
@ 25°C
Units
3.5V
5.5V
3.5V
5.5V
20
25
8
8
7
20
3.7
3.7
mA
mA
mA
mA
7.0
7.0
10
10
800
800
2.9
2.9
2
3
600
600
mA
mA
µA
µA
µA
µA
Min
Conditions
@ 16 MHz
@ 16 MHz
VIN = 0V, VCC
@ 16 MHz
Clock Divide by
16 @ 16 MHz
VIN = 0V, VCC
VIN = 0V, VCC
VIN = 0V, VCC
VIN = 0V, VCC
Notes
4,5
4,5
4,5
4,5
ICC2
Standby Current
Stop Mode
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
IALL
Auto Latch
Low Current
3.5V
5.5V
0.7
1.4
8
15
2.4
4.7
µA
µA
0V <VIN<VCC
0V <VIN<VCC
4,5
4,5
6,11
6,11
6,11,1
4
6,11,1
4
9
9
IALH
Auto Latch
High Current
3.5V
5.5V
-0.6
-1
-5
-8
-1.8
-3.8
µA
µA
0V<VIN<VCC
0V<VIN<VCC
9
9
TPOR
Power On Reset
3.5V
5.5V
VLV
Auto Reset Voltage
3.0
2.0
2.3
24
13
3.1
7
4
2.9
ms
ms
V
1,7
Notes:
1. Device does function down to the Auto Reset voltage.
2. GND=0V
3. The VCC voltage specification of 5.5V guarantees 5.0V ± 0.5V and
the VCC voltage specification of 3.5V guarantees only 3.5V.
4. All outputs unloaded, I/O pins floating, inputs at rail.
5. CL1= CL2 = 22 pF
6. Same as note [4] except inputs at VCC.
7. Max. temperature is 70°C.
8. STD Mode (not Low EMI Mode)
9. Auto Latch (mask option) selected
10. For analog comparator inputs when analog comparators are
enabled.
11. Clock must be forced Low, when XTAL1 is clock driven and XTAL2
is floating.
12. Typicals are at VCC = 5.0V and VCC = 3.5V
13. Z86E40 only
14. WDT running
14
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
TA=–40 °C to +105 °C
Sym
Parameter
VCC
Note [3]
Min
Max
Typical
@ 25°C
Units
Conditions
VCH
Clock Input High
Voltage
4.5V
5.5V
0.7 VCC
0.7 VCC
VCC+0.3
VCC+0.3
2.5
2.5
V
V
Driven by External
Clock Generator
VCL
Clock Input Low
Voltage
4.5V
5.5V
GND-0.3
GND-0.3
0.2 VCC
0.2 VCC
1.5
1.5
V
V
Driven by External
Clock Generator
VIH
Input High Voltage
4.5V
5.5V
0.7 VCC
0.7 VCC
VCC+0.3
VCC+0.3
2.5
2.5
V
V
VIL
Input Low Voltage
4.5V
5.5V
GND-0.3
GND-0.3
0.2 VCC
0.2 VCC
1.5
1.5
V
V
VOH
Output High
Voltage Low EMI
Mode
Output High Voltage
4.5V
5.5V
VCC -0.4
VCC -0.4
4.8
4.8
V
V
IOH = – 0.5 mA
IOH = – 0.5 mA
8
8
4.5V
4.5V
VCC -0.4
VCC -0.4
4.8
4.8
V
V
IOH = -2.0 mA
IOH = -2.0 mA
8
8
VOL
Output Low Voltage
Low EMI Mode
4.5V
5.5V
0.4
0.4
0.2
0.2
V
V
IOL = 1.0 mA
IOL = 1.0 mA
VOL1
Output Low Voltage
4.5V
5.5V
0.4
0.4
0.1
0.1
V
V
IOL = + 4.0 mA
IOL = +4.0 mA
8
8
VOL2
Output Low Voltage
4.5V
5.5V
1.2
1.2
0.5
0.5
V
V
IOL = + 12 mA
IOL = + 12 mA
8
8
VRH
Reset Input High
Voltage
3.5V
5.5V
VCC
VCC
1.7
2.1
V
V
VOLR
Reset Output Low
Voltage
3.5V
5.5V
0.6
0.6
0.3
0.2
V
V
VOFFSET Comparator Input
Offset Voltage
VICR
Input Common
Mode Voltage
Range
Input Leakage
IIL
4.5V
5.5V
4.5V
5.5V
0
0
25
25
VCC-1.5V
VCC-1.5V
4.5V
5.5V
4.5V
5.5V
-1
-1
-1
-1
2
2
2
2
<1
<1
<1
<1
µA
µA
µA
µA
4.5V
5.5V
4.5V
5.5V
4.5V
-18
-18
-180
-180
25
25
8
-112
-112
20
20
3.7
µA
µA
mA
mA
mA
5.5V
8
3.7
mA
10
10
2
3
20
20
4.7
4.7
VOH1
IOL
Output Leakage
IIR
Reset Input Current
ICC
Supply Current
ICC1
Standby Current
Halt Mode
ICC2
Standby Current
(Stop Mode)
4.5V
5.5V
IALL
Auto Latch Low
Current
4.5V
5.5V
DS97Z8X0502
.8 VCC
.8 VCC
1.4
1.4
10
10
PRELIMINARY
1
Notes
13
13
IOL = 1.0 mA
IOL = 1.0 mA
mV
mV
V
V
13
13
10
10
VIN = 0V, VCC
VIN = 0V, VCC
VIN = 0V, VCC
VIN = 0V, VCC
µA
µA
@ 16 MHz
@ 16 MHz
VIN = 0V, VCC
@ 16 MHz
VIN = 0V, VCC
@ 16 MHz
VIN = 0V, VCC
VIN = 0V, VCC
4,5
4,5
4,5
6,11,14
6,11,14
µA
µA
0V < VIN < VCC
0V < VIN < VCC
9
9
4,5
15
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
DC ELECTRICAL CHARACTERISTICS (Continued)
TA=–40 °C to +105 °C
Sym
Parameter
VCC
Note [3]
Min
Max
Typical
@ 25°C
Units
IALH
Auto Latch High
Current
4.5V
5.5V
-1.0
-1.0
-10
-10
-3.8
-3.8
µA
µA
TPOR
Power On Reset
4.5V
5.5V
VLV
Auto Reset Voltage
2.0
2.0
2.0
14
14
3.3
4
4
2.9
mS
mS
V
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
16
Conditions
0V < VIN < VCC
0V < VIN < VCC
Notes
9
9
1
Device does function down to the Auto Reset voltage.
GND=0V
The VCC voltage specification of 5.5V guarantees 5.0V ± 0.5V.
All outputs unloaded, I/O pins floating, inputs at rail.
CL1= CL2 = 22 pF
Same as note [4] except inputs at VCC.
Maximum temperature is 70°C
STD Mode (not Low EMI Mode)
Auto Latch (mask option) selected
For analog comparator inputs when analog comparators are
enabled.
Clock must be forced Low, when XTAL1 is clock driven and XTAL2
is floating.
Typicals are at VCC = 5.0V
Z86E40 only
WDT is not running.
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
R/W , DM
1
13
12
19
Port 0
16
18
Port 1
20
3
A7 - A0
1
D7 - D0 IN
2
9
AS
8
11
4
5
DS
(Read)
6
17
10
Port1
A7 - A0
D7 - D0 OUT
14
15
7
DS
(W rite)
Figure 14. External I/O or Memory Read/Write Timing
Z86E40 Only
DS97Z8X0502
PRELIMINARY
17
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
DC ELECTRICAL CHARACTERISTICS (Continued)
TA = 0°C to 70°C
16 MHz
No
Symbol
Note [3]
VCC
Parameter
1
TdA(AS)
2
TdAS(A)
3
TdAS(DR)
4
TwAS
Address Valid to AS Rise
Delay
AS Rise to Address Float
Delay
AS Rise to Read Data Req’d
Valid
AS Low Width
5
TdAS(DS)
Address Float to DS Fall
6
TwDSR
DS (Read) Low Width
7
TwDSW
DS (Write) Low Width
8
TdDSR(DR)
9
ThDR(DS)
10
TdDS(A)
11
TdDS(AS)
DS Fall to Read Data Req’d
Valid
Read Data to DS Rise Hold
Time
DS Rise to Address Active
Delay
DS Rise to AS Fall Delay
12
TdR/W(AS)
R/W Valid to AS Rise Delay
13
TdDS(R/W)
DS Rise to R/W Not Valid
14
TdDW(DSW)
15
TdDS(DW)
16
TdA(DR)
17
TdAS(DS)
Write Data Valid to DS Fall
(Write) Delay
DS Rise to Write Data Not
Valid Delay
Address Valid to Read Data
Req’d Valid
AS Rise to DS Fall Delay
18
TdDM(AS)
DM Valid to AS Fall Delay
20
ThDS(AS)
DS Valid to Address Valid
Hold Time
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
Min
Max
25
25
35
35
180
180
40
40
0
0
135
135
80
80
75
75
0
0
50
50
35
35
25
25
35
35
55
55
35
35
25
25
230
230
45
45
30
30
35
35
Units
Notes
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
2
2
1,2
2
1,2
1,2
1,2
2
2
2
2
2
2
2
1,2
2
2
Notes:
1. When using extended memory timing, add 2 TpC.
2. Timing numbers given are for minimum TpC.
3. The VCC voltage specification of 5.5V guarantees 5.0V ±0.5V and
the VCC voltage specification of 3.5V guarantees only 3.5V
Standard Test Load
All timing references use 0.7 VCC for a logic 1 and 0.2 VCC for a logic 0.
For Standard Mode (not Low-EMI Mode for outputs) with SMR D1 = 0, D0 = 0.
18
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
No
Symbol
TA = -40°C to 105°C
16 MHz
Note [3]
VCC
Min
Max
Parameter
1
TdA(AS)
2
TdAS(A)
3
TdAS(DR)
4
TwAS
Address Valid to AS Rise
Delay
ASAS Rise to Address Float
Delay
AS Rise to Read Data Req’d
Valid
AS Low Width
5
TdAS(DS)
Address Float to DS Fall
6
TwDSR
DS (Read) Low Width
7
TwDSW
DS (Write) Low Width
8
TdDSR(DR)
9
ThDR(DS)
10
TdDS(A)
11
TdDS(AS)
DS Fall to Read Data Req’d
Valid
Read Data to DS Rise Hold
Time
DS Rise to Address Active
Delay
DS Rise to AS Fall Delay
12
TdR/W(AS)
R/W Valid to AS Rise Delay
13
TdDS(R/W)
DS Rise to R/W Not Valid
14
TdDW(DSW)
15
TdDS(DW)
16
TdA(DR)
17
TdAS(DS)
Write Data Valid to DS Fall
(Write) Delay
DS Rise to Write Data Not
Valid Delay
Address Valid to Read Data
Req’d Valid
AS Rise to DS Fall Delay
18
TdDM(AS)
/DM Valid to AS Fall Delay
20
ThDS(AS)
DS Valid to Address Valid
Hold Time
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
4.5V
5.5V
25
25
35
35
180
180
40
40
0
0
135
135
80
80
75
75
0
0
50
50
35
35
25
25
35
35
55
55
35
35
25
25
230
230
45
45
30
30
35
35
1
Units
Notes
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
2
2
1,2
2
1,2
1,2
1,2
2
2
2
2
2
2
2
1,2
2
2
Notes:
1. When using extended memory timing, add 2 TpC.
2. Timing numbers given are for minimum TpC.
3. The VCC voltage specification of 5.5V guarantees 5.0V ±0.5V and
the VCC voltage specification of 3.5V guarantees only 3.5V
Standard Test Load
All timing references use 0.7 VCC for a logic 1 and 0.2 VCC for a logic 0.
For Standard Mode (not Low-EMI Mode for outputs) with SMR, D1 = 0, D0 = 0.
DS97Z8X0502
PRELIMINARY
19
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
DC ELECTRICAL CHARACTERISTICS (Continued)
3
1
Clock
2
7
2
3
7
TIN
4
5
6
IRQN
8
9
Clock
Setup
11
Stop
Mode
Recovery
Source
10
Figure 15. Additional Timing Diagram
20
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Additional Timing Table (Divide-By-One Mode)
TA = 0 °C to +70 °C
4 MHz
No
Symbol
Parameter
1
TpC
Input Clock Period
2
TrC,TfC
3
TwC
Clock Input Rise &
Fall Times
Input Clock Width
4
TwTinL
5
TwTinH
6
TpTin
7
TrTin, TfTin Timer Input Rise
& Fall Timer
TwIL
Int. Request Low
Time
TwIL
Int. Request Low
Time
TwIH
Int. Request Input
High Time
Twsm
STOP Mode
Recovery Width
Spec
Tost
Oscillator Startup
Time
8A
8B
9
10
11
Timer Input Low
Width
Timer Input High
Width
Timer Input Period
VCC
Note [6]
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
TA = -40 °C to +105 °C
1
4 MHz
Min
Max
Min
Max
Units
Notes
250
250
DC
DC
25
25
250
250
DC
DC
25
25
ns
ns
ns
ns
ns
ns
ns
ns
100
100
ns
ns
ns
ns
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,2,7,8
1,2,7,8
1,3,7,8
1,3,7,8
1,2,7,8
1,2,7,8
4,8
4,8
100
100
100
70
5TpC
5TpC
8TpC
8TpC
100
100
100
70
5TpC
5TpC
8TpC
8TpC
100
100
100
70
5TpC
5TpC
5TpC
5TpC
12
12
3.5V
5.5V
100
70
5TpC
5TpC
5TpC
5TpC
12
12
5TpC
5TpC
ns
ns
5TpC
4,8,9
Notes:
1. Timing Reference uses 0.7 VCC for a logic 1 and 0.2 VCC for a logic 0.
2. Interrupt request via Port 3 (P31–P33).
3. Interrupt request via Port 3 (P30).
4. SMR-D5 = 1, POR STOP Mode Delay is on.
5. Reg. WDTMR.
6. The VCC voltage specification of 5.5V guarantees 5.0V ± 0.5V and
the VCC voltage specification of 3.5V guarantees 3.5V only.
7. SMR D1 = 0.
8. Maximum frequency for internal system clock is 4 MHz when
using XTAL divide-by-one mode.
9. For RC and LC oscillator, and for oscillator driven by clock driver.
DS97Z8X0502
PRELIMINARY
21
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
DC ELECTRICAL CHARACTERISTICS (Continued)
Handshake Timing Diagrams
Data In Valid
Data In
Next Data In Valid
1
2
3
DA V
(Input)
Delayed DAV
4
5
RDY
(Output)
6
Delayed RDY
Figure 16. Input Handshake Timing
Data Out
Data Out Valid
Next Data Out Valid
7
DAV
(Output)
Delayed DAV
8
9
11
10
RDY
(Input)
Delayed
RDY
Figure 17. Output Handshake Timing
22
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Additional Timing Table
TA = -40 °C to +105 °C
1
16 MHz
No
Symbol
Parameter
1
TpC
Input Clock Period
2
TrC,TfC
3
TwC
Clock Input Rise &
Fall Times
Input Clock Width
4
TwTinL
5
TwTinH
6
TpTin
7
TrTin, TfTin Timer Input Rise
& Fall Timer
TwIL
Int. Request Low
Time
TwIL
Int. Request Low
Time
TwIH
Int. Request Input
High Time
Twsm
STOP Mode
Recovery Width
Spec
Tost
Oscillator Startup
Time
Twdt
Watch-Dog Timer
Delay Time
Before Timeout
8A
8B
9
10
11
12
Timer Input Low
Width
Timer Input High
Width
Timer Input Period
VCC
Note [6]
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
3.5V
5.5V
Min
Max
Units
62.5
62.5
DC
DC
15
15
ns
ns
ns
ns
ns
ns
ns
ns
100
100
ns
ns
ns
ns
31
31
70
70
5TpC
5TpC
8TpC
8TpC
70
70
5TpC
5TpC
5TpC
12
12
Conditions
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,7,8
1,2,7,8
1,2,7,8
1,3,7,8
1,3,7,8
1,2,7,8
ns
ns
4,8
4,8
ms
ms
ms
ms
ms
ms
ms
ms
4,8
4,8
5,11
5,11
5,11
5,11
5,11
5,11
5,11
5,11
5TpC
5TpC
10
5
20
10
40
20
160
80
Notes
D0 = 0
D1 = 0
D0 = 1
D1 = 0
D0 = 0
D1 = 1
D0 = 1
D1 = 1
Notes:
1. Timing Reference uses 0.7 VCC for a logic 1 and 0.2 VCC for a logic 0.
2. Interrupt request via Port 3 (P31–P33)
3. Interrupt request via Port 3 (P30)
4. SMR-D5 = 1, POR STOP Mode Delay is on
5. Reg. WDTMR
6. The VCC voltage spec. of 5.5V guarantees 5.0V ± 0.5V.
7. SMR D1 = 0
8. Maximum frequency for internal system clock is 4 MHz when using
XTAL divide-by-one mode.
9. For RC and LC oscillator, and for oscillator driven by clock driver.
10. Standard Mode (not Low EMI output ports)
11. Using internal RC
DS97Z8X0502
PRELIMINARY
23
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PIN FUNCTIONS
EPROM Programming Mode
D7–D0 Data Bus. The data can be read from or written to
external memory through the data bus.
A11–A0 Address Bus. During programming, the EPROM
address is written to the address bus.
VCC Power Supply. This pin must supply 5V during the
EPROM read mode and 6V during other modes.
CE Chip Enable (active Low). This pin is active during
EPROM Read Mode, Program Mode, and Program Verify
Mode.
OE Output Enable (active Low). This pin drives the direction of the Data Bus. When this pin is Low, the Data Bus is
output, when High, the Data Bus is input.
EPM EPROM Program Mode. This pin controls the different EPROM Program Mode by applying different voltages.
VPP Program Voltage. This pin supplies the program voltage.
PGM Program Mode (active Low). When this pin is Low,
the data is programmed to the EPROM through the Data
Bus.
Application Precaution
The production test-mode environment may be enabled
accidentally during normal operation if excessive noise
surges above VCC occur on pins XTAL1 and RESET.
In addition, processor operation of Z8 OTP devices may be
affected by excessive noise surges on the VPP, CE, EPM,
OE pins while the microcontroller is in Standard Mode.
Recommendations for dampening voltage surges in both
test and OTP mode include the following:
■
Using a clamping diode to VCC
■
Adding a capacitor to the affected pin
R/W Read/Write (output, write Low). The R/W signal is
Low when the CCP is writing to the external program or
data memory (Z86E40 only).
RESET Reset (input, active Low). Reset will initialize the
MCU. Reset is accomplished either through Power-On,
Watch-Dog Timer reset, STOP-Mode Recovery, or external reset. During Power-On Reset and Watch-Dog Timer
Reset, the internally generated reset drives the reset pin
low for the POR time. Any devices driving the reset line
must be open-drain in order to avoid damage from a possible conflict during reset conditions. Pull-up is provided internally. After the POR time, RESET is a Schmitt-triggered
input.
To avoid asynchronous and noisy reset problems, the
Z86E40 is equipped with a reset filter of four external
clocks (4TpC). If the external reset signal is less than 4TpC
in duration, no reset occurs. On the fifth clock after the reset is detected, an internal RST signal is latched and held
for an internal register count of 18 external clocks, or for
the duration of the external reset, whichever is longer. During the reset cycle, DS is held active Low while AS cycles
at a rate of TpC/2. Program execution begins at location
000CH, 5–10 TpC cycles after RESET is released. For
Power-On Reset, the reset output time is 5 ms. The
Z86E40 does not reset WDTMR, SMR, P2M, and P3M
registers on a STOP-Mode Recovery operation.
ROMless (input, active Low). This pin, when connected to
GND, disables the internal ROM and forces the device to
function as a Z86C90/C89 ROMless Z8. (Note that, when
left unconnected or pulled High to VCC, the device functions normally as a Z8 ROM version).
Note: When using in ROM Mode in High EMI (noisy) environment, the ROMless pins should be connected directly
to VCC.
Standard Mode
XTAL Crystal 1 (time-based input). This pin connects a
parallel-resonant crystal, ceramic resonator, LC, RC network, or external single-phase clock to the on-chip oscillator input.
XTAL2 Crystal 2 (time-based output). This pin connects a
parallel-resonant crystal, ceramic resonator, LC, or RC
network to the on-chip oscillator output.
24
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Port 0 (P07–P00). Port 0 is an 8-bit, bidirectional, CMOScompatible I/O port. These eight I/O lines can be configured under software control as a nibble I/O port, or as an
address port for interfacing external memory. The input
buffers are Schmitt-triggered and nibble programmed. Either nibble output that can be globally programmed as
push-pull or open-drain. Low EMI output buffers can be
globally programmed by the software. Port 0 can be placed
under handshake control. In Handshake Mode, Port 3
lines P32 and P35 are used as handshake control lines.
The handshake direction is determined by the configuration (input or output) assigned to Port 0's upper nibble. The
lower nibble must have the same direction as the upper
nibble.
nibble) depending on the required address space. If the
address range requires 12 bits or less, the upper nibble of
Port 0 can be programmed independently as I/O while the
lower nibble is used for addressing. If one or both nibbles
are needed for I/O operation, they must be configured by
writing to the Port 0 mode register. In ROMless mode, after
a hardware reset, Port 0 is configured as address lines
A15–A8, and extended timing is set to accommodate slow
memory access. The initialization routine can include reconfiguration to eliminate this extended timing mode. In
ROM mode, Port 0 is defined as input after reset.
Port 0 can be set in the High-Impedance Mode if selected
as an address output state, along with Port 1 and the control signals AS, DS, and R/W (Figure 18).
For external memory references, Port 0 provides address
bits A11–A8 (lower nibble) or A15–A8 (lower and upper
4
Port 0 (I/O)
4
Handshake Controls
/DAV0 and RDY0
(P32 and P35)
Open-Drain
OEN
PAD
Out
1.5
2.3V Hysteresis
In
Auto Latch
R
500 kΩ
Figure 18. Port 0 Configuration
DS97Z8X0502
PRELIMINARY
25
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PIN FUNCTIONS (Continued)
Port 1 (P17–P10). Port 1 is an 8-bit, bidirectional, CMOScompatible port with multiplexed Address (A7–A0) and
Data (D7–D0) ports. These eight I/O lines can be programmed as inputs or outputs or can be configured under
software control as an Address/Data port for interfacing
external memory. The input buffers are Schmitt-triggered
and the output buffers can be globally programmed as either push-pull or open-drain. Low EMI output buffers can
be globally programmed by the software. Port 1 can be
placed under handshake control. In this configuration, Port
3, lines P33 and P34 are used as the handshake controls
RDY1 and /DAV1 (Ready and Data Available). To interface external memory, Port 1 must be programmed for the
multiplexed Address/Data mode. If more than 256 external
locations are required, Port 0 outputs the additional lines
(Figure 19).
Port 1 can be placed in the high-impedance state along
with Port 0, AS, DS, and R/W, allowing the Z86E40 to
share common resources in multiprocessor and DMA applications.
Port 2 (I/O)
MCU
Handshake Controls
DAV1 and RDY1
(P33 and P34)
Open-Drain
OEN
PAD
Out
1.5
2.3V Hysteresis
In
Auto Latch
R
500 kΩ
Figure 19. Port 1 Configuration (Z86E40 Only)
26
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Port 2 (P27–P20). Port 2 is an 8-bit, bidirectional, CMOScompatible I/O port. These eight I/O lines can be configured under software control as an input or output, independently. All input buffers are Schmitt-triggered. Bits programmed as outputs can be globally programmed as
either push-pull or open-drain. Low EMI output buffers can
be globally programmed by the software. When used as an
I/O port, Port 2 can be placed under handshake control.
In Handshake Mode, Port 3 lines P31 and P36 are used as
handshake control lines. The handshake direction is determined by the configuration (input or output) assigned to bit
7 of Port 2 (Figure 20).
Port 2 (I/O)
Z86E40
MCU
Handshake Controls
DAV2 and RDY2
(P31 and P36)
Open-Drain
OEN
PAD
Out
TTL Level Shifter
In
Auto Latch
R ≈ 500 KΩ
Figure 20. Port 2 Configuration
DS97Z8X0502
PRELIMINARY
27
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PIN FUNCTIONS (Continued)
Port 3 (P37–P30). Port 3 is an 8-bit, CMOS-compatible
port with four fixed inputs (P33–P30) and four fixed outputs
(P37–P34). These eight lines can be configured by software for interrupt and handshake control functions. Port 3,
Pin 0 is Schmitt- triggered. P31, P32, and P33 are standard CMOS inputs with single trip point (no Auto Latches)
and P34, P35, P36, and P37 are push-pull output lines.
Low EMI output buffers can be globally programmed by
the software. Two on-board comparators can process analog signals on P31 and P32 with reference to the voltage
on P33. The analog function is enabled by setting the D1
of Port 3 Mode Register (P3M). The comparator output can
be outputted from P34 and P37, respectively, by setting
PCON register Bit D0 to 1 state. For the interrupt function,
P30 and P33 are falling edge triggered interrupt inputs.
P31 and P32 can be programmed as falling, rising or both
edges triggered interrupt inputs (Figure 21). Access to
Counter/Timer 1 is made through P31 (TIN) and P36
(TOUT). Handshake lines for Port 0, Port 1, and Port 2 are
also available on Port 3 (Table 9).
28
Note: When enabling/ or disabling analog mode, the following is recommended:
1. Allow two NOP delays before reading this comparator
output.
2. Disable global interrupts, switch to analog mode, clear
interrupts, and then re-enable interrupts.
3. IRQ register bits 3 to 0 must be cleared after enabling
analog mode.
Note: P33–P30 differs from the Z86C30/C31/C40 in that
there is no clamping diode to VCC due to the EPROM highvoltage circuits. Exceeding the VIH maximum specification
during standard operating mode may cause the device to
enter EPROM mode.
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
1
Z86E40
MCU
Port 3
(I/O or Control)
Auto Latch
R ≈ 500 KΩ
P30
P30 Data
Latch IRQ3
R247 = P3M
D1
1 = Analog
0 = Digital
DIG.
P31 (AN1)
IRQ2, Tin, P31 Data Latch
+
AN.
-
P32 (AN2)
IRQ0, P32 Data Latch
+
P33 (REF)
-
IRQ1, P33 Data Latch
From Stop Mode
Recovery Source
Figure 21. Port 3 Configuration
Table 9. Port 3 Pin Assignments
Pin
I/O
CTC1
Analog
Interrupt
P30
P31
IN
IN
TIN
AN1
IRQ3
IRQ2
P32
P33
P34
P35
P36
IN
IN
OUT
OUT
OUT
P37
OUT
DS97Z8X0502
AN2
REF
AN1-Out
IRQ0
IRQ1
P0 HS
P1 HS
P2 HS
Ext
D/R
D/R
D/R
R/D
/DM
R/D
TOUT
R/D
An2-Out
PRELIMINARY
29
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PIN FUNCTIONS (Continued)
Comparator Inputs. Port 3, P31, and P32, each have a
comparator front end. The comparator reference voltage
P33 is common to both comparators. In analog mode, P31
and P32 are the positive input of the comparators and P33
is the reference voltage of the comparators.
Auto Latch. The Auto Latch puts valid CMOS levels on all
CMOS inputs (except P33–P31) that are not externally
driven. Whether this level is 0 or 1, cannot be determined.
A valid CMOS level, rather than a floating node, reduces
excessive supply current flow in the input buffer. Auto
Latches are available on Port 0, Port 2, and P30. There
are no Auto Latches on P31, P32, and P33.
Low EMI Emission. The Z86E40 can be programmed to
operate in a low EMI Emission Mode in the PCON register.
The oscillator and all I/O ports can be programmed as low
EMI emission mode independently. Use of this feature results in:
30
■
The pre-drivers slew rate reduced to 10 ns typical.
■
Low EMI output drivers have resistance of 200 Ohms
(typical).
■
Low EMI Oscillator.
■
Internal SCLK/TCLK= XTAL operation limited to a
maximum of 4 MHz – 250 ns cycle time, when Low EMI
Oscillator is selected and system clock (SCLK = XTAL,
SMR Reg. Bit D1 =1).
■
Note for emulation only:
Do not set the emulator to emulate Port 1 in low EMI
mode. Port 1 must always be configured in Standard
Mode.
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION
The MCU incorporates the following special functions to
enhance the standard Z8 architecture to provide the user
with increased design flexibility.
RESET. The device is reset in one of three ways:
1. Power-On Reset
2. Watch-Dog Timer
3. STOP-Mode Recovery Source
Note: Having the Auto Power-On Reset circuitry built-in,
the MCU does not need to be connected to an external
power-on reset circuit. The reset time is 5 ms (typical). The
MCU does not reinitialize WDTMR, SMR, P2M, and P3M
registers to their reset values on a STOP-Mode Recovery
operation.
65535
4096
4095
Location of
First Byte of
Instruction
Executed
After RESET
Interrupt
Vector
(Lower Byte)
Interrupt
Vector
(Upper Byte)
Note: The device VCC must rise up to the operating VCC
specification before the TPOR expires.
Program Memory. The MCU can address up to 4 KB of
Internal Program Memory (Figure 22). The first 12 bytes of
program memory are reserved for the interrupt vectors.
These locations contain six 16-bit vectors that correspond
to the six available interrupts. For EPROM mode, byte 12
(000CH) to address 4095 (0FFFH) consists of programmable EPROM. After reset, the program counter points at
the address 000CH, which is the starting address of the
user program.
In ROMless mode, the Z86E40 can address up to 64 KB
of External Program Memory. The ROM/ROMless option
is only available on the 44-pin devices.
EPROM
ROMless
External
ROM and RAM
On-Chip One Time PROM
External
ROM and RAM
11
IRQ5
IRQ5
10
IRQ5
IRQ5
9
IRQ4
IRQ4
8
IRQ4
IRQ4
7
IRQ3
IRQ3
6
IRQ3
IRQ3
5
IRQ2
IRQ2
4
IRQ2
IRQ2
3
IRQ1
IRQ1
2
IRQ1
IRQ1
1
IRQ0
IRQ0
0
IRQ0
IRQ0
12
Figure 22. Program Memory Map
(ROMless Z86E40 Only)
EPROM Protect. When in ROM Protect Mode, and executing out of External Program Memory, instructions LDC,
LDCI, LDE, and LDEI cannot read Internal Program Memory.
DS97Z8X0502
When in ROM Protect Mode and executing out of Internal
Program Memory, instructions LDC, LDCI, LDE, and LDEI
can read Internal Program Memory.
PRELIMINARY
31
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
Data Memory (DM). In EPROM Mode, the Z86E40 can
address up to 60 KB of external data memory beginning at
location 4096. In ROMless mode, the Z86E40 can address
up to 64 KB of data memory. External data memory may
be included with, or separated from, the external program
memory space. DM, an optional I/O function that can be
programmed to appear on pin P34, is used to distinguish
between data and program memory space (Figure 23).
The state of the DM signal is controlled by the type of instruction being executed. An LDC opcode references
PROGRAM (DM inactive) memory, and an LDE instruction
references data (DM active Low) memory.
EPROM
ROMless
External
Data
Memory
External
Data
Memory
65535
4096
4095
Not Addressable
0
Figure 23. Data Memory Map
32
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Register File. The register file consists of three I/O port
registers, 236/125 general-purpose registers, 15 control
and status registers, and three system configuration registers in the expanded register group. The instructions can
access registers directly or indirectly through an 8-bit address field. This allows a short 4-bit register address using
the Register Pointer (Figure 24). In the 4-bit mode, the register file is divided into 16 working register groups, each
occupying 16 continuous locations. The Register Pointer
addresses the starting location of the active working-register group.
Note: Register Bank E0–EF can only be accessed through
working register and indirect addressing modes. (This
bank is available in Z86E30/E40 only.)
R253 RP
D7 D6 D5 D4 D3 D2 D1 D0
Expanded Register Group
Working Register Group
Default setting after RESET = 00000000
Figure 24. Register Pointer Register
Expanded Register File (ERF). The register file has been
expanded to allow for additional system control registers,
mapping of additional peripheral devices and input/output
ports into the register address area. The Z8 register address space R0 through R15 is implemented as 16 groups
of 16 registers per group (Figure 26). These register
groups are known as the Expanded Register File (ERF).
DS97Z8X0502
The low nibble (D3–D0) of the Register Pointer (RP) select
the active ERF group, and the high nibble (D7–D4) of register RP select the working register group. Three system
configuration registers reside in the Expanded Register
File at bank FH: PCON, SMR, and WDTMR. The rest of
the Expanded Register is not physically implemented and
is reserved for future expansion.
PRELIMINARY
33
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
r7 r6
r5 r4
r3 r2
r1 r0
R253
(Register Pointer)
The upper nibble of the register file address
provided by the register pointer specifies
the active working-register group.
FF
Register Group F
F0
EF
Note: Registers 80H
through EFH are
available in the Z86C30
only.
80
7F
70
6F
60
5F
50
4F
40
3F
30
2F
Specified Working
Register Group
The lower nibble
of the register
file address
provided by the
instruction points
to the specified
register.
20
1F
Register Group 1
R15 to R0
Register Group 0
R15 to R4*
10
0F
00
I/O Ports
R3 to R0*
* Expanded Register Group (0) is selected
in this figure by handling bits D3 to D0 as
"0" in Register R253 (RP).
Figure 25. Register Pointer
34
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Z8® STANDARD CONTROL REGISTERS
1
RESET CONDITION
D7 D6 D5 D4 D3 D2 D1 D0
REGISTER
REGISTER POINTER
7
6
5
4
3
2
Working Register
Group Pointer
1
% FF
SPL
0
0
0
0
0
0
0
0
% FE
SPH
0
0
0
0
0
0
0
0
% FD
RP
0
0
0
0
0
0
0
0
% FC
FLAGS
U
U
U
U
U
U
U
U
% FB
IMR
0
U
U
U
U
U
U
U
% FA
IRQ
0
0
0
0
0
0
0
0
% F9
IPR
U
U
U
U
U
U
U
U
†
% F8
P01M
0
1
0
0
1
1
0
1
*
% F7
P3M
0
0
0
0
0
0
0
0
*
% F6
P2M
1
1
1
1
1
1
1
1
% F5
PRE0
U
U
U
U
U
U
U
0
% F4
T0
U
U
U
U
U
U
U
U
% F3
PRE1
U
U
U
U
U
U
0
0
% F2
T1
U
U
U
U
U
U
U
U
% F1
TMR
0
0
0
0
0
0
0
0
% F0
Reserved
0
Expanded Register
Group Pointer
Z8 Reg. File
%FF
%FO
Z86E30/E40 Only
EXPANDED REG. GROUP (F)
REGISTER
*
Z86E30/E40 Only
%7F
*
**
Reserved
%0F
%00
Notes:
U = Unknown
† For Z86E40 (ROMless) reset condition: "10110110"
* Will not be reset with a STOP Mode Recovery
** Will not be reset with a STOP Mode Recovery, except Bit D0.
% (F) 0F
WDTMR
% (F) 0E
Reserved
% (F) 0D
SMR2
% (F) 0C
Reserved
% (F) 0B
SMR
% (F) 0A
Reserved
% (F) 09
Reserved
% (F) 08
Reserved
% (F) 07
Reserved
% (F) 06
Reserved
% (F) 05
Reserved
% (F) 04
Reserved
% (F) 03
Reserved
% (F) 02
Reserved
% (F) 01
Reserved
% (F) 00
PCON
EXPANDED REG. GROUP (0)
REGISTER
*
*
RESET CONDITION
U
U
U
0
1
1
0
1
U
U
U
U
U
U
0
0
0
0
1
0
0
0
0
0
1
1
1
1
1
1
1
0
RESET CONDITION
% (0) 03
P3
1
1
1
1
U
U
U
U
% (0) 02
P2
U
U
U
U
U
U
U
U
% (0) 01
P1
U
U
U
U
U
U
U
U
% (0) 00
P0
U
U
U
U
U
U
U
U
Figure 26. Expanded Register File Architecture
DS97Z8X0502
PRELIMINARY
35
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
General-Purpose Registers (GPR). These registers are
undefined after the device is powered up. The registers
keep their last value after any reset, as long as the reset
occurs in the VCC voltage-specified operating range. The
register R254 is general-purpose on Z86E30/E31. R254
and R255 are set to 00H after any reset or STOP-Mode
Recovery.
RAM Protect. The upper portion of the RAM's address
spaces 80H to EFH (excluding the control registers) can
be protected from reading and writing. This option can be
selected during the EPROM Programming Mode. After this
option is selected, the user can activate this feature from
the internal EPROM. D6 of the IMR control register (R251)
is used to turn off/on the RAM protect by loading a 0 or 1,
respectively. A “1” in D6 indicates RAM Protect enabled.
RAM Protect is not available on the Z86E31.
Stack. The Z86E40 external data memory or the internal
register file can be used for the stack. The 16-bit Stack
Pointer (R254–R255) is used for the external stack, which
can reside anywhere in the data memory for ROMless
mode, but only from 4096 to 65535 in ROM mode. An 8-bit
Stack Pointer (R255) is used for the internal stack on the
Z86E30/E31/E40 that resides within the 236 general-purpose registers (R4–R239). SPH (R254) can be used as a
general-purpose register when using internal stack only.
R254 and R255 are set to 00H after any reset or StopMode Recovery.
36
Counter/Timers. There are two 8-bit programmable
counter/timers (T0 and T1), each driven by its own 6-bit
programmable prescaler. The T1 prescaler is driven by internal or external clock sources; however, the T0 prescaler
is driven by the internal clock only (Figure 27).
The 6-bit prescalers can divide the input frequency of the
clock source by any integer number from 1 to 64. Each
prescaler drives its counter, which decrements the value
(1 to 256), that has been loaded into the counter. When the
counter reaches the end of count, a timer interrupt request,
IRQ4 (T0) or IRQ5 (T1), is generated.
The counters can be programmed to start, stop, restart to
continue, or restart from the initial value. The counters can
also be programmed to stop upon reaching zero (single
pass mode) or to automatically reload the initial value and
continue counting (modulo-n continuous mode).
The counters, but not the prescalers, can be read at any
time without disturbing their value or count mode. The
clock source for T1 is user-definable and can be either the
internal microprocessor clock divided by four, or an external signal input through Port 3. The Timer Mode register
configures the external timer input (P31) as an external
clock, a trigger input that can be retriggerable or non-retriggerable, or as a gate input for the internal clock. Port 3 line
P36 serves as a timer output (TOUT) through which T0, T1,
or the internal clock can be output. The counter/timers can
be cascaded by connecting the T0 output to the input of
T1.
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
OSC
1
Internal Data Bus
D1 (SMR)
Write
Write
Read
÷2
PRE0
Initial Value
Register
T0
Initial Value
Register
6-Bit
Down
Counter
8-bit
Down
Counter
T0
Current Value
Register
D0 (SMR)
÷ 16
÷4
Internal
Clock
IRQ4
÷2
TOUT
External Clock
P36
Clock
Logic
÷4
Internal Clock
Gated Clock
Triggered Clock
TIN P31
Write
6-Bit
Down
Counter
8-Bit
Down
Counter
PRE1
Initial Value
Register
T1
Initial Value
Register
Write
IRQ5
T1
Current Value
Register
Read
Internal Data Bus
Figure 27. Counter/Timer Block Diagram
DS97Z8X0502
PRELIMINARY
37
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
Interrupts. The MCU has six different interrupts from six
different sources. The interrupts are maskable and prioritized (Figure 28). The six sources are divided as follows:
four sources are claimed by Port 3 lines P33–P30) and two
in counter/timers. The Interrupt Mask Register globally or
individually enables or disables the six interrupt requests
(Table 10).
IRQ0 IRQ2
IRQ1, 3, 4, 5
Interrupt
Edge
Select
IRQ (D6, D7)
IRQ
IMR
6
IPR
Global
Interrupt
Enable
Interrupt
Request
Priority
Logic
Vector Select
Figure 28. Interrupt Block Diagram
Table 10. Interrupt Types, Sources, and Vectors
38
Name
Source
Vector Location
IRQ0
IRQ1
IRQ2
DAV0, IRQ0
IRQ1
DAV2, IRQ2, TIN
0, 1
2, 3
4, 5
IRQ3
IRQ4
IRQ5
IRQ3
T0
TI
6, 7
8, 9
10, 11
Comments
External (P32), Rising/Falling Edge Triggered
External (P33), Falling Edge Triggered
External (P31), Rising/Falling Edge Triggered
External (P30), Falling Edge Triggered
Internal
Internal
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
When more than one interrupt is pending, priorities are resolved by a programmable priority encoder that is controlled by the Interrupt Priority Register (IPR). An interrupt
machine cycle is activated when an interrupt request is
granted. Thus, disabling all subsequent interrupts, saves
the Program Counter and Status Flags, and then branches
to the program memory vector location reserved for that interrupt. All interrupts are vectored through locations in the
program memory. This memory location and the next byte
contain the 16-bit starting address of the interrupt service
routine for that particular interrupt request.
To accommodate polled interrupt systems, interrupt inputs
are masked and the interrupt request register is polled to
determine which of the interrupt requests need service.
An interrupt resulting from AN1 is mapped into IRQ2, and
an interrupt from AN2 is mapped into IRQ0. Interrupts
IRQ2 and IRQ0 may be rising, falling or both edge triggered, and are programmable by the user. The software
may poll to identify the state of the pin.
Programming bits for the Interrupt Edge Select are located
in bits D7 and D6 of the IRQ Register (R250). The
configuration is shown in Table 11.
XTAL1
C1
Table 11. IRQ Register Configuration
IRQ
D7
D6
P31
P32
0
0
1
1
0
1
0
1
F
F
R
R/F
F
R
F
R/F
Clock. The on-chip oscillator has a high-gain, parallel-resonant amplifier for connection to a crystal, RC, ceramic
resonator, or any suitable external clock source (XTAL1 =
Input, XTAL2 = Output). The crystal should be AT cut, 10
KHz to 16 MHz max, with a series resistance (RS) less
than or equal to 100 Ohms.
The crystal should be connected across XTAL1 and
XTAL2 using the vendor's recommended capacitor values
from each pin directly to device pin Ground. The RC oscillator option can be selected in the programming mode.
The RC oscillator configuration must be an external resistor connected from XTAL1 to XTAL2, with a frequency-setting capacitor from XTAL1 to Ground (Figure 29).
XTAL1
XTAL1
XTAL1
XTAL2
XTAL2
C1
L
XTAL2
Ceramic Resonator or
Crystal
C1, C2 = 47 pF TYP *
F = 8 MHz
1
Notes:
F = Falling Edge
R = Rising Edge
C1
C2
Interrupt Edge
R
XTAL2
C2
LC
C1, C2 = 22 pF
RC
@ 5V Vcc (TYP)
L = 130 µH *
F = 3 MHz *
C1 = 100 pF
R = 2K
F = 6 MHz
External Clock
* Typical value including pin parasitics
Figure 29. Oscillator Configuration
DS97Z8X0502
PRELIMINARY
39
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
Power-On Reset (POR). A timer circuit clocked by a dedicated on-board RC oscillator is used for the Power-On Reset (POR) timer function. The POR timer allows VCC and
the oscillator circuit to stabilize before instruction execution begins.
The POR timer circuit is a one-shot timer triggered by one
of three conditions:
In order to enter STOP or HALT Mode, it is necessary to
first flush the instruction pipeline to avoid suspending execution in mid-instruction. To do this, the user must execute
a NOP (Opcode=FFH) immediately before the appropriate
sleep instruction, that is:
FF
6F
1. Power fail to Power OK status
FF
7F
2. Stop-Mode Recovery (if D5 of SMR=0)
3. WDT time-out
The POR time is a nominal 5 ms. Bit 5 of the STOP mode
Register (SMR) determines whether the POR timer is bypassed after STOP-Mode Recovery (typical for an external
clock and RC/LC oscillators with fast start up times).
HALT. Turns off the internal CPU clock, but not the XTAL
oscillation. The counter/timers and external interrupt IRQ0,
IRQ1, and IRQ2 remain active. The device is recovered by
interrupts, either externally or internally generated. An interrupt request must be executed (enabled) to exit HALT
Mode. After the interrupt service routine, the program continues from the instruction after the HALT.
NOP
STOP
or
NOP
HALT
; clear the pipeline
; enter STOP Mode
; clear the pipeline
; enter HALT Mode
STOP. This instruction turns off the internal clock and external crystal oscillation and reduces the standby current
to 10 microamperes or less. STOP Mode is terminated by
one of the following resets: either by WDT time-out, POR,
a Stop-Mode Recovery Source, which is defined by the
SMR register or external reset. This causes the processor
to restart the application program at address 000CH.
Port Configuration Register (PCON). The PCON register configures the ports individually; comparator output on
Port 3, open-drain on Port 0 and Port 1, low EMI on Ports
0, 1, 2 and 3, and low EMI oscillator. The PCON register is
located in the expanded register file at Bank F, location 00
(Figure 30).
PCON (FH) 00H
D7
D6 D5
D4 D3
D2 D1 D0
Comparator Output Port 3
0 P34, P37 Standard Output*
1 P34, P37 Comparator Output
0 Port 1 Open Drain
1 Port 1 Push-pull Active*
0 Port 0 Open Drain
1 Port 0 Push-pull Active*
0 Port 0 Low EMI
1 Port 0 Standard*
0 Port 1 Low EMI
1 Port 1 Standard*
0 Port 2 Low EMI
1 Port 2 Standard*
0 Port 3 Low EMI
1 Port 3 Standard*
* Default Setting After Reset
Low EMI Oscillator
0 Low EMI
1 Standard*
Figure 30. Port Configuration Register (PCON)
(Write Only)
40
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Comparator Output Port 3 (D0). Bit 0 controls the comparator output in Port 3. A “1” in this location brings the
comparator outputs to P34 and P37, and a “0” releases the
Port to its standard I/O configuration. The default value
is 0.
Port 1 Open-Drain (D1). Port 1 can be configured as an
open-drain by resetting this bit (D1=0) or configured as
push-pull active by setting this bit (D1=1). The default value is 1.
Port 0 Open-Drain (D2). Port 0 can be configured as an
open-drain by resetting this bit (D2=0) or configured as
push-pull active by setting this bit (D2=1). The default value is 1.
Low EMI Port 0 (D3). Port 0 can be configured as a Low
EMI Port by resetting this bit (D3=0) or configured as a
Standard Port by setting this bit (D3=1). The default value
is 1.
Low EMI Port 1 (D4). Port 1 can be configured as a Low
EMI Port by resetting this bit (D4=0) or configured as a
Standard Port by setting this bit (D4=1). The default value
is 1. Note: The emulator does not support Port 1 low EMI
mode and must be set D4 = 1.
Low EMI Port 3 (D6). Port 3 can be configured as a Low
EMI Port by resetting this bit (D6=0) or configured as a
Standard Port by setting this bit (D6=1). The default value
is 1.
Low EMI OSC (D7). This bit of the PCON Register controls the low EMI noise oscillator. A “1” in this location configures the oscillator with standard drive. While a “0” configures the oscillator with low noise drive, however, it does
not affect the relationship of SCLK and XTAL. The low EMI
mode will reduce the drive of the oscillator (OSC). The default value is 1. Note: 4 MHz is the maximum external
clock frequency when running in the low EMI oscillator
mode.
Stop-Mode Recovery Register (SMR). This register
selects the clock divide value and determines the mode of
Stop-Mode Recovery (Figure 31). All bits are Write Only
except bit 7 which is a Read Only. Bit 7 is a flag bit that is
hardware set on the condition of STOP Recovery and
reset by a power-on cycle. Bit 6 controls whether a low or
high level is required from the recovery source. Bit 5
controls the reset delay after recovery. Bits 2, 3, and 4 of
the SMR register specify the Stop-Mode Recovery Source.
The SMR is located in Bank F of the Expanded Register
Group at address 0BH.
Low EMI Port 2 (D5). Port 2 can be configured as a Low
EMI Port by resetting this bit (D5=0) or configured as a
Standard Port by setting this bit (D5=1). The default value
is 1.
DS97Z8X0502
PRELIMINARY
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1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
SMR (F) 0B
D7 D6 D5 D4 D3 D2 D1 D0
SCLK/TCLK Divide by 16
0 OFF **
1 ON
External Clock Divide by 2
0 SCLK/TCLK =XTAL/2*
1 SCLK/TCLK =XTAL
Stop Mode Recovery Source
000 POR and/or External Reset *
001 P30
010 P31
011 P32
100 P33
101 P27
110 P2 NOR 0:3
111 P2 NOR 0:7
Stop Delay
0 OFF
1 ON*
Stop Recovery Level
0 Low *
1 High
Stop Flag
0 POR*
1 Stop Recovery
* Default setting after RESET.
** Default setting after RESET and STOP-Mode Recovery.
Figure 31. STOP-Mode Recovery Register
(Write-Only Except Bit D7, Which is Read-Only)
42
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
SCLK/TCLK Divide-by-16 Select (D0). This bit of the
SMR controls a divide-by-16 prescaler of SCLK/TCLK.
The purpose of this control is to selectively reduce device
power consumption during normal processor execution
(SCLK control) and/or HALT mode (where TCLK sources
counter/timers and interrupt logic).
External Clock Divide-by-Two (D1). This bit can eliminate the oscillator divide-by-two circuitry. When this bit is
0, the System Clock (SCLK) and Timer Clock (TCLK) are
equal to the external clock frequency divided by two. The
SCLK/TCLK is equal to the external clock frequency when
this bit is set (D1=1). Using this bit together with D7 of
PCON further helps lower EMI (i.e., D7 (PCON) = 0, D1
(SMR) = 1). The default setting is zero.
STOP-Mode Recovery Source (D2, D3, and D4). These
three bits of the SMR register specify the wake up source
of the STOP-Mode Recovery (Figure 32). Table 12 shows
the SMR source selected with the setting of D2 to D4.
P33–P31 cannot be used to wake up from STOP mode
when programmed as analog inputs. When the STOPMode Recovery sources are selected in this register then
SMR2 register bits D0, D1 must be set to zero.
Note: If the Port2 pin is configured as an output, this output
level will be read by the SMR circuitry.
SMR2 D1 D0
0 0
SMR2 D1 D0
0 1
VDD
P20
P20
P23
P27
SMR2 D1 D0
1 0
SMR D4 D3 D2
0 0 0
VDD
P30
P31
P32
SMR D4
0
0
0
D3
0
1
1
D2 SMR D4 D3 D2
1
1 0 0
0
1
P33
SMR D4 D3 D2
1 0 1
SMR D4 D3 D2
1 1 0
P20
P20
P23
P27
SMR D4 D3 D2
1 1 1
P27
To POR
RESET
Stop-Mode Recovery Edge
Select (SMR)
To P33 Data
Latch and IRQ1
MUX
P33 From Pads
Digital/Analog Mode
Select (P3M)
Figure 32. Stop-Mode Recovery Source
DS97Z8X0502
PRELIMINARY
43
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
Table 12. Stop-Mode Recovery Source
D4
D3
D2
SMR Source selection
0
0
0
0
0
1
0
1
0
0
1
1
1
0
0
1
1
1
0
1
1
1
0
1
POR recovery only
P30 transition
P31 transition (Not in analog
mode)
P32 transition (Not in analog
mode)
P33 transition (Not in analog
mode)
P27 transition
Logical NOR of Port 2 bits 0–3
Logical NOR of Port 2 bits 0–7
Stop-Mode Recovery Delay Select (D5). The 5 ms RESET delay after Stop-Mode Recovery is disabled by programming this bit to a zero. A “1” in this bit will cause a 5
ms RESET delay after Stop-Mode Recovery. The default
condition of this bit is 1. If the fast wake up mode is selected, the Stop-Mode Recovery source needs to be kept active for at least 5TpC.
Stop-Mode Recovery Level Select (D6). A “1” in this bit
defines that a high level on any one of the recovery sources wakes the MCU from STOP Mode. A 0 defines low level
recovery. The default value is 0.
Cold or Warm Start (D7). This bit is set by the device
upon entering STOP Mode. A “0” in this bit indicates that
the device has been reset by POR (cold). A “1” in this bit
indicates the device was awakened by a SMR source
(warm).
Stop-Mode Recovery Register 2 (SMR2). This register
contains additional Stop-Mode Recovery sources. When
the Stop-Mode Recovery sources are selected in this register then SMR Register. Bits D2, D3, and D4 must be 0.
SMR:10
Operation
D1
D0
Description of Action
0
0
1
0
1
0
POR and/or external reset recovery
Logical AND of P20 through P23
Logical AND of P20 through P27
Watch-Dog Timer Mode Register (WDTMR). The WDT
is a retriggerable one-shot timer that resets the Z8 if it
reaches its terminal count. The WDT is disabled after Power-On Reset and initially enabled by executing the WDT instruction and refreshed on subsequent executions of the
WDT instruction. The WDT is driven either by an on-board
RC oscillator or an external oscillator from XTAL1 pin. The
44
POR clock source is selected with bit 4 of the WDT register.
Note: Execution of the WDT instruction affects the Z (Zero), S (Sign), and V (Overflow) flags.
WDT Time-Out Period (D0 and D1). Bits 0 and 1 control
a tap circuit that determines the time-out periods that can
be obtained (Table 13). The default value of D0 and D1
are 1 and 0, respectively.
Table 13. Time-out Period of WDT
D1
D0
0
0
1
1
0
1
0
1
Time-out of Time-out of
the Internal the System
RC OSC
Clock
5 ms
10 ms*
20 ms
80 ms
128 SCLK
256 SCLK*
512 SCLK
2048 SCLK
Notes:
*The default setting is 10 ms.
WDT During HALT Mode (D2). This bit determines
whether or not the WDT is active during HALT Mode. A “1”
indicates that the WDT is active during HALT. A “0” disables the WDT in HALT Mode. The default value is “1”.
WDT During STOP Mode (D3). This bit determines
whether or not the WDT is active during STOP mode. A “1”
indicates active during STOP. A “0” disables the WDT during STOP Mode. This is applicable only when the WDT
clock source is the internal RC oscillator.
Clock Source For WDT (D4). This bit determines which
oscillator source is used to clock the internal POR and
WDT counter chain. If the bit is a 1, the internal RC oscillator is bypassed and the POR and WDT clock source is
driven from the external pin, XTAL1, and the WDT is
stopped in STOP Mode. The default configuration of this
bit is 0, which selects the RC oscillator.
Permanent WDT. When this feature is enabled, the WDT
is enabled after reset and will operate in Run and Halt
Mode. The control bits in the WDTMR do not affect the
WDT operation. If the clock source of the WDT is the internal RC oscillator, then the WDT will run in STOP mode. If
the clock source of the WDT is the XTAL1 pin, then the
WDT will not run in STOP mode.
Note: WDT time-out in STOP Mode will not reset
SMR,SMR2,PCON, WDTMR, P2M, P3M, Ports 2 & 3 Data
Registers.
WDTMR Register Accessibility. The WDTMR register is
accessible only during the first 60 internal system clock
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
cycles from the execution of the first instruction after
Power-On Reset, Watch-Dog reset or a STOP-Mode
Recovery (Figures 33 and 34). After this point, the register
cannot be modified by any means, intentional or
otherwise. The WDTMR cannot be read and is located in
Bank F of the Expanded Register Group at address
location 0FH.
WDTMR (F) 0F
D7 D6 D5 D4 D3 D2 D1 D0
WDT TAP
00
01 *
10
11
INT RC OSC System Clock
5 ms
128 SCLK
10 ms
256 SCLK
20 ms
512 SCLK
80 ms
2048 SCLK
WDT During HALT
0 OFF
1 ON *
WDT During STOP
0 OFF
1 ON *
XTAL1/INT RC Select for WDT
0 On-Board RC *
1 XTAL
Reserved (Must be 0)
* Default setting after RESET
Figure 33. Watch-Dog Timer Mode Register
Write Only
DS97Z8X0502
PRELIMINARY
45
1
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
Reset
4 Clock
Filter
Clear
CLK
18 Clock RESET
Generator
RESET
Internal
RESET
WDT Select
(WDTMR)
WDT TAP SELECT
CLK Source
Select
(WDTMR)
XTAL
M
U
X
Internal
RC OSC.
VDD
+
VLV
-
5ms POR
5ms 15ms 25ms 100ms
CK
WDT/POR Counter Chain
CLR
2V Operating
Voltage Det.
WDT
From Stop
Mode
Recovery
Source
Stop Delay
Select (SMR)
Figure 34. Resets and WDT
46
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Auto Reset Voltage. An on-board Voltage Comparator
checks that VCC is at the required level to ensure correct
operation of the device. Reset is globally driven if VCC is
below VLV (Figure 35).
VCC
(Volts)
Note: VCC must be in the allowed operating range prior to
the minimum Power-On Reset time-out (TPOR).
1
3.7
3.5
3.3
3.1
2.9
2.7
2.5
2.3
-60
-40
-20
0
20
40
60
80
100
120
140
Temperature
(°C)
Figure 35. Typical Z86E40 VLV Voltage vs. Temperature
DS97Z8X0502
PRELIMINARY
47
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
EPROM MODE
Table 14 shows the programming voltages of each programming mode. Table 15, and figures that follow show
the programming timing of each programming mode. Figure 38 shows the circuit diagram of a Z86E40 programming adapter, which adapts from 2764A to Z86E40 and
Figure 39 shows the Z86E30/E31 Programming Adapter
Circuitry. Figure 40 shows the flowchart of an Intelligent
Programming Algorithm, which is compatible with 2764A
EPROM (Z86E40 is 4K EPROM, 2764A is 8K EPROM).
Since the EPROM size of Z86E30/E31/E40 differs from
2764A, the programming address range has to be set from
0000H to 0FFFH for the Z86E30/E40 and 0000H to 07FFH
for Z86E31. Otherwise, the upper portion of EPROM data
will overwrite the lower portion of EPROM data. Figure 39
shows the adaptation from the 2764A to Z86E30/E31.
EPROM R/W mode allows the programming of the user
mode program ROM.
Option Bit R/W allows the programming of the Z8 option
bits. When the device is latched into Option Bit R/W mode,
the address must then be changed to 63 decimals
(000000111111 Binary). The Options are mapped into this
address as follows:
Bit
7
6
5
4
3
2
1
0
Note: EPROM Protect feature allows the LDC, LDCI, LDE,
and LDEI instructions from internal program memory. A
ROM lookup table can be used with this feature.
During programming, the VPP input pin supplies the programming voltage and current to the EPROM. This pin is
also used to latch which EPROM mode is to be used (R/W
EPROM or R/W Option bits). The mode is set by placing
the correct mode number on the least significant bits of the
address and raising the EPM pin above V. After a setup
time, the VPP pin can then be raised or lowered. The
latched EPROM mode will remain until the EPM pin is reduced below VH.
Mode Name
EPROM R/W
Option Bit R/W
48
Mode #
LSB Addr
0
3
0000
0011
Option
Unused
Unused
32 KHz XTAL Option
Permanent WDT
Auto Latch Disable
RC Oscillator Option
RAM Protect
ROM Protect
Table 14 gives the proper conditions for EPROM R/W operations, once the mode is latched.
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Table 14. EPROM Programming Table
Programming
Modes
VPP
EPM
CE
OE
PGM
ADDR
DATA
VCC*
EPROM READ1
X
VH
VIL
VIL
VIH
ADDR
Out
4.5V†
EPROM READ2
X
VH
VIL
VIL
VIH
ADDR
Out
5.5V†
PROGRAM
VPP
VH
VIL
VIH
VIL
ADDR
In
6.4V
PROGRAM
VERIFY
OPTION BIT PGM
VPP
VH
VIL
VIL
VIH
ADDR
Out
6.0V
VPP
VH
VIL
VIH
VIL
63
IN
6.4V
OPTION BIT READ
X
VH
VIL
VIL
VIH
63
OUT
6.0V
1
Notes:
VH = 13.0 V ± 0.1 V
VIH = As per specific Z8 DC specification
VIL= As per specific Z8 DC specification
X=Not used, but must be set to VH, VIH, or VIL level.
NU = Not used, but must be set to either VIH or VIL level.
IPP during programming = 40 mA maximum.
ICC during programming, verify, or read = 40 mA maximum.
*VCC has a tolerance of ±0.25V.
† Zilog recommends an EPROM read at VCC = 4.5 V and 5.5 V to
ensure proper device operations during the VCC after programming,
but VCC = 5.0 V is acceptable.
Table 15. EPROM Programming Timing
Parameters
Name
Min
Max
Units
1
2
3
Address Setup Time
Data Setup Time
VPP Setup
2
2
2
µs
µs
µs
4
VCC Setup Time
2
µs
5
6
7
8
9
10
11
Chip Enable Setup Time
Program Pulse Width
Data Hold Time
OE Setup Time
Data Access Time
Data Output Float Time
Overprogram Pulse
Width/Option Program
Pulse Width
EPM Setup Time
PGM Setup Time
Address to OE Setup Time
OE Width
Address to OE Low
2
0.95
2
2
200
2.85
µs
ms
µs
µs
ns
ns
ms
2
2
2
250
125
µs
µs
µs
ns
ns
12
13
14
15
16
DS97Z8X0502
1.05
100
PRELIMINARY
49
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
FUNCTIONAL DESCRIPTION (Continued)
VIH
Address
Address Stable
VIL
16
VIH
Data
VIL
Address Stable
Invalid
Valid
Invalid
Valid
9
VH
VPP
VIL
VH
EPM
VIL
5.5V
12
VCC
4.5V
VIH
CE
VIL
OE
VIL
15
VIH
PGM
15
5
VIH
15
VIL
3
Figure 36. EPROM Read Mode Timing Diagram
50
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Z86E40 TIMING DIAGRAMS
1
VIH
Address
Address Stable
VIL
1
VIH
Data
Data Stable
VIL
Data Out Valid
2
9
10
VH
VPP
VIH
3
VH
EPM
VIL
6V
VCC
4.5V
VIH
4
7
CE
VIL
5
VIH
OE
VIL
VIH
PGM
VIL
6
8
15
11
Program Cycle
Verify Cycle
Figure 37. Timing Diagram of EPROM Program and Verify Modes
DS97Z8X0502
PRELIMINARY
51
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Z86E40 TIMING DIAGRAMS (Continued)
U2
U1
D4
39
D5
2
D6
3
D7
4
A0
26
A1
27
A2
30
A3
34
A4
5
A5
6
A6
A7
7
10
1
20
40
GND
21
9
P12 32
33
P13
8
P14
9
P15
12
P16
13
P17
A2
8
A3
7
A4
6
A5
5
A6
4
A7
3
P22
P23
P24
P25
P26
P27
P00
P30
P01
P31
P02
P32
A9
A10
21
17 EPM
A11
23
18 VPP
P03
P33
P04
P34
19 A8
P05
P35
22 A9
P06
P36
24 A10
P07
P37
2
27
1 KOhm 1
1 KOhm 1
23 A11
R2
R1
2
20
2
22
DS
XTAL1
RESET
XTAL2
A4
A5
A6
A7
D5
D6
D7
A9
A10
A11
A12
GND
14
GND
CS
VCC
28
VCC
OE
VPP
1
PGM
VPP
0.01µF
14
GND
12.5V
D1 1
X3
D3 3
0.1µF
C2
2
1
X1
EPM
4
D4
15 CE
U3
12.5V 16
D3
2764 Pins
Z86E40
40-Pin DIP
Socket
GND
A3
11 VCC
AS
D2
03 15
16
04
17
05
18
06
07 19
02
31 GND
R/W
13
A2
25 A8
16 OE
D1
01
A8
24
25 PGM
12
A1
2
38
A1
P11
D0
00
C1
37
D3
29
P21
11
A0
1
D2
10
1
R4
2
1 KOhm
1
R3
2
10 KOhm
1
36
A0
P10
D1
D1
28
P20
2
35
1N5243
D0
GND
GND
12.5 Volt
2
1
P1
VCC 15 IX1
1
5.0V
S4
D4 6
X
1 KOhm
1
5
X
X
D2
D2 3
2
2
S2
1N5231
4
X
R5
GND
10
X
IX2
VCC
5.0 V
IH5043
Figure 38. Z86E40 Z8 OTP Programming Adapter
For use with Standard EPROM Programmers
52
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
1
U2
U1
D0
24
D1
25
D2
26
D3
27
D4
28
D5
1
D6
2
D7
3
A0
19
A1
20
A2
21
A3
23
A4
4
A5
5
A6
6
A7
7
P20
P21
P22
P23
P24
P25
P26
P27
A0
10
A1
9
A2
8
A3
7
A4
6
A5
5
A6
4
A7
3
A4
25
P00
P30
18
PGM
A5
24
P01
P31
11
OE
A6
21
12
EPM
A7
23
13
VPP
P02
P32
P03
P33
P04
P34
14
A8
P05
P35
15
A9
P06
P36
P07
P37
A10
17
16
A11
1 KOhm 1
R1
2
20
2
22
12
D1
13
D2
03 15
16
04
17
05
18
06
19
07
D3
GND 14
GND
CS
VCC 28
VCC
OE
VPP
A1
01
02
A3
A4
A5
A6
A7
D4
D5
D6
D7
A8
A9
A10
A11
A12
27
R2
D0
00
A2
2
1 KOhm 1
11
A0
PGM
VPP
1
GND
D1 1
R4
2
1 KOhm
1
4
GND
GND
12.5 Volt
2
1
P1
D3 3
X3
2
10 KOhm
EPM
GND
R3
1
1
D1
0.1µF
C2
2
1
12.5V
U3
X1
C1
1
9
Z86E30/31
28-Pin DIP
Socket
12.5V 16
1
5.0V
15 IX1
D2 3
5
X
S4
D4 6
10
X
IX2
VCC
IH5043
X
2
1
1 KOhm
D2
S2
R5
2
4
X
1N5231
VCC
0.01µF
2
XTAL2
CE
10
1N5243
XTAL1
2
2764 Pins
GND
X
5.0 V
Note: The programming address must be set to
0000H - 0FFFH (Lower 4K Byte Memory). For Z86E30
0000H - 07FFH (Lower 2K Byte Memory). For Z86E31
Figure 39. Z86E30/E31 Programming Adapter Circuitry
DS97Z8X0502
PRELIMINARY
53
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Start
1
Addr =
First Location
Vcc = 6.0V
Vpp = 12.5V
N=0
Program
1 ms Pulse
Increment N
Yes
N = 25 ?
No
Fail
Fail
Verify
One Byte
Verify Byte
Pass
Pass
Prog. One Pulse
3xN ms Duration
Increment
Address
No
Last Addr ?
Yes
Vcc = Vpp = 4.5V *
Note:
* To ensure proper operaton,
Zilog recommends Vcc range
of the device Vcc specification,
But Vcc = 5.0V is acceptable.
Verify All
Bytes
Fail
Pass
Device Failed
Vcc = Vpp = 5.5V *
Verify All
Bytes
Pass
Fail
Device Passed
Figure 40. Z86E40 Programming Algorithm
DS97Z8X0502
PRELIMINARY
55
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
EXPANDED REGISTER FILE CONTROL REGISTERS
PCON (FH) 00H
WDTMR (F) 0F
D7 D6 D5 D4 D3 D2 D1 D0
D7 D6 D5 D4 D3 D2 D1 D0
WDT TAP
00
01 *
10
11
Comparator Output Port 3
0 P34, P37 Standard*
1 P34, P37 Comparator Output
0 Port 1 Open-Drain
1 Port 1 Push-Pull Active*†
WDT During HALT
0 OFF
1 ON *
0 Port 0 Open-Drain
1 Port 0 Push-pull Active*
WDT During STOP
0 OFF
1 ON *
0 Port 0 Low EMI
1 Port 0 Standard*
0 Port 1 Low EMI
1 Port 1 Standard*†
XTAL1/INT RC Select for WDT
0 On-Board RC *
1 XTAL
0 Port 2 Low EMI
1 Port 2 Standard*
0 Port 3 Low EMI
1 Port 3 Standard*
* Default Setting After Reset
† Must Be 1 for Z86E30/E31
Low EMI Oscillator
0 Low EMI
1 Standard*
INT RC OSC System Clock
5 ms
128 SCLK
10 ms
256 SCLK
20 ms
512 SCLK
80 ms
2048 SCLK
Reserved (Must be 0)
* Default setting after RESET
Figure 43. Watch-Dog Timer Mode Register
Write Only
Figure 41. Port Configuration Register
Write Only
SMR2 (0F) DH
D7 D6 D5 D4 D3 D2 D1 D0
SMR (FH) 0B
Stop-Mode Recovery Source 2
00 POR only*
01 AND P20,P21,P22,P23
10 AND P20,P21,P22,P23,P24,
P25,P26,P27
D7 D6 D5 D4 D3 D2 D1 D0
SCLK/TCLK Divide-by-16
0 OFF **
1 ON
Reserved (Must be 0)
Note: Not used in conjunction with SMR Source
External Clock Divide by 2
0 SCLK/TCLK =XTAL/2*
1 SCLK/TCLK =XTAL
Stop Mode Recovery Source
000 POR Only and/or External Reset*
001 P30
010 P31
011 P32
100 P33
101 P27
110 P2 NOR 0-3
111 P2 NOR 0-7
Stop Delay
0 OFF
1 ON*
Stop Recovery Level
0 Low*
1 High
Figure 44. STOP-Mode Recovery Register 2
Write Only
Stop Flag
0 POR*
1 Stop Recovery
* Default setting after RESET.
** Default setting after RESET and STOP-Mode Recovery.
Figure 42. STOP-Mode Recovery Register
Write Only Except Bit D7, Which is Read Only
56
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Z8 CONTROL REGISTER DIAGRAMS
R240
1
R243 PRE1
D7 D6 D5 D4 D3 D2 D1
D0
D7 D6
D5 D4 D3 D2 D1 D0
Reserved (Must be 0)
Count Mode
0 T1 Single Pass*
1 T1 Modulo N
Clock Source
1 T1 Internal
0 T1 External Timing Input
(TIN Mode)
Figure 45. Reserved
Prescaler Modulo
(Range: 1-64 Decimal
01-00 HEX)
R241 TMR
D7 D6 D5 D4 D3 D2 D1 D0
*Default After Reset
0 No Function*
1 Load T0
Figure 48. Prescaler 1 Register
F3H: Write Only
0 Disable T0 Count*
1 Enable T0 Count
0 No Function*
1 Load T1
0 Disable T1 Count*
1 Enable T1 Count
R244 T0
D7 D6 D5 D4 D3 D2 D1 D0
TIN Modes
00 External Clock Input*
01 Gate Input
10 Trigger Input
(Non-retriggerable)
11 Trigger Input
(Retriggerable)
T0 Initial Value
(When Written)
(Range: 1-256 Decimal
01-00 HEX)
T0 Current Value
(When Read)
TOUT Modes
00 Not Used*
01 T0 Out
10 T1 Out
11 Internal Clock Out
Figure 49. Counter/Timer 0 Register
F4H; Read/Write
Default After Reset = 00H
R245 PRE0
Figure 46. Timer Mode Register
F1H: Read/Write
D7 D6 D5 D4 D3 D2 D1 D0
Count Mode
0 T1 Single Pass
1 T1 Modulo N
R242 T1
D7 D6 D5 D4 D3 D2 D1 D0
Reserved (Must be 0)
T1 Initial Value
(When Written)
(Range: 1-256 Decimal
01-00 HEX)
T1 Current Value
(When Read)
Prescaler Modulo
(Range: 1-64 Decimal
01-00 HEX)
Figure 50. Prescaler 0 Register
F5H: Write Only
Figure 47. Counter/Timer 1 Register
F2H: Read/Write
DS97Z8X0502
PRELIMINARY
57
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Z8 CONTROL REGISTER DIAGRAMS (Continued)
R248 P01M
R246 P2M
D7 D6 D5 D4 D3 D2 D1 D0
D7 D6 D5 D4 D3 D2 D1 D0
* Default After Reset
P03 – P00 Mode
00 Output
01 Input
1X A11–A8
P20 - P27 I/O Definition
0 Defines Bit as Output
1 Defines Bit as Input*
Stack Selection
0 External
1 Internal
P17 – P10 Mode
00 Byte Output†
01 Byte Input
10 AD7–AD0
11 High-Impedance AD7–AD0,
AS, DS, R/W, A11–A8,
A15–A12, If Selected
Figure 51. Port 2 Mode Register
F6H: Write Only
R247 P3M
External Memory Timing
0 Normal
1 Extended
D7 D6 D5 D4 D3 D2 D1 D0
0 Port 2 Open-Drain
1 Port 2 Push-pull Active
P07 – P04 Mode
00 Output
01 Input
1X A15 - A12
0 P31, P32 Digital Mode
1 P31, P32 Analog Mode
Reset Condition = 0100 1101B
For ROMless Condition = 1011 0110B
† Z86E30/E31 Must be 00
0 P32 = Input
P35 = Output
1 P32 = DAV0/RDY0
P35 = RDY0/DAV0
00
01
10
11
P33 = Input
P34 = Output
P33 = Input
P34 = DM
P33 = DAV1/RDY1
P34 = RDY1/DAV1
0 P31 = Input (TIN)
P36 = Output (TOUT)
1 P31 = DAV2/RDY2
P36 = RDY2/DAV2
†
Figure 53. Port 0 and 1 Mode Register
F8H: Write Only
Z86E30/E31 Only
R249 IPR
D7 D6 D5 D4
0 P30 = Input
P37 = Output
Reserved (Must be 0)
Default After Reset = 00H
† Z86E30/E31 Must Be 00
Figure 52. Port 3 Mode Register
F7H: Write Only
D3 D2 D1 D0
Interrupt Group Priority
000 Reserved
001 C > A > B
010 A > B > C
011 A > C > B
100 B > C > A
101 C > B > A
110 B > A > C
111 Reserved
IRQ1, IRQ4 Priority (Group C)
0 IRQ1 > IRQ4
1 IRQ4 > IRQ1
IRQ0, IRQ2 Priority (Group B)
0 IRQ2 > IRQ0
1 IRQ0 > IRQ2
IRQ3, IRQ5 Priority (Group A)
0 IRQ5 > IRQ3
1 IRQ3 > IRQ5
Reserved (Must be 0)
Figure 54. Interrupt Priority Register
F9H: Write Only
58
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
R253 RP
R250 IRQ
D7 D6
D5 D4 D3 D2
IRQ0 = P32 Input
IRQ1 = P33 Input
IRQ2 = P31 Input
IRQ3 = P30 Input
IRQ4 = T0
IRQ5 = T1
Default After Reset = 00H
1
D7 D6 D5 D4 D3 D2 D1 D0
D1 D0
Expanded Register File
Working Register Pointer
Default After Reset = 00H
Inter Edge
P31 ↓ P32 ↓ = 00
P31 ↓ P32 ↑ = 01
P31 ↑ P32 ↓ = 10
P31 ↑↓ P32 ↑↓ = 11
Figure 58. Register Pointer
FDH: Read/Write
R254 SPH
Figure 55. Interrupt Request Register
FAH: Read/Write
D7 D6 D5 D4 D3 D2 D1 D0
(Z86E40)
Stack Pointer Upper
Byte (SP8 - SP15)
R251 IMR
(Z86E30/E31)
0 = 0 State
1 = 1 State
D7 D6 D5 D4 D3 D2 D1 D0
1 Enables IRQ5-IRQ0
(D0 = IRQ0)
Figure 59. Stack Pointer High
FEH: Read/Write
1 Enables RAM Protect †
1 Enables Interrupts
† This option must be selected when ROM code is
submitted for ROM Masking, otherwise this control bit
is disabled permanently.
R255 SPL
D7 D6 D5 D4 D3 D2 D1 D0
Figure 56. Interrupt Mask Register
FBH: Read/Write
Stack Pointer Lower
Byte (SP0 - SP7)
R252 FLAGS
Figure 60. Stack Pointer Low
FFH: Read/Write
D7 D6 D5 D4 D3 D2 D1 D0
User Flag F1
User Flag F2
Half Carry Flag
Decimal Adjust Flag
Overflow Flag
Sign Flag
Zero Flag
Carry Flag
Figure 57. Flag Register
FCH: Read/Write
DS97Z8X0502
PRELIMINARY
59
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
PACKAGE INFORMATION (Continued)
PACKAGE INFORMATION
Figure 61. 40-Pin DIP Package Diagram
60
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
1
Figure 62. 44-Pin PLCC Package Diagram
Figure 63. 44-Pin QFP Package Diagram
DS97Z8X0502
PRELIMINARY
61
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
Figure 64. 28-Pin DIP Package Diagram
Figure 65. 28-Pin SOIC Package Diagram
62
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
1
Figure 66. 28-Pin PLCC Package Diagram
DS97Z8X0502
PRELIMINARY
63
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
ORDERING INFORMATION
Z86E40 (16 MHz)
40-Pin DIP
44-Pin PLCC
44-Pin QFP
Z86E4016PSC
Z86E4016PEC
Z86E4016VSC
Z86E4016VEC
Z86E4016FSC
Z86E4016FEC
28-Pin DIP
28-Pin SOIC
28-Pin PLCC
Z86E3016PSC
Z96E3016PEC
Z86E3016SSC
Z86E3016SEC
Z86E3016VSC
Z86E3016VEC
28-Pin DIP
28-Pin SOIC
28-Pin PLCC
Z86E3116PSC
Z86E3116PEC
Z86E3116SSC
Z86E3116SEC
Z86E3116VSC
Z86E3116VEC
Z86E30 (16 MHz)
Z86E31 (16 MHz)
For fast results, contact your local Zilog sales office for assistance in ordering the part desired.
Package
Temperature
P = Plastic DIP
S = 0 °C to +70 °C
E = -40 °C to +105 °C
V = Plastic Leaded Chip Carrier
Speed
F = Plastic Quad Flat Pack
16 = 16 MHz
S = SOIC (Small Outline Integrated Circuit)
Environmental
C= Plastic Standard
E = Hermetic Standard
Example:
Z 86E40 16 P S C
is a Z86E40, 16 MHz, DIP, 0°C to +70°C, Plastic Standard Flow
Environmental Flow
Temperature
Package
Speed
Product Number
Zilog Prefix
64
PRELIMINARY
DS97Z8X0502
Z86E30/E31/E40
Z8 4K OTP Microcontroller
Zilog
© 1998 by Zilog, Inc. All rights reserved. No part of this
document may be copied or reproduced in any form or by
any means without the prior written consent of Zilog, Inc.
The information in this document is subject to change
without notice. Devices sold by Zilog, Inc. are covered by
warranty and patent indemnification provisions appearing
in Zilog, Inc. Terms and Conditions of Sale only.
ZILOG, INC. MAKES NO WARRANTY, EXPRESS,
STATUTORY, IMPLIED OR BY DESCRIPTION,
REGARDING THE INFORMATION SET FORTH HEREIN
OR REGARDING THE FREEDOM OF THE DESCRIBED
DEVICES
FROM
INTELLECTUAL
PROPERTY
INFRINGEMENT. ZILOG, INC. MAKES NO WARRANTY
OF MERCHANTABILITY OR FITNESS FOR ANY
PURPOSE.
Zilog, Inc. shall not be responsible for any errors that may
appear in this document. Zilog, Inc. makes no commitment
to update or keep current the information contained in this
document.
Zilog’s products are not authorized for use as critical
components in life support devices or systems unless a
specific written agreement pertaining to such intended use
is executed between the customer and Zilog prior to use.
Life support devices or systems are those which are
intended for surgical implantation into the body, or which
sustains life whose failure to perform, when properly used
in accordance with instructions for use provided in the
labeling, can be reasonably expected to result in
significant injury to the user.
Zilog, Inc. 210 East Hacienda Ave.
Campbell, CA 95008-6600
Telephone (408) 370-8000
FAX 408 370-8056
Internet: http://www.zilog.com
DS97Z8X0502
PRELIMINARY
65
1