6. Pseudo SRAM (Standard)
The device is TOSHIBA 4MB SRAM (TC51V8512AFT 512K
×
8bit)
with access time of 120ns.
6-1. CPU interface
The figure below shows a typical pseudo SRAM interface in the up-
3300.
Fig. 8
6-2. Pseudo SRAM address
Standard pseudo SRAM is decoded as follows by the RASPN1 signal.
1
700000h
∼
7FFFFFh
The base signal is 2MB. It thus wraparounds with 600000H
∼
6FFFFFH 1MB.
Pseudo SRAM consists of 1 chip for respective even and odd number
addresses. Both of word and byte access from CPU are available.
7. NOR-type flash memory
Here is the explanation for the interface of NOR-type flash memory.
The device is Sharp’s LH28F016SU flash memory which consists of
512 K words
×
16 or 1 MB
×
8, with 16 blocks of 64 KB.
7-1. CPU interface
The figure below shows a typical interface for the LH28F016SU of the
up-3300 system.
Fig. 9
7-2. Device control
After resetting, the device automatically enters the array read mode
and perform the same action as the usual ROM, thus requiring no
special consideration when reading data.
Data can be written at high speed by using the page buffer.
8. SSP control
The UP-3300 uses flash memory in the place of EPROM, so it is
possible to rewrite the contents of the flash memory in changing the
program. However, since the existing gate array MPCA8 is used, it is
also possible to use the conventional SSP.
8-1. Operation
Like the MPCA7, the MPCA8 adopts the break address register com-
parison method for detecting addresses. The operation of this method
is briefly explained below.
The gate array always compares the break address register (BAR)
built in the gate array, with the address bus to monitor the address
bus.
If both agree, the gate array outputs the NMI signal to the CPU, which
in turn shifts from normal handling to exception handling.
In both the MPCA7 and the MPCA8, SSP is achieved by the above
operation.
The setting of the break address register (BAR) is directly written in
the addresses from FFFF00h to FFFFFFh.
9. Interrupt control
There are roughly two types of interrupts:
•
Internal interrupts:
Controlled inside the CPU
•
External interrupts:
Input into the CPU from outside
9-1. Internal interrupts
Device interrupts built in the CPU are used for the following applica-
tions:
Table 8
Event factor
Application
SC11
Interrupt source as IR channel
SC12
Not used (SC1 is used for CKDC interface.)
FRT1
(ICI)
(OCRA)
(OCRB)
(OVF)
INTMCR
∼
MCR interrupt (to FT11 terminal)
FRT2
(ICI)
Standard SHEN event (for CKDC)
(OCRA)
Simple IRC timer event
(OCRB)
RS232 timer event
(OVF)
System timer (53 ms)
TMR
(CMA)
(CMB)
(OVF)
WDT
(OVF)
Drawer open timer
A/D
Not used
NMI
SSP request
9-2. External interrupts
The following types of external interrupts are available:
•
NMI (SSP)
•
IRQ0 (Standard I/O interrupt)
•
IRQ1 (RS232 interrupt)
•
IRQ2 (Used as SCk terminal)
•
IRQ3 (Used as SCK terminal)
Odd side PSRAM
/OWR
A0
/HWR
/LWR
/RESET
/AS
/PCE1_O
/W3SWP
D7~D0
D15~D8
/WR
/CE
SD7~SD0
EVEN side PSRAM
Gate Array
RASPN1
A0
/RESET
/AS
/PCE1_E
/HWR
SD7~SD0
/WR
/CE
RASPN1E
RASPN1
/OE
.
/REFSH
RASPN1
or
RASPN2
/RD
/RESET
ISP
2032
/RASPN12
/PSREF
/PSRFO
ISP2032
H8/510
MPCA8
DATA
ADDRESS
HWR-
RD-
PORT64
PORT63
FROS1-
DQ0 ~ DQ15
A0 ~ A21
WE#
OE#
WP#
RY/BY#
RP#
CE0#
CE1#
VCC
VPP
BYTE#
3/5#
GND
LH28F
016SUT
RESET-
FYPON
NORDY
5V
/IPLON0
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