RFPIC12F675F-I/SS Microchip Technology, RFPIC12F675F-I/SS Datasheet - Page 55

IC MCU 1KX14 RF FSK/ASK 20SSOP

RFPIC12F675F-I/SS

Manufacturer Part Number
RFPIC12F675F-I/SS
Description
IC MCU 1KX14 RF FSK/ASK 20SSOP
Manufacturer
Microchip Technology
Series
PIC®r
Datasheets

Specifications of RFPIC12F675F-I/SS

Package / Case
20-SSOP
Frequency
380MHz ~ 450MHz
Applications
RKE, Security Systems
Modulation Or Protocol
ASK, FSK
Data Rate - Maximum
40 kbps
Power - Output
10dBm
Current - Transmitting
14mA
Data Interface
PCB, Surface Mount
Antenna Connector
PCB, Surface Mount
Memory Size
1024 x 14 words Flash, 128 x 8 Byte EEPROM, 64 x 8 Byte SRAM
Voltage - Supply
2V ~ 5.5V
Operating Temperature
-40°C ~ 125°C
Processor Series
RFPIC12F
Core
PIC
Data Bus Width
8 bit
Data Ram Size
64 B
Interface Type
USB
Maximum Clock Frequency
20 MHz
Number Of Programmable I/os
6
Number Of Timers
2
Operating Supply Voltage
2 V to 5.5 V
Maximum Operating Temperature
+ 85 C
Mounting Style
SMD/SMT
Development Tools By Supplier
ICE2000, DV164102, AC164101, AC164103
Minimum Operating Temperature
- 40 C
On-chip Adc
4-ch x 10-bit
Program Memory Type
Flash
Program Memory Size
1.75 KB
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
For Use With
XLT20SS-1 - SOCKET TRANSITION 18DIP 20SSOPAC164103 - MODULE RCVR RFPIC 433MHZAC164101 - MODULE TRANSMITTER RFPIC 433MHZDV164102 - KIT DEV RFPICKIT KIT 1AC124002 - MOD SKT PROMATEII 18SOIC/20SSOP
Features
-
Lead Free Status / Rohs Status
Lead free / RoHS Compliant
Other names
Q3188156

Available stocks

Company
Part Number
Manufacturer
Quantity
Price
Part Number:
RFPIC12F675F-I/SS
Manufacturer:
MCP
Quantity:
181
Part Number:
RFPIC12F675F-I/SS
Manufacturer:
MICROCHIP
Quantity:
12 000
Part Number:
RFPIC12F675F-I/SS
Manufacturer:
MICROCHIP
Quantity:
17 867
9.6
The clock output is available to the microcontroller or
other circuits requiring an accurate reference
frequency. This signal would typically be used to
correct the internal RC oscillator for system designs
that require accurate bit synchronization or tight time
division multiplexing. The REFCLK output can
connect directly to the T0CKI or T1CKI.
The REFCLK output frequency is the crystal oscillator
divided by 4 on the rfPIC12F675K and rfPIC12F675F.
For the rfPIC12F675H the crystal oscillator is divided
by 8.
9.7
The LF pin connects to an internal node on the PLL
filter. Typically the pin should not be connected. In
specialized cases it may be necessary to load this pin
with extra capacitance to ground. Adding capacitance
reduces the loop filter bandwidth which trades off an
increase in phase noise for a reduction in clock spurs.
Useful diagnostic measurements can be taken on the
LF pin with a high impedance, low capacitance probe.
Measuring the time from RFEN going high until the LF
voltage stabilizes will determine the minimum delay
before the start of a transmission. For more information
on PLL filters refer to Application Note AN846 Basic
PLL Filters for the rfPIC™/rfHCS.
TABLE 9-4:
 2003 Microchip Technology Inc.
Layout considerations - Keep the clock trace short
and narrow yet as far as possible from other traces to
reduce capacitance and the associated current draw.
If the REFCLK trace must pass near the crystal and
LF nodes then shield them with ground traces.
Layout considerations - Keep traces short and if the
optional loop filter capacitor is required, place it as
close as possible to the LF pin with its own via to the
ground plane.
Note 1: Standard Operating Conditions, T
Power Step
Clock Output
Phase-Locked Loop Filter
2: Typical values, for complete specifications see data sheet Section 13.0.
3: R1 resistor variations plus I
4
3
2
1
0
POWER SELECT RESISTOR SELECTION
Output Power
(dBm)
-12
-70
-4
9
2
PS
current supply variations must not exceed V
A
= 25°C, RFEN = 1, V
Preliminary
PS Voltage
(Volts)
1.6
0.8
0.4
0.2
0.1
9.8
The PLL output feeds the power amplifier (PA) which
drives the open-collector ANT output. The output
should be DC biased with an inductor to the V
supply. The output impedance must be matched to the
load impedance to deliver the maximum power. This is
typically done with a transformer or tapped capacitor
circuit. Failure to match the impedance may cause
excessive spurious and harmonic emissions. For more
information on transformer matching see Application
Note AN831, Matching Small Loop Antennas to rfPIC™
Devices. For more information on tapped capacitor
matching see Application Note AN242 Designing an
FCC Approved ASK rfPIC™ Transmitter.
The transmit output power can be adjusted in five
discrete steps from +9 dBm to -70 dBm by varying the
voltage on the PS pin. Since the PS pin has an internal
8 µA source the voltage can be set with a resistor from
the PS pin to ground as shown in Figure 9-7. Some
possible resistor values to set the current are shown in
Table 9-4.
It is usually desirable to select the lowest power level
step that does not compromise communications reli-
ablity. The most important benefit is the conservation of
battery power. Another reason is to make it easier to
pass regulatory limits. And a third reason is to reduce
interference to other communications in the shared RF
spectrum. Small inefficient antennas will require higher
power level settings than larger efficient antennas.
FIGURE 9-7:
(1,2)
DDRF
Power Amplifier
R1 Resistance
= 3V, f
100k
47k
22k
open
short
(Ω)
R1
TRANSMIT
.POWER SELECT CIRCUIT
(3)
(3)
V
(3)
PS
rfPIC12F675
PS
PS
step limits.
= 433.92 MHz
RF Transmitter
rfPIC12F675
I
PS
Current (mA)
= 8
To power
select
circuitry
µA
10.7
6.5
4.7
3.5
2.7
DS70091A-page 53
DDRF

Related parts for RFPIC12F675F-I/SS