MITEL SP5055

SP5055
2.6GHz Bidirectional I2C BUS Controlled Synthesiser
Supersedes version in April 1994 Consumer IC Handbook, HB3120 - 2.0
DS2384 - 4.4 May 1996
The SP5055 is a single chip frequency synthesiser designed
for TV tuning systems. Control data is entered in the standard
I2C BUS format. The device contains 4 addressable current
limited outputs and 4 addressable Bi-Directional open collector
ports one of which is a 3 bit ADC. The information on these
ports can be read via the I2C BUS. The device has one fixed
I2C BUS address and 3 programmable addresses, programmed
by applying a specific input voltage to one of the current limited
outputs. This enables 2 or more synthesisers to be used in a
system.
FEATURES
■ Complete 2.6GHz Single Chip System
■ Programmable via I2C BUS
■ Low power consumption (5V 65mA)
■ Low Radiation
■ Phase Lock Detector
■ Varactor Drive Amp Disable
■ 6 Controllable Outputs, 4 Bi-Directional
■ 5 Level ADC
■ Variable I2C BUS Address For Multi Tuner Applications
■ Full ESD Protection*
* Normal ESD handling procedures should be observed.
Fig. 1 Pin connections – top view
APPLICATIONS
■ Satellite TV
■ High IF Cable Tuning Systems
ORDERING INFORMATION
SP5055S MP - (16 lead Miniature Plastic package)
SP5055
ELECTRICAL CHARACTERISTICS
Tamb = -20°C to +80°C, VCC = +4.7V to 5.3V.
These Characteristics are guaranteed by either production test or design. They apply within the specified ambient
temperature and supply voltage unless otherwise stated. Reference frequency = 4MHz unless otherwise stated.
Value
Characteristic
Pin
Units
Conditions
Typ.
Min.
Max.
Supply current
Prescaler input voltage
Prescaler input voltage
12
13, 14
13, 14
Prescaler input impedance
Prescaler input capacitance
13, 14
SDA, SCL
Input high voltage
Input low voltage
Input high current
Input low current
Leakage current
SDA
Output voltage
Charge pump current low
Charge pump current high
Charge pump output leakage current
Charge pump drive output current
Charge pump amplifier gain
Recommended crystal series resistance
Crystal oscillator drive level
Crystal oscillator negative resistance
4, 5
4, 5
4, 5
4, 5
4, 5
1
1
1
16
80
300
300
3
0
mA
VCC = 5V
mVRMS 500MHz to 2.6GHz Sinewave
mVRMS 120MHz, see Fig. 5
Ω
pF
50
2
4
5.5
1.5
10
-10
10
V
V
µA
µA
µA
Input voltage = VCC
Input voltage = 0V
When VCC = 0V
0.4
V
Isink = 3mA
µA
µA
nA
µA
Byte 4, bit 2 = 0, pin 1 = 2V
Byte 4, bit 2 = 1, pin 1 = 2V
Byte 4, bit 4 = 1, pin 1 = 2V
Vpin 16 = 0·7V
±50
±170
±5
500
6400
10
2
2
Output Ports
P0, P3 sink current
P0, P3 leakage current
P4-P7 sink current
P4-P7 leakage current
10, 11
10, 11
9-6
9-6
Input Ports
P3 input current high
P3 input current low
P4,P5,P7 input voltage low
P4,P5,P7 input voltage high
P6 input current high
P6 input current low
10
10
9,8,6
9,8,6
7
7
2
65
50
100
200
Ω
mVp-p
Ω
1.5
10
mA
µA
mA
µA
VOUT = 12V
VOUT = 13·2V
VOUT = 0.7V
VOUT = 13·2V
µA
µA
V
V
µA
µA
Vpin 10 = 13.2V
Vpin 10 = 0V
80
750
0.7
1
10
10
+10
-10
0.8
2.7
+10
-10
See Table 3 for ADC Levels
SP5055
Fig. 2 Block diagram
FUNCTIONAL DESCRIPTION
The SP5055 is programmed from an I2 C BUS. Data and
Clock are fed in on the SDA and SCL lines respectively as
defined by the I 2C BUS format. The synthesiser can either
accept new data (write mode) or send data (read mode). The
Tables in Fig. 3 illustrate the format of the data. The device
can be programmed to respond to several addresses, which
enables the use of more than one synthesiser in an I 2C Bus
system. Table 4 shows how the address is selected by
applying a voltage to P3. The last bit of the address byte
(R/W) sets the device into read mode if it is high and write
mode if it is low. When the SP5055 receives a correct address
byte it pulls the SDA line low during the acknowledge period
and during following acknowledge periods after further data
bytes are programmed. When the SP5055 is programmed
into the read mode the controlling device accepting the data
must pull down the SDA line during the following acknowledge
period to read another status byte.
WRITE MODE (FREQUENCY SYNTHESIS)
When the device is in the write mode Bytes 2 + 3 select the
synthesised frequency while bytes 4 + 5 select the output port
states and charge pump information.
Once the correct address is received and acknowledged,
the first Bit of the next Byte determines whether that byte is
interpreted as byte 2 or 4, a logic 0 for frequency information
and a logic 1 for charge pump and output port information.
Additional data bytes can be entered without the need to
re-address the device until an I2C stop condition is recognised.
This allows a smooth frequency sweep for fine tuning or AFC
purposes.
If the transmission of data is stopped mid-byte (i.e., by
another device on the bus) then the previously programmed
byte is maintained.
Frequency data from bytes 2 and 3 is stored in a 15-bit shift
register and is used to control the division ratio of the 15-bit
programmable divider which is preceded by a divide-by-16
prescaler and amplifier to give excellent sensitivity at the local
oscillator input; see Fig 5. The input impedance is shown in
Fig 7.
The programmed frequency can be calculated by
multiplying the programmed division ratio by 16 times the
comparison frequency F comp.
When frequency data is entered, the phase comparator,
via the charge pump and varactor drive amplifier, adjusts the
local oscillator control voltage until the output of the
programmable divider is frequency and phase locked to the
comparison frequency.
The reference frequency may be generated by an external
source capacitively coupled into pin 2 or provided by an onboard 4MHz crystal controlled oscillator.
Note that the comparison frequency is 7·8125kHz when a
4MHz reference is used.
Bit 2 of byte 4 of the programming data (CP) controls the
current in the charge pump circuit, a logic 1 for ±170µA and
a logic 0 for ±50µA, allowing compensation for the variable
tuning slope of the tuner and also to enable fast channel
changes over the full band. Bit 4 of byte 4 (T0) disables the
charge pump if set to a logic 1. Bit 8 of byte 4 (OS) switches
the charge pump drive amplifier’s output off when it is set to
a logic 1. Bit 3 of Byte 4 (T1) selects a test mode where the
phase comparator inputs are available on P6 and P7, a logic
1 connects F comp to P6 and F div to P7.
Byte 5 programs the output ports P0 to P7; on a logic 0 for
a high impedance output, logic 1 for low impedance (on).
READ MODE
When the device is in the read mode the status data read from
the device on the SDA line takes the form shown in Table 2.
Bit 1 (POR) is the power-on reset indicator and is set to a logic
1 if the power supply to the device has dropped below 3V and the
programmed information lost (e.g., when the device is initially
turned on). The POR is set to 0 when the read sequence is
terminated by a stop command. The outputs are all set to high
impedance when the device is initially powered up. Bit 2 (FL)
indicates whether the device is phase locked, a logic 1 is present
if the device is locked and a logic 0 if the device is unlocked.
3
SP5055
Bits 3, 4 and 5 (I2,I1,I0) show the status of the I/O Ports P7,
P5 and P4 respectively. A logic 0 indicates a low level and a logic
1 a high level. If the ports are to be used as inputs they should
be programmed to a high impedance state (logic 1). These
inputs will then respond to data complying with TTL type voltage
levels. Bits 6, 7 and 8 (A2,A1,A0) combine to give the output of
the 5 level ADC.
The 5 level ADC can be used to feed AFC information to
the microprocessor from the IF section of the receiver, as
illustrated in the typical application circuit.
APPLICATION
A typical Application is shown in Fig. 4. All input/output
interface circuits are shown in Fig. 6.
MSB
Address
LSB
1
1
0
0
0
Programmable divider
0
14
13
12
11
Programmable divider
7
2
2
Charge pump and test bits
1
P7
I/O port control bits
2
6
2
5
2
2
MA1 MA0
10
2
9
2
1
0
A
Byte 1
8
A
Byte 2
0
2
2
4
2
3
2
2
2
2
2
A
Byte 3
CP
T1
T0
1
1
1
OS
A
Byte 4
P6
P5
P4
P3
X
X
P0
A
Byte 5
1
A
Byte 1
A0
A
Byte 2
Table 1 Write data format (MSB transmitted first)
Address
1
1
Status byte
POR FL
0
0
0
I2
I1
I0
MA1 MA0
A2
A1
Table 2 Read data format (MSB is transmitted first)
A
MA1, MA0
CP
T1
T0
OS
P7, P6, P5, P4,
P3, P0
POR
FL
I2, I1, I0
A2, A1, A0
X
:
:
:
:
:
:
:
Acknowledge bit
Variable address bits (see Table 4)
Charge Pump current select
Test mode selection
Charge pump disable
Varactor drive Output disable Switch
Control output states
:
:
:
:
:
Power On Reset indicator
Phase lock detect flag
Digital information from Ports P7, P5 and P4, respectively
5 Level ADC data from P6 (see Table 3)
Don't care
A2
A1
A0 Voltage input to P6
1
0
0
0.6VCC to 13.2V
0
0
0V to 0·2VCC
0
1
1
0·45VCC to 0·6VCC
0
1
Always valid
0
1
0
0·3VCC to 0·45VCC
1
0
0·3VCC to 0·7VCC
0
0
1
0·15VCC to 0·3VCC
1
1
0·8VCC -13.2V
0
0
0
0 to 0.15VCC
Table 4 Address selection
Table 3 ADC levels
Fig. 3 Data formats
4
MA1 MA0 Voltage input to P3
SP5055
APPLICATION
A typical application is shown in Fig. 4. All input/output interface circuits are shown in Fig. 6.
Fig. 4 Typical application
Fig. 5 Typical input sensitivity
5
SP5055
Fig. 6 SP5055 Input/output interface circuits
6
SP5055
Fig. 7 Typical input impedance
ABSOLUTE MAXIMUM RATINGS
All voltages are referred to VEE and pin 3 at 0V
Parameter
Supply voltage
RF input voltage
Pin
12
Units
Min.
Max.
-0.3
7
V
2.5
Vp-p
14
6
14
V
V
V
13, 14
Port voltage
6-11
6-9
10, 11
Total port output current
6-11
RF input DC offset
Value
-0.3
-0.3
-0.3
50
-0.3
VCC+0.3
V
Charge pump DC offset
1
-0.3
VCC+0.3
V
Drive DC offset
16
-0.3
VCC+0.3
V
Crystal oscillator DC offset
2
-0.3
VCC+0.3
V
4, 5
-0.3
-0.3
VCC+0.3
5.5
V
V
-55
+125
°C
Junction temperature
+150
°C
MP 16 Thermal resistance, chip-to-ambient
MP 16 Thermal resistance, chip-to-case
111
41
°C/W
°C/W
Power consumption at 5.5V
440
mW
Storage temperature
Port in off state
Port in on state
Port in on state
mA
13, 14
SDA, SCL input voltage
Conditions
With VCC applied
VCC not applied
All ports off
7
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