ATMEL U3600BM-NFNY

Features
• All Functions and Channel Selections are Controlled by Serial Bus
RF Part
•
•
•
•
All Oscillators and PLL Integrated
IF Converter
FM Demodulator
RSSI
Low Frequency Part
•
•
•
•
•
Asymmetrical Input of Microphone Amplifier
Asymmetrical Output of Earpiece Amplifier
Compander
Power Supply Management
Serial Bus
Single-chip
Cordless
Telephone IC
U3600BM
Application
• CT0 Standard
• Narrowband Voice and Data Transmitting/Receiving Systems
1. Description
The programmable single-chip multichannel cordless phone IC includes all necessary
low frequency parts such as microphone- and earphone amplifier, compander, powersupply management as well as all RF parts such as IF converter, FM demodulator,
RSSI, oscillators and PLL. Several gains and mutes in transmit and receive direction
are controlled by the serial bus. The compander can be bypassed.
Rev. 4516D–CT0–10/05
Figure 1-1.
Block Diagram
MIX1IN2
41
MIX1IN1
MIX2IN
MIX2O
OSCGND
MIX1O
XCK VAF
MIX2GND
39
40
42
37
38
Mixer1
GNDLO
36
34
35
IFIN1
IFIN2
LO1
43
44
VCO3
f LO
:2
fLO
sin
cos
PCLO 1
f Ref3
:N
(3)
Serial
Bus
:K
-
EXIN
29
Ear
Amp
27
26
Demodulator
+
Bias
Bat low
Detector
Phase
Comparator
28
Expander
MUXDA
D
A
f LO
LO2
30
IF
Amp
RSSI
Mixer2
Crystal
Oscillator
ETC
31
32
33
25
+
1
DATRX
RECO
RECO2
RXO
DAIN
1.5V
Mic
+
MixerT
+45
-45
:D2
:D3
(1)
:D1
:M12
:M12
(2)
RFOGND
RFO
RFOVB
3
Loop
Filter
VCO2
4
5
AGND
6
VBIAS
8
VRF
2
+
Spl 1.5V
Limiter
Amp
-
Phase
Comparator
10
MLF LFGND MODIN
(1): PLL1: Modulator PLL
20
f Ref1
9
11
VDD
(2): PLL2: Mixer PLL
12
22
21
:2
VCO1
7
Compressor
:M
:2
Phase
Comparator
2
VRMIC
23
:10
f Mod
f Ref2
24
13
14
15 16
17
19
MIC
MICO
COIN
CTC
COUT
LIMIN
18
VSS D C
TXO
OPOUT
OPIN
DACO
(3): PLL3: Local oscillator (LO) PLL
U3600BM
4516D–CT0–10/05
U3600BM
2. Pin Configuration
Figure 2-1.
Pinning SSO44
PCLO
1
44
LO1
RFOGND
2
43
LO2
RFO
3
42
GNDLO
RFOVB
4
41
MIX1IN2
AGND
5
40
MIX1IN1
VBIAS
6
39
MIX1O
VRF
7
38
OSCGND
MLF
8
37
XCK
LFGND
9
36
VAF
MODIN
10
35
MIX2O
VDD
11
34
MIX2GND
VSS
12
33
MIX2IN
D
13
32
IFIN1
C
14
31
IFIN2
DACO
15
30
ETC
OPOUT
16
29
EXIN
OPIN
17
28
RECO1
TXO
18
27
RECO2
LIMIN
19
26
RXO
COUT
20
25
DAIN
CTC
21
24
MIC
COIN
22
23
MICO
3
4516D–CT0–10/05
Table 2-1.
4
Pin Description
Pin
Symbol
1
PCLO
Function
2
RFOGND
3
RFO
4
RFOVB
Power supply input of RF transmit output buffer
5
AGND
Analog ground for RF part
6
VBIAS
7
VRF
Supply voltage for RF part
8
MLF
Modulator loop filter
9
LFGND
Modulator loop filter ground
10
MODIN
Modulator input
11
VDD
Supply voltage output for peripherals and internal supply of digital part
12
VSS
Ground for LF analog and digital
13
D
Data input of serial bus
14
C
Clock input of serial bus
15
DACO
16
OPOUT
17
OPIN
Operational amplifier input (inverting)
18
TXO
Output of limiter amplifier
19
LIMIN
Limiter input
20
COUT
Compressor output
21
CTC
Compressor time constant control analog output
22
COIN
Compressor input
23
MICO
Microphone amplifier output
Phase comparator local oscillator
RF transmit output ground
RF transmit output
Decoupling capacitor of current reference
D/A and data comparator output
Operational amplifier output
24
MIC
Inverting input of microphone amplifier
25
DAIN
Data comparator input
26
RXO
Output of demodulator
27
RECO2
28
RECO1
29
EXIN
Expander input
30
ETC
Expander time constant control analog output
31
IFIN2
32
IFIN1
33
MIX2IN
34
MIX2GND
35
MIX2O
Symmetrical output of receive amplifier
Symmetrical input of IF amplifier
Input of Mixer2
IF amplifier and Mixer2 ground
Mixer2 output
36
VAF
Supply voltage for AF/IF parts
37
XCK
Crystal oscillator input 11.15 MHz
38
OSCGND
Oscillator ground
39
MIX1O
Output of Mixer1
40
MIX1IN1
41
42
MIX1IN2
GNDLO
43
44
LO2
LO1
Symmetrical input of MIxer1
Ground of LO
Tank elements for LO are connected to these pins
U3600BM
4516D–CT0–10/05
U3600BM
3. System Description
Radio frequency IC for analog cordless telephone application in 26/50 MHz band (CTO standard). The IC performs full duplex communication. The transmitting and receiving frequency are
depending on whether the IC is used in the handset or in the base station.
Frequency converter comprise an FM transmitter with switchable output power and first receiver
mixer in the same unit. A two-wire bus interface can be used for the frequency control as well as
for switching the transmitter power amplifier and the receiver. Fine frequency adjust of reference
quartz oscillator is programmable.
The receive part is designed for a double conversion architecture. The incoming radio frequency
signal will be filtered and amplified before reaching the first mixer. At this stage the RF signal will
be converted down to the first intermediate frequency (10.7 MHz) by using a crystal oscillator
(LO1).
The transmit part contains two PLL controlled VCOs. The frequency modulation is accomplished
by super-posing the incoming audio signal on the PLL control voltage. Final frequency is a product of mixing VCO1 with first local oscillator of receiver part (VCO3). The FM modulated carrier
is amplified by externals power amplifier before entering the output filter and the antenna
connector.
3.1
Adjustments for VCO1 and VCO2
To be able to use a wide frequency range for the VCOs (i.e., VCO2 26.3 MHz to 49.9 MHz) the
two internal VCOs (VCO1 and VCO2, i.e., the VCOs of the transmit part) have a rough adjust
and a fine adjust to increase the frequency range given by the phase comparator.
The rough adjusts for these VCOs are correlated with the country setting. For every country
there are two sets of VCO rough adjust settings, one for the base and one for the handset. See
tables at channels frequencies and dividers.
To compensate the variation in production there is a fine adjust for each of the VCOs. The fine
adjusts of the internal VCOs could be set manually (for test purposes) or set by the automatic
mode. Theoretically the sign of the changing (increase/ decrease when the voltage of the phase
comparator is to high) is selectable, but we need value 1 () in all cases.
Setting VCO1 (VCO2) under normal conditions:
EAFA1 (EAFA2) = 1, automatic fine adjust VCO1(VCO2) enabled
SAFA1 (SAFA2) = 1, sign of auto fine adjustment of VCO1 (VCO2) = 1.
3.2
Adjustment for VCO3
In order to increase the adjustment range of VCO3 with fixed external tank elements and/or for
“band switching”, especially for US frequencies, VCO3 has programmable capacitors inside.
These capacitors can be added by serial bus (FA3 [4:0]) between LO1 and LO2. There are 31
steps available, every step adding a capacitor of 0.5 pF.
5
4516D–CT0–10/05
3.3
Speed-up of the Loop Filter of PLL1 (“Modulator PLL”)
To have a fast locking time for the modulator loop there is a precharge and a speed-up mode for
the external loop filter.
During receive mode (VCO3 enabled, VCO1 disabled) the modulator loop filter is precharged to
about half of the internally regulated 2.5V charge-pump voltage.
During the first 30 ms after enabling VCO1 the modulator phase comparator is in speed-up
mode. In this mode the current of the pase comparator which charges the loop filter is much
larger than in normal mode. Additionally to the automatically switched 30 ms speed-up mode,
the speed-up can be activated for any time by setting the bit SU1.
3.4
Speed-up of the Loop Filter of PLL3 (“1st. LO.”)
Similiar to PLL1, there is also a possibility to increase the locking speed of PLL3. This can be
done by setting the bit SU3. Having done this, the charge pump at the output of the phase comparator has a bigger current capability and therefore charges the external capacitors faster.
3.5
Adjustment of the Modulator Gain
To fulfil the different requirements of the different countries three conversion gains of the modulator are selectable by the bits GMOD [1:0] (R6: D2, D3).
Country settings see tables at channel frequencies and dividers. Ranges see electrical characteristics at RF transmitter.
3.6
Modulator PLL
The fractional divider has been chosen to increase the reference frequency of the modulator
PLL.
Q1 ⎞
557.5 kHz = f Mod / ⎛ P 1 + --------⎝
223⎠
P1: integer part of the fractional divider (M = 1)
Q1: fractional part of the fractional divider (M = 1)
f Mod
Q 1 = 223 × ⎛ -------------------------- – P 1⎞
⎝ 557.5 kHz
⎠
kHz223 = 557.5
-------------------------2.5 kHz
The frequency step 2.5 kHz is a fraction of the reference frequency 557.5 kHz.
In fact, the fractional divider divides Q1 times by (P1 + 1) and (223 – Q1) times by P1
during 223 cycles.
Q 1 × ( P 1 + 1 ) + ( 223 – Q 1 )P 1
Q1
→------------------------------------------------------------------------------ = P 1 + --------223
223
For each comparison cycle (fRef1 = 557.5 kHz), the accumulator content is incremented by the
Q1 value and the divider divides by the P1 value. When the accumulator value reaches or
exceeds 223, the divider divides by the value (P1 + 1). Then, the accumulator holds the excess
value (accumulator value - 223). After 223 cycles, the correct division is executed.
6
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U3600BM
3.7
Serial Bus Interface
The circuit is remoted by an external microcontroller through the serial bus.
The data is a 12-bit word:
A0 - A3: address of the destination register (0 to 15)
D7 - D0: contents of register
The data line must be stable when the clock is high and data must be serially shifted.
After 12 clock periods, the transfer to the destination register is (internally) generated by a low to
high transition of the data line when the clock is high.
Figure 3-1.
Serial Bus
Data
Microprocessor
Figure 3-2.
D
Clock
C
Serial Bus Transmission
Data
(D)
D0
D1
D2
A1
A0
A2
A3
Clock
(C)
1st word
2nd word
Word transmission
Figure 3-3.
Transfer condition
Serial Bus Structure
Data
8
4
Clock
0
128
Address
Latches
Decoder
15
Commands
7
4516D–CT0–10/05
Figure 3-4.
Serial Bus Timing Diagram
Data
(D)
A1
A2
A3
D0
Clock
(C)
tsud
3.8
thd
teon
tcl
tch
teh
teoff
Content of Internal Registers
The registers have the following structure
D7
D6
D5
D4
D3
D2
D1
D0
DA4
DA3
DA2
DA1
DA0
GDEM
free
free
MRX
ERX2
R0: Reference for D/A converter
MUXDA
MUXDA:
DA(0:6):
DA6
DA5
D/A multiplexing VBAT/RSSI
Reference voltage D/A
R1: Gain of earpeace amplifier and demodulator
GEA4
GEA[0:4]:
GDEM:
GEA3
GEA2
GEA1
GEA0
Gain of earpeace amplifier; “0” is LSB, “4” is MSB
Demodulator gain (1 = low gain)
R2: Switches and mutes for receive and data reception
DATRX
DATRX:
BEXP:
EEA:
ERXO:
ERX1:
ERXHF:
MRX:
ERX2:
8
BEXP
EEA
ERXO
ERX1
ERXHF
Switch data comparator output to “DACO”-pin
Bypass expander
Enable earpiece amplifier
Enable RXO output driver
Enable RX low frequency part 1
Enable Mixer2 and IF-amplifier
Mute RX low frequency path (expander) keeping circuit enabled
Enable RX low frequency part 2 (expander)
U3600BM
4516D–CT0–10/05
U3600BM
R3: Switches and mutes for transmit and power managemant
PDVDD
PDVDD:
RBAT:
MTX:
ETX:
RBAT
free
free
free
free
MTX
ETX
Enable pull-down transistor in power-down mode
Battery detection high/low range
Mute TX low frequency path (compressor) keeping circuit enabled
Enable TX low frequency part
R4: free (not used, for future extensions )
free
free
free
free
free
free
free
free
KV23
KV22
KV21
M12
free
free
GMOD0
SU1
(TM)
R5: Gain VCO2
free
KV2[1:3]:
M12:
free
Gain of VCO2
Double phase comparator frequency of PLL2
R6: Miscellaneus settings in synthesizer part
ETXO
M1CP
FRMT
IMIXI
GMOD1
ETXO:
M1CP:
Enable HF-transmit output
Changes 1 dB compression point and current consumption of Mixer1
(“0” –> high, “1” –> low)
FRMT:
Output frequency range of MixerT
IMIXI:
Invert inputs of phase comparator in PLL2
GMOD[0:1]: Modulation gain of VCO1
SU1:
Speed-up phase comparator for PLL1
(TM):
Enable the internal test mode. It is mandatory that TM is kept to “0”!
(if not 0, the circuit will not work as expected or described here in this paper)
R7: PLL1 setting
DR1I1
DR1I0
RA11
RA10
DV1I3
DV1I2
DV1I1
DV1I0
DV1F1
DV1F0
DR1I[0:1]: Additional divider reference frequency PLL1
RA1[0:1]: Rough adjustment VCO1
DV1I[0:3]: Divider setting PLL1 integer part; “0” is LSB, “3” is MSB
R8: Divider PLL1 fractional part
DV1F7
DV1F6
DV1F5
DV1F4
DV1F3
DV1F2
DV1F[0:7]: Divider setting PLL1 fractional part; “0” is LSB, “7” is MSB
9
4516D–CT0–10/05
R9: Divider PLL3 LSBs
DV3I7
DV3I6
DV3I5
DV3I4
DV3I3
DV3I2
DV3I1
DV3I0
DV3I9
DV3I8
R10: Divider PLL3 MSBs and MSB of VCO3 fine adjustment
FA34
DV3I14
DV3I13
DV3I12
DV3I11
DV3I10
FA34:
Fine adjustment VCO3 (frequency reduction) MSB
DV1I[0:14]: Divider setting PLL3 integer part; “0” is LSB, “14” is MSB
R11: Setting PLL2 and VCO3
FA33
FA32
FA31
FA30
AMIX2
AMIX1
RA21
RA20
FA3[0:4]: Fine adjustment of VCO3 (frequency reduction); “0” is LSB, “4” is MSB
AMIX[1:2]: Lengthening antibacklash signal PLL2
RA2[1:0]: Rough adjustment VCO2
R12: Divider for country setting, fine adjustment oscillator
FAOS2
FAOS1
FAOS0
D31
D30
D20
D11
D10
FAOS[0:2]: Fine adjustment of crystal oscillator (frequency reduction);
“0” is LSB, “2” is MSB
D3[0:1]:
Setting divider D3
D20:
Setting divider D2
D1[0:1]:
Setting divider D1
R13: VCO1 enable and fine adjustment
EVCO1
EVCO1:
SAFA1:
EAFA1:
FA1(0:4):
SAFA1
EAFA1
FA14
FA13
FA12
FA11
FA10
FA21
FA20
Enable VCO1
Sign for automatic fine adjustment of VCO1
Enable automatic fine adjustment of VCO1
Manual fine adjustment of VCO1 (frequency reduction);
“0” is LSB, “4” is MSB
R14: VCO2 enable and fine adjustment
EVCO2
EVCO2:
SAFA2:
EAFA2:
FA2(0:4):
10
SAFA2
EAFA2
FA24
FA23
FA22
Enable VCO2 and MixerT
Sign for automatic fine adjustment of VCO2
Enable automatic fine adjustment of VCO2
Manual fine adjustment of VCO2 (frtequency reduction);
“0” is LSB, “4” is MSB
U3600BM
4516D–CT0–10/05
U3600BM
R15: VCO3 enable, speed-up and referencq frequency, crystal oscillator enable
EVCO3
EOSC
SU3
E25K
E12K5
E10K
E6K25
E5K
EVCO3:
Enable VCO3 and Mixer1
EOSC:
Enable crystal oscillator (11.15 MHz)
SU3:
Speed-up phase comparator for PLL3
E25K:
Selection phase comparator frequency for PLL3: fRef3 = 25 kHz
E12K5:
Selection phase comparator frequency for PLL3: fRef3 = 12.5 kHz
E10K:
Selection phase comparator frequency for PLL3: fRef3 = 10 kHz
E6K25:
Selection phase comparator frequency for PLL3: fRef3 = 6.25 kHz
E5K:
Selection phase comparator frequency for PLL3: fRef3 = 5 kHz
E5K, E6K25, E10K, E15K5, E25K = 0:
Selection phase comparator frequency for PLL3: fRef3 = 2.5 kHz
4. Absolute Maximum Ratings
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating
only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this
specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Parameters
Symbol
Supply voltage
Value
Unit
VBatt, VDD
5.5
V
Junction temperature
Tj
+125
°C
Ambient temperature
Tamb
–25 to +75
°C
Storage temperature
Tstg
–50 to +125
°C
Power dissipation Tamb = 60°C
Ptot
0.9
W
Symbol
Value
Unit
RthJA
70
K/W
5. Thermal Resistance
Parameters
Junction ambient SSO44
11
4516D–CT0–10/05
6. Electrical Characteristics
Tamb = +25°C, VRF = VAF = RFOVB = 3.6V, all bits set to “0”, unless otherwise specified.
Test circuit, see Figure 8-1 on page 18. Crystal specifications, see table “Crystal Specifications”.
Parameters
Test Conditions
Symbol
Min.
Typ.
Max.
Unit
3.1
3.6
5.2
V
Power Supply
Operating voltage range
Current Consumption
Operating current in inactive
mode (low voltage)
VRF = VAF = RFOVB = 2.9V
VDD = 0V
30
65
85
µA
Operating current in standby
mode
VRF = VAF = RFOVB = 3.6V
30
100
350
µA
Operating current in RX mode
“waiting for RSSI”
ERXHF = EVCO3 = EOSC = 1
7.5
10.4
mA
Operating current in RX mode
“receiving data”
ERXHF = EVCO3 = EOSC = ERX1
= ERXO = 1
8.5
11.5
mA
Operating current in
conversation mode: all blocks
enabled
ERXHF = EVCO3 = EOSC = ERX1 = ERXO
= ERX2 = EEA = EVCO2 = ETXO = 1
no load at RFO pin 3
20
29
mA
Charge Pump of LL1
Charge pump output voltage
Output high
2.38
2.5
2.63
V
Precharge voltage at the loop
filter
SB127 = 1, SB119 = 0
1.15
1.4
1.65
V
VMLF = 1.25V, output low
190
400
µA
VMLF = 1.25V, output high
–400
–190
µA
VMLF = 1.25V, output low
4.3
6.2
8
µA
VMLF = 1.25V, output high
–8
–6.2
–4.3
µA
+150
nA
Charge pump output current
in speed-up mode
Charge pump output current
Charge pump leakage current
VMLF = 1.25V, output tristate
–150
Charge pump output voltage
Output high
2.38
2.63
V
Charge pump output current
in speed-up mode
VPCLO = 1.25V, output low
220
420
µA
VPCLO = 1.25V, output high
–420
–220
µA
VPCLO = 1.25V, output low
80
160
µA
VPCLO = 1.25V, output high
–160
–80
µA
VPCLO = 1.25V, output tristate
–50
+50
nA
20
50
MHz
Charge Pump of PLL3
Charge pump output current
Charge pump leakage current
2.5
Receiver Input Mixer (Mixer1), EVCO3 = EOSC = 1
Input frequency range
Output frequency
10.7
MHz
Input resistance
MIX1IN1/MIX1IN2 to GND
3.0
kΩ
Input capacitance
MIX1IN1/MIX1IN2 to GND
3.5
pF
Output impedance
MIX1O
Voltage gain
MIX1IN1/2 -> MIX1O
“Loaded” (330 Ω with serial capacitance)
“Unloaded”
Input noise voltage
12
210
330
390
Ω
11.5
17.5
dB
dB
9
nV Hz–1/2
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U3600BM
6. Electrical Characteristics (Continued)
Tamb = +25°C, VRF = VAF = RFOVB = 3.6V, all bits set to “0”, unless otherwise specified.
Test circuit, see Figure 8-1 on page 18. Crystal specifications, see table “Crystal Specifications”.
Parameters
Test Conditions
Input 1-dB compression point
“Loaded” (330Ω with serial capacitance)
M1CP=0
M1CP=1
“unloaded”
M1CP=1
Third order input intercept
point
“Loaded” (330Ω with seial capacitance)
M1CP=0
Symbol
Min.
Typ.
Max.
Unit
140
40
mV
mV
100
mV
430
mV
IF Mixer (Mixer2), EOSC = ERXHF = 1; Input Frequency: 10.7 MHz
Input resistance
MIX2IN to GND
Input capacitance
MIX2IN to GND
Output impedance
MIX2O
Voltage gain
2.0
3.0
4.0
kΩ
2.5
3
3.5
pF
1200
1500
1800
Ω
MIX2IN -> MIX2O
“Loaded” (1500Ω with serial capacitance)
13
15
17
dB
Input 1-dB compression point
“Loaded” (1500Ω with serial capacitance)
32
mV
Third order input intercept
point
“Loaded” (1500Ω with serial capcitance)
80
mV
IF Amplifier and Demodulator, ERXHF=1, ERX1=1, ERXO=1; Input Signal: 450 kHz, 500 µV, FM-modulation Frequency = 1 kHz
Recovered audio at RXO,
demodulator gain
GDEM=0
GDEM=1
180
90
mV/kHz
mV/kHz
AM rejection ratio
30% AM, 2.5 kHz FM
35
dB
Expander, ERX2 = 1; 470 nF from ETC to GND (VSS)
Gain reference level = G.R.L.
(gain = 0 dB)
70
80
90
mVrms
–11
–21
–35
–10
–20
–30
–9
–19
–25
dB
dB
dB
Gain versus input signal level
(“gain tracking”)
VEXIN = 10 dB less than G.R.L.
VEXIN = 20 dB less than G.R.L.
VEXIN = 30 dB less than G.R.L.
Attack time
VEXIN = step 25 mV –> 50 mV
measure time after step, when output
voltage has 0.75 times of final value
16
ms
Release time
VEXIN = step 50 mV –> 25 mV
measure time after step, when output
voltage has 1.5 times of final value
16
ms
Input resistance
9.5
15
kΩ
Earpiece Amplifier, EEA = 1, ERX2 = 1, BEXP = 1; Apply Input Voltage to EXIN; Measure Differentially at RECO1/2
Minimum gain
GEA[4:0]=0
0
1
2
dB
Medium gain
GEA[4:0]=16
16
17
18
dB
Maximum gain
GEA[4:0]=31
Gain adjust step
Output voltage swing
Input resistance
Maximum gain; 1 kΩ load; increase input
voltage until distortion ≈ 5%
31
32
33
dB
0.8
1
1.2
dB
4.8
5
7.3
Vpp
12.5
kΩ
13
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6. Electrical Characteristics (Continued)
Tamb = +25°C, VRF = VAF = RFOVB = 3.6V, all bits set to “0”, unless otherwise specified.
Test circuit, see Figure 8-1 on page 18. Crystal specifications, see table “Crystal Specifications”.
Parameters
Test Conditions
Symbol
Min.
Typ.
Max.
Unit
IF Amplifier: RSSI
Input frequency
ERXHF=1
Input resistance
450
1.6
2.0
kHz
2.5
kΩ
VIF = 0 µV
starting from 0 increase RSSI-level until
mean of sampled signal at DACO is ≥ 0.5.
RSSI-level = ION0
RSSI sensitivity
1
VIF = 25.4 µV, f = 450 kHz
increase RSSI level again until mean of
sampled signal at DACO is ≥ 0.5.
RSSI-level = ION1
RSSI-sensitivity = ION1-ION0
RSSI input voltage dynamic
range
65
dB
RSSI level number of
programmable steps (see
folowing table “RSSI Level
Programming (Typical Values)
127
dB
RSSI level step size in the
logarithmic region
Table 6-1.
14
0.35
0.46
0.6
dB
RSSI Level Programming (Typical Values)
Input Voltage VIF (µV)
RSSI Level (Decimal)
0
5
25.4
8
42.4
14
424
54
4240
97
42400
111
U3600BM
4516D–CT0–10/05
U3600BM
7. Electrical Characteristics
Tamb = +25°C, VRF = VAF = RFOVB = 3.6V, all bits set to “0”, unless otherwise specified. Test circuit, see Figure 8-1 on page 18.
Parameters
Test Conditions
Symbol
Min.
Typ.
Max.
Unit
Data Comparator, ERX1 = DATRX = 1
Hysteresis
50
mV
Threshold voltage
1.5
V
Input impedance
DAIN
100
kΩ
Output high voltage
DACO, without load
(CMOS-output –> full swing)
3.5
V
Output low voltage
DACO, without load
(CMOS-output –> full swing)
0.1
V
Output impedance
DACO
6
kΩ
Battery Switch
“Off” threshold
Decrease VBAT until internal switch
between VBAT and VDD becomes high
ohmic (“off”)
2.85
2.95
3.1
V
“On” threshold
Increase VBAT until internal switch
between VBAT and VDD becomes low
ohmic (“on”)
3.1
3.2
3.35
V
Hysteresis
Difference between on and off threshold
250
mV
“Off”-leakage current
10
µA
Switch “On”-resistance
50
Ω
Battery Management, MUXDA = 1
Maximum bat low
DA[6:0] = 127, RBAT = 1
3.7
3.95
4.1
V
Minimum bat low over switch
DA[6:0] = 27, RBAT = 1
3.05
3.2
3.35
V
Maximum bat high
DA[6:0] = 127, RBAT = 0
4.75
5.05
5.25
V
Minimum bat high
DA[6:0] = 0, RBAT = 0
3.83
4.1
4.27
V
3.5
7.5
11.5
mV
852.5
952.5
1052.5
mV
Adjust step
Maximum - Minimum
Microphone Amplifier, ETX=1
Open loop gain
80
dB
Gain bandwidth product
3
MHz
Input noise voltage,
BW = 300 Hz to 3.4 kHz,
psophometrically weighted
0.8
2
µVrmsp
298
316
340
mVrms
9
19
22
10
20
25
30
11
21
28
Compressor, ETX = 1; 470 nF from CTC to GND (VSS)
Gain reference level = G.R.L.
(gain = 0 dB)
Gain versus input signal level
(“gain tracking”)
VCOIN = 20 dB less than G.R.L.
VCOIN = 40 dB less than G.R.L.
VCOIN = 50 dB less than G.R.L.
VCOIN = 60 dB less than G.R.L
Attack time
VCOIN = step 31.6 mV –> 126 mV,
(-30 dBV –> –18 dBV)
measure time after step, when output
voltage has 1.5 times of final value
3.5
dB
ms
15
4516D–CT0–10/05
7. Electrical Characteristics (Continued)
Tamb = +25°C, VRF = VAF = RFOVB = 3.6V, all bits set to “0”, unless otherwise specified. Test circuit, see Figure 8-1 on page 18.
Parameters
Test Conditions
Release time
VCOIN = step 126 mV –> 31.6 mV
(–18 dBV –> –30 dBV)
measure time after step, when output
voltage has 0.75 times of final value
Input resistance
Symbol
Min.
Typ.
Max.
14.4
14
19.5
Unit
ms
26
kΩ
Splatter Amplifier, ETX = 1
Open loop gain
90
dB
Gain bandwidth product
150
kHz
Maximum output voltage
swing
2.4
Vpp
Limiter Amplifier, ETX = 1, Tj = 25°C
Gain for signals below
limitation
LIMIN –> TXO,
20 mVRMS applied to LIMIN (AC coupled)
Distortion for signals below
limitation
LIMIN –> TXO,
20 mVRMS applied to LIMIN (AC coupled)
Maximum output voltage
swing (above limitation,
clipping)
26
1.8
2.1
dB
2
%
2.35
Vpp
Input resistance at LIMIN
15
20
25
kΩ
Note:
The gain and maximum output voltage swing of the limiter amplifier changes with temperature to compensate the temperature dependancy of MODIN (“tx conversion gain” of RF transmit part), fundamentally determined by the structure of the
circuitry.
RF Transmitter, ETXO = EVCO1 = EVCO2 = EVCO3 = EOSC = 1; Tj = 25°C
MODIN input impedance
RFO output impedance
Load = 200 ø
RFO output voltage level
ETXO = 0; no load
Highest operating frequency
USA Base Channel 9 (US1b9)
70
100
130
kΩ
230
300
390
Ω
0.3
V
49.99
00
MHz
USA1:
GMOD[1:0] = 00; fMod = ~7.6 MHz
5.2
kHz/V
USA2:
GMOD[1:0] = 01; fMod = ~5.7 MHz
5.2
kHz/V
France:
GMOD[1:0] = 01; fMod = 4.3 MHz
GMOD[1:0] = 00; fMod = 4.3 MHz
3.8
2.7
kHz/V
kHz/V
Spain/Netherlands:
GMOD[1:0] = 10; fMod = 1.8 MHz
7.9
kHz/V
For the complete programming see
“Channel Frequencies, Dividers and
Country Settings” on page 20“
TX conversion gain
MODIN - RFO
Demodulated distortion THD
MODIN - RFO
16
Modulation frequency: 1 kHz
US:
∆F = 4.0 kHz
France: ∆F = 2.5 kHz
1.5
5
%
U3600BM
4516D–CT0–10/05
U3600BM
7. Electrical Characteristics (Continued)
Tamb = +25°C, VRF = VAF = RFOVB = 3.6V, all bits set to “0”, unless otherwise specified. Test circuit, see Figure 8-1 on page 18.
Parameters
Test Conditions
Symbol
Min.
Typ.
Max.
Unit
Note:
The tx conversion gain of the RF transmitter is somehow dependent on temperature. This is determined by the fundamental
principle of this circuitry. Means have been taken inside the limiter amplifier, being in the signal path before MODIN, which are
able to completely compensate this temperature behavior.
Logical Part
Inputs: C, D
Low voltage input
High voltage input
Vil
Vih
0.2 × VDD
0.8 × VD
D
Input leakage current
(0 < VI < VDD)
Ii
Input leakage current
Pin XCK (0 < VI < VDD)
–1
–5
Serial bus (Figure 8-2)
Data set-up time
Data hold time
Clock low time
Clock high time
Hold time before transfer
condition
Data low pulse on transfer
condition
Data high pulse on transfer
condition
+5
µA
+5
µA
tsud
thd
tcl
tch
teon
0.1
0
2
2
0.1
µs
µs
µs
µs
µs
teh
0.2
µs
teoff
0.2
µs
8. Fine Adjustment of the Oscillator Frequency
To set the frequency of the oscillator exact to 11.15 MHz, the frequency is adjustable in 8 steps, by adding 3 different internal capacities
the frequency could be reduced.
Parameters
Oscillator frequency without
reduction
Changing of oscillator frequency
with FOSC reduction
Test Conditions/Pins
FAOS (0:2) = 0
FAOS2 FAOS1 FAOS0
0
0
1
0
1
0
1
0
0
1
0
1
Min.
Typ.
Max.
Unit
11.15
+∆
MHz
140
280
560
700
Hz
17
4516D–CT0–10/05
Figure 8-1.
Test Circuit
RFO
BZT55C51
56K
10N
VRF
MLF
100N
LFGND
MODIN
VDD
DATA
470N
MIX1IN1
VSS
CLOCK
MIX1O
OSCGND
10K
10N
MIX2O
MIX2O
MIX2IN
DATA
IFIN1
CLOCK
IFIN2
DACO
ETC
1500
470N
EIN
OPIN
RECO1
TXO
RECO2
LIMIN
RXO
COUT
DAIN
MIX2IN
10N
MIC
MICO
470N
CIN
23
10K
470N
MIX2GND
CTC
22
VAF
VAF
OPOUT
DACO
2
1
XCK
10N
470N
VRF
11.15M
470N
RFOVB
MPU serial
interface
MIX1IN2
0
RFOVB
VBIAS
330
1
1U
GNDLO
U3600BM
5.6K
MIX1O
44
1
MODIN
MIX1IN1
LO2
RFO
AGND
10N
10N
LO1
RFOGND
Loop Filter
MIX1IN2
5P
PCLO
TX-/Modulator-
10N
68N
24K
850
10N
IFIN1
10N
IFIN2
EIN
85
44K
220N
22UF
1000
4.7N
RECO1
RECO2
47N
47N
220N
RXO
NOTE:
18
MICIN
MICO
CIN
COUT
VDD
LIMIN
COUT
SPLAIN
OPOUT
DAIN
This schematics is only a basic(simplified) representation of the current production test circuit
U3600BM
4516D–CT0–10/05
4516D–CT0–10/05
TX
10n
56K
TXGND
24K
68n
RXGND
RX
100n
20
2.2K
1uH
10
+VB
1n
330
100n
Hand : 100nH
Base : 230nH
2x BZT55C51
5.6p
47p
47p
4
3
2
41
5
VCO2
+45
-45
39
6
38
:N
Phase
f Ref2
1u
5.6K
Comparator
Phase
:M12
:D1
Comparator
100n
8
:M12
:D2
35
:K
(3): PLL3: Local oscillator (LO) PLL
(2): PLL2: Mixer PLL
36
fRef3
Crystal
Oscillator
37
+VB
7
Loop
Filter
(3)
fLO
(2)
cos
MixerT
fLO
:2
fLO
Mixer1
sin
VCO3
40
(1): PLL1: Modulator PLL
1
1
44
43
42
11.15 MHz
9
VCO1
:2
33
4.7n
10
(1)
Mixer2
34
100n
390
10K
Comparator
Phase
: (PM + QM )
223
fMod
:D3
Bias
Bat low
Detector
Serial
Bus
100n
SFE
10.7 MS 2
11
fRef1
32
12
:2
:M
:10
-
31
5.6k
CFW
450 E
13 14
+
D
MUXDA
RSSI
A
IF - Amp
Expander
1n
15 16
15K
17
-
Spl Amp 1.5V
+
-
+
10K
18
Limiter
Compressor
+
Mic
24
25
26
27
28
12n
12K
19
20
21
22
23
VRMIC
1.5V
Ear Amp
-
Demodulator
29
DATRX
30
470n
470n
DACO
C
D
VDD
TX DATA
15n
470n
0.75n
22n
12K
100K
2.2n
4.7K
220n
22K
2.2K
20K
1K
15n
100n
56n
Electret
Microphone
22n
µC
8.2K
7.5K
220n
Figure 8-2.
100n
100n
+VB
U3600BM
Application Circuit
19
Duplex Filter
Antenna
9. Channel Frequencies, Dividers and Country Settings
To meet all requirements of various countries – France (F), Spain (E), Netherlands (NL), USA,
Portugal (P), Taiwan, New Zealand and Korea – and modes – base (b), handset (h) – several
bits have to be set which do not change for the different channels. These settings are called
country settings.
• The country-setting bits contain:
• Rough adjustments for 2 VCOs
• Setting three integer divider in the mixer PLL and modulator PLL
• Conversion gain adjustment of mixer PLL
• Modulator gain
• Setting of the pulling direction of PLL2 (value dependent, if TX frequency is higher or lower
than LO frequency)
• Demodulator gain
Name Register
Function
Notes
Number of
Positions
RA1[1:0]
Rough adjust VCO1
00: is the highest frequency
3
RA2[1:0]
Rough adjust VCO2
00: is the highest frequency
4
D1[1:0]
Integer divider D1
Division by 2, 4, 6, 8
4
D20
Integer divider D2
Division by 6, 8
2
Integer divider M12
Doubles reference frequency
of PLL2 when set to “1”
2
Division by 1, 2, 4
3
M12
Note:
20
D3[1:0]
Integer divider D3
KV[3:1]
Conversion gain VCO2
GMOD[1:0]
Modulator gain
00: gain minimal
3
IMIXI
Reverse inputs of PC of
PLL
0: if fVCO2 lower than fVCO3
2
DR1[1:0]
Additional divider M for
reference frequency fRef1
“0” means no reduction, >0
only necessary in E, NL,
Portugal
4
FRMT
Frequency range
Mixer T
0: output frequency < 5 MHz
2
GDEM
Demodulator gain
0: high gain
1: low gain
2
6
Setting the fractional dividers:
For N, QM, send the binary equivalent of the numbers given below.
For PM (integer part of modulator PLL), send the D2 complement (16 – PM)
i.e., Fb1 (PM = 7, QM = 159 => integer: send 16 – PM = 9, fractional: send 159)
U3600BM
4516D–CT0–10/05
U3600BM
10. Tables for Programming of the Dividers (Refer to Block Diagram)
Table 10-1.
Divider D1 for PLL2
D11 (bit)
D10 (bit)
Decimally
D1 (Block Diagram),if M12 = 0
D1 (Block Diagram),if M12 = 1
0
0
0
2
1
0
1
1
8
4
1
0
2
6
3
1
1
3
4
2
Table 10-2.
Divider D2 between PLL1 and PLL2
D20 (bit)
Decimally
D2 (Block Diagram),if M12 = 0
D2 (Block Diagram),if M12 = 1
0
0
6
3
0
1
8
4
Table 10-3.
Divider D3 for PLL1
D31 (bit)
D30 (bit)
Decimally
D3 (Block Diagram)
0
0
0
1
0
1
1
2
1
0
2
6
1
1
3
4
10.1
Divider M for Reference Frequency of PLL1
There are several countries like Spain, the Netherlands and Portugal with relatively low modulator frequencies fMod. In case of modulation there will be a big maximum time shift between
pulses coming from fractional divider and pulses coming from reference frequency divider. As a
consequence the phase comparator enters an undesired operation mode. To avoid entering this
operation mode the reference frequency fRef1 has to be reduced by a factor M. Simultaneously,
keeping fMod constant, the factors of fractional dividers have to be changed as well.
The connection between the additional reference frequency divider M and the factors PM and QM
of fractional divider is given below. The subscript M denotes which value of M refers to the factors PM and QM of fractional divider. The formulas take into account that the numerator of the
fraction QM/223 must not exceed 223.
PM = P1 × M + integer (Q × M/223)
QM = Q1 × M - 223 × integer (Q1 × M/223)
21
4516D–CT0–10/05
10.2
France Base
Table 10-4.
Name
RA1[1:0]
Setting
00
Value
Note:
Country Setting
max
RA2[1:0]
11
min
D1[1:0]
11
D1 = 4
D20
1
D2 = 8
D3[1:0]
KV2[3:1]
01
GMOD[1:0]
100
D3 = 2
01
(1)
IMIXI
DR1I[1:0]
FRMT
0
00
0
0
low
high
gain
supra
M=1
GDEM
Alternatively, GMOD[1:0] could be set to “00”. This reduces the TX conversion gain (MODIN –> RFO) from
about 3.8 kHz/V to about 2.7 kHz/V, a value, which should be still sufficient for a maximum ∆f of ∼2.5 kHz
that is useful in the French case.
Table 10-5.
Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel
(MHz)
Rx Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
26.3125
41.3125
30.6125
4898
2
26.3250
41.3250
30.6250
4900
3
26.3375
41.3375
30.6375
4902
4
26.3500
41.3500
30.6500
4904
5
26.3625
41.3625
30.6625
4906
6
26.3750
41.3750
30.6750
4908
7
26.3875
41.3875
30.6875
4910
8
26.400
41.4000
30.7000
4912
9
26.4125
41.4125
30.7125
4914
10
26.4250
41.4250
30.7250
4916
11
26.4375
41.4375
30.7375
4918
12
26.4500
41.4500
30.7500
4920
13
26.4625
41.4625
30.7625
4922
14
26.4750
41.4750
30.7750
4924
15
26.4875
41.4875
30.7875
4926
10.2.1
France Modulation Loop Frequency and Divider
fMod = 4.3 MHz, PM = 7, QM = 159, M = 1
22
U3600BM
4516D–CT0–10/05
U3600BM
10.3
France Hand
Table 10-6.
Name
RA1[1:0]
Setting
00
Value
Note:
Country Setting
max
RA2[1:0]
01
D1[1:0]
D20
11
D1 = 4
1
D2 = 8
D3[1:0]
KV2[3:1]
01
GMOD[1:0]
101
D3 = 2
01
(1)
IMIXI
DR1I[1:0]
FRMT
1
00
0
0
low
high
gain
infra
M=1
GDEM
Alternatively, GMOD[1:0] could be set to “00”. This reduces the TX conversion gain (MODIN –> RFO) from
about 3.8 kHz/V to about 2.7 kHz/V, a value, which should be still sufficient for a maximum ∆f of ∼2.5 kHz
that is useful in the French case.
Table 10-7.
Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
41.3125
26.3125
37.0125
5922
2
41.3250
26.3250
37.0250
5924
3
41.3375
26.3375
37.0375
5926
4
41.3500
26.3500
37.0500
5928
5
41.3625
26.3625
37.0625
5930
6
41.3750
26.3750
37.0750
5932
7
41.3875
26.3875
37.0875
5934
8
41.4000
26.4000
37.1000
5936
9
41.4125
26.4125
37.1125
5938
10
41.4250
26.4250
37.1250
5940
11
41.4375
26.4375
37.1375
5942
12
41.4500
26.4500
37.1500
5944
13
41.4625
26.4625
37.1625
5946
14
41.4750
26.4750
37.1750
5948
15
41.4875
26.4875
37.1875
5950
10.3.1
France Modulation Loop Frequency and Divider
fMod = 4.3 MHz, PM = 7, QM = 159, M = 1
23
4516D–CT0–10/05
10.4
Spain Base
Table 10-8.
Country Setting
Name
RA1[1:0]
RA2[1:0]
Setting
10
10
Value
Table 10-9.
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
001
10
00
1
11
D1 = 2
D2 = 8
D3 = 4
IMIXI
DR1I[1:0]
FRMT
GDEM
1
11
1
1
infra
M=4
high
low gain
Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
31.025
39.925
29.225
4676
2
31.050
39.950
29.250
4680
3
31.075
39.975
29.275
4684
4
31.100
40.000
29.300
4688
5
31.125
40.025
29.325
4692
6
31.150
40.050
29.350
4696
7
31.175
40.075
29.375
4700
8
31.200
40.100
29.400
4704
9
31.250
40.150
29.450
4712
10
31.275
40.175
29.475
4716
11
31.300
40.200
29.500
4720
12
31.325
40.225
29.525
4724
10.4.1
Spain Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.8 MHz/4,PM = 12,QM = 204, M = 4
24
U3600BM
4516D–CT0–10/05
U3600BM
10.5
Spain Hand
Table 10-10. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
100
01
00
1
11
high
D1 = 2
D2 = 8
D3 = 4
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
10
0
11
1
1
high
supra
M=4
high
low gain
Table 10-11. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
39.925
31.025
41.725
6676
2
39.950
31.050
41.750
6680
3
39.975
31.075
41.775
6684
4
40.000
31.100
41.800
6688
5
40.025
31.125
41.825
6692
6
40.050
31.150
41.850
6696
7
40.075
31.175
41.875
6700
8
40.100
31.200
41.900
6704
9
40.150
31.250
41.950
6712
10
40.175
31.275
41.975
6716
11
40.200
31.300
42.000
6720
12
40.225
31.325
42.025
6724
10.5.1
Spain Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.8 MHz/4,PM = 12,QM = 204, M = 4
25
4516D–CT0–10/05
10.6
Netherlands Base
Table 10-12. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
001
10
00
1
11
low
D1 = 2
D2 = 8
D3 = 4
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
10
1
11
1
1
high
infra
M=4
high
low gain
Table 10-13. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
31.0375
39.9375
29.2375
4678
2
31.0625
39.9625
29.2625
4682
3
31.0875
39.9875
29.2875
4686
4
31.1125
40.0125
29.3125
4690
5
31.1375
40.0375
29.3375
4694
6
31.1625
40.0625
29.3625
4698
7
31.1875
40.0875
29.3875
4702
8
31.2125
40.1125
29.4125
4706
9
31.2375
40.1375
29.4375
4710
10
31.2625
40.1625
29.4625
4714
11
31.2875
40.1875
29.4875
4718
12
31.3125
40.2125
29.5125
4722
10.6.1
Netherlands Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.8 MHz/4,PM = 12,QM = 204, M = 4
26
U3600BM
4516D–CT0–10/05
U3600BM
10.7
Netherlands Hand
Table 10-14. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
001
01
00
1
11
high
D1 = 2
D2 = 8
D3 = 4
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
10
0
11
1
1
high
supra
M=4
high
low gain
Table 10-15. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
39.9375
31.0375
41.7375
6678
2
39.9625
31.0625
41.7625
6682
3
39.9875
31.0875
41.7875
6686
4
40.0125
31.1125
41.8125
6690
5
40.0375
31.1375
41.8375
6694
6
40.0625
31.1625
41.8625
6698
7
40.0875
31.1875
41.8875
6702
8
40.1125
31.2125
41.9125
6706
9
40.1375
31.2375
41.9375
6710
10
40.1625
31.2625
41.9625
6714
11
40.1875
31.2875
41.9875
6718
12
40.2125
31.3125
42.0125
6722
10.7.1
Netherlands Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.8 MHz/4,PM = 12,QM = 204, M = 4
27
4516D–CT0–10/05
10.8
U.K. Base
Table 10-16. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
001
10
00
1
11
low
D1 = 2
D2 = 8
D3 = 4
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
10
1
11
1
1
high
infra
M=4
high
low gain
Table 10-17. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
31.0375
39.9375
29.2375
4678
2
31.0625
39.9625
29.2625
4682
3
31.0875
39.9875
29.2875
4686
4
31.1125
40.0125
29.3125
4690
10.8.1
U.K. Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.8 MHz/4,PM = 12,QM = 204, M = 4
10.9
U.K. Handset
Table 10-18. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
001
01
00
1
11
high
D1 = 2
D2 = 8
D3 = 4
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
10
0
11
1
1
high
supra
M=4
high
low gain
Table 10-19. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
39.9375
31.0375
41.7375
6678
2
39.9625
31.0625
41.7625
6682
3
39.9875
31.0875
41.7875
6686
4
40.0125
31.1125
41.8125
6690
10.9.1
U.K. Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.8 MHz/4,PM = 12,QM = 204, M = 4
28
U3600BM
4516D–CT0–10/05
U3600BM
10.10 USA Base
Table 10-20. Country Setting Channels (Channel 1 – 10, USA1)
Name
RA1[1:0]
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
Setting
10
00
01
1
00
100
00
1
00
1
1
max
D1 = 8
D2 = 8
D3 = 1
low
infra
M=1
high
low gain
Value
Table 10-21. Country Setting New Channels (Channel 11 – 25, USA2)
Name
RA1[1:0]
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
Setting
01
01
10
0
00
110
01
1
00
0
1
high
D1 = 6
D2 = &
D3 = 1
infra
M=1
low
low gain
Value
Table 10-22. Channel Frequencies and 1st LO Divider, fRef3 = 5 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
46.610
49.670
38.970
7794
2
46.630
49.845
39.145
7829
3
46.670
49.860
39.160
7832
4
46.710
49.770
39.070
7814
5
46.730
49.875
39.175
7835
6
46.770
49.830
39.130
7826
7
46.830
49.890
39.190
7838
8
46.870
49.930
39.230
7846
9
46.930
49.990
39.290
7858
10
46.970
49.970
39.270
7854
TX Channel Frequency
(MHz)
43.720
43.740
43.820
43.840
43.920
43.960
44.120
44.160
44.180
44.200
44.320
44.360
44.400
44.460
44.480
RX Channel Frequency
(MHz)
48.760
48.840
48.860
48.920
49.020
49.080
49.100
49.160
49.200
49.240
49.280
49.360
49.400
49.460
49.500
fLO = 1/2 fVCO3
(MHz)
38.06
38.14
38.16
38.22
38.32
38.38
38.40
38.46
38.50
38.54
38.58
38.66
38.70
38.76
38.80
DV3I[14:0] = N
7612
7628
7632
7644
7664
7676
7680
7692
7700
7708
7716
7732
7740
7752
7760
Table 10-23. New Channel
Channel
Number
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
29
4516D–CT0–10/05
10.11 USA Hand
Table 10-24. Country Setting Channels (Channel 1 – 10, USA1):
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
100
00
00
01
1
00
max
D1 = 8
D2 = 8
D3 = 1
IMIXI
DR1I[1:0]
FRMT
GDEM
0
00
1
1
supra
M=1
high
low gain
Table 10-25. Country Setting New Channels (Channel 11 – 25, USA2):
Name
RA1[1:0]
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
GDEM
Setting
01
00
10
0
00
110
01
0
00
0
1
high
D1 = 6
D2 = &
D3 = 1
supra
M=1
low
low gain
Value
Table 10-26. Channel Frequencies and 1st LO Divider, fRef3 = 5 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
49.670
46.610
57.31
11462
2
49.845
46.630
57.33
11466
3
49.860
46.670
57.37
11474
4
49.770
46.710
57.41
11482
5
49.875
46.730
57.43
11486
6
49.830
46.770
57.47
11494
7
49.890
46.830
57.53
11506
8
49.930
46.870
57.57
11514
9
49.990
46.930
57.63
11526
10
49.970
46.970
57.67
11534
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
11
48.760
43.720
54.42
10884
12
48.840
43.740
54.44
10888
13
48.860
43.820
54.52
10904
14
48.920
43.840
54.54
10908
15
49.020
43.920
54.62
10924
16
49.080
43.960
54.66
10932
17
49.100
44.120
54.82
10964
18
49.160
44.160
54.86
10972
19
49.200
44.180
54.88
10976
20
49.240
44.200
54.90
10980
21
49.260
44.320
55.02
11004
22
49.360
44.360
55.06
11012
23
49.400
44.400
55.10
11020
24
49.460
44.460
55.16
11032
25
49.500
44.480
55.18
11036
Table 10-27. New channel
30
U3600BM
4516D–CT0–10/05
U3600BM
Table 10-28. USA Modulation Loop Frequencies and Dividers
N Channel
PM
QM
fMod (MHz)
1
13
157
7.640
2
13
95
7.485
3
13
105
7.510
4
13
157
7.640
5
13
123
7.555
6
13
157
7.640
7
13
157
7.640
8
13
157
7.640
9
13
157
7.640
10
13
181
7.700
N Channel
PM
QM
fMod (MHz)
11
10
34
5.66
12
10
10
5.60
13
10
34
5.66
14
10
18
5.62
15
10
10
5.60
16
10
2
5.58
17
10
58
5.72
18
10
50
5.70
19
10
42
5.68
20
10
34
5.66
21
10
66
5.74
22
10
50
5.70
23
10
50
5.70
24
10
50
5.70
25
10
42
5.68
Table 10-29. New Channel
31
4516D–CT0–10/05
10.12 Portugal Base
Table 10-30. Country Setting
Name
RA1[1:0]
RA2[1:0]
Setting
01
10
Value
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
001
10
00
1
11
D1 = 2
D2 = 8
D3 = 4
IMIXI
DR1I[1:0]
FRMT
GDEM
1
11
1
1
infra
M=4
high
low gain
Table 10-31. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
27.550
37.000
26.300
4208
2
27.575
37.025
26.325
4212
3
27.600
37.050
26.350
4216
4
27.625
37.075
26.375
4220
5
27.650
37.100
26.400
4224
6
27.675
37.125
26.425
4228
7
27.700
37.150
26.450
4232
8
27.725
37.175
26.475
4236
9
27.750
37.200
26.500
4240
10
27.775
37.225
26.525
4244
11
27.800
37.250
26.550
4248
12
27.825
37.275
26.575
4252
10.12.1 Portugal Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.25 MHz/4,PM = 8,QM = 216, M = 4
32
U3600BM
4516D–CT0–10/05
U3600BM
10.13 Portugal Hand
Table 10-32. Country Setting
Name
RA1[1:0]
RA2[1:0]
Setting
01
01
Value
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
001
10
00
1
11
D1 = 2
D2 = 8
D3 = 4
IMIXI
DR1I[1:0]
FRMT
GDEM
0
11
1
1
supra
M=4
high
low gain
Table 10-33. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
37.000
27.550
38.250
6120
2
37.025
27.575
38.275
6124
3
37.050
27.600
38.300
6128
4
37.075
27.625
38.325
6132
5
37.100
27.650
38.350
6136
6
37.125
27.675
38.375
6140
7
37.150
27.700
38.400
6144
8
37.175
27.725
38.425
6148
9
37.200
27.750
38.450
6152
10
37.225
27.775
38.475
6156
11
37.250
27.800
38.500
6160
12
37.275
27.825
38.525
6164
10.13.1 Portugal Modulation Loop Frequency and Divider
fRef1 = 557.5 kHz/4, fMod = 1.25 MHz/4,PM = 8,QM = 216, M = 4
33
4516D–CT0–10/05
10.14 Taiwan Base
Table 10-34. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
110
01
00
01
1
00
max
D1 = 8
D2 = 8
D3 = 1
IMIXI
DR1I[1:0]
FRMT
GDEM
1
00
1
1
infra
M=1
high
low gain
Table 10-35. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
45.2500
48.2500
37.5500
6008
2
45.2750
48.2750
37.5750
6012
3
45.3000
48.3000
37.6000
6016
4
45.3250
48.3250
37.6250
6020
5
45.3500
48.3500
37.6500
6024
6
45.3750
48.3750
37.6750
6028
7
45.4000
48.4000
37.7000
6032
8
45.4250
48.4250
37.7250
6036
9
45.4500
48.4500
37.7500
6040
10
45.4750
48.4750
37.7750
6044
10.14.1 Taiwan Modulation Loop Frequency and Divider
fMod = 7.7 MHz, PM = 13,QM = 181, M = 1
34
U3600BM
4516D–CT0–10/05
U3600BM
10.15 Taiwan Hand
Table 10-36. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
110
00
00
01
1
00
max
D1 = 8
D2 = 8
D3 = 1
IMIXI
DR1I[1:0]
FRMT
GDEM
0
00
1
1
supra
M=1
high
low gain
Table 10-37. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
48.2500
45.2500
55.9500
8952
2
48.2750
45.2750
55.9750
8956
3
48.3000
45.3000
56.0000
8960
4
48.3250
45.3250
56.0250
8964
5
48.3500
45.3500
56.0500
8968
6
48.3750
45.3750
56.0750
8972
7
48.4000
45.4000
56.1000
8976
8
48.4250
45.4250
56.1250
8980
9
48.4500
45.4500
56.1500
8984
10
48.4750
45.4750
56.1750
8988
10.15.1 Taiwan Modulation Loop Frequency and Divider
fMod = 7.7 MHz, PM = 13,QM = 181, M = 1
35
4516D–CT0–10/05
10.16 China Base
Table 10-38. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
110
01
00
01
1
00
max
D1 = 8
D2 = 8
D3 = 1
IMIXI
DR1I[1:0]
FRMT
GDEM
1
00
1
1
infra
M=1
high
low gain
Table 10-39. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
45.0000
48.0000
37.3000
5968
2
45.0250
48.0250
37.3250
5972
3
45.0500
48.0500
37.3500
5976
4
45.0750
48.0750
37.3750
5980
5
45.1000
48.1000
37.4000
5984
6
45.1250
48.1250
37.4250
5988
7
45.1500
48.1500
37.4500
5992
8
45.1750
48.1750
37.4750
5996
9
45.2000
48.2000
37.5000
6000
10
45.2250
48.2250
37.5250
6004
11
45.2500
48.2500
37.5500
6008
12
45.2750
48.2750
37.5750
6012
13
45.3000
48.3000
37.6000
6016
14
45.3250
48.3250
37.6250
6020
15
45.3500
48.3500
37.6500
6024
16
45.3750
48.3750
37.6750
6028
17
45.4000
48.4000
37.7000
6032
18
45.4250
48.4250
37.7250
6036
19
45.4500
48.4500
37.7500
6040
20
45.4750
48.4750
37.7750
6044
10.16.1 China Modulation Loop Frequency and Divider
fMod = 7.7 MHz, PM = 13,QM = 181, M = 1
36
U3600BM
4516D–CT0–10/05
U3600BM
10.17 China Hand
Table 10-40. Country Setting
Name
RA1[1:0]
Setting
10
Value
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
110
00
00
01
1
00
max
D1 = 8
D2 = 8
D3 = 1
IMIXI
DR1I[1:0]
FRMT
GDEM
0
00
1
1
supra
M=1
high
low gain
Table 10-41. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
48.000
45.0000
55.7000
8912
2
48.0250
45.0250
55.7250
8916
3
48.0500
450500
55.7500
8920
4
48.0750
450750
55.7750
8924
5
48.1000
45.1000
55.8000
8928
6
48.1250
45.1250
55.8250
8932
7
48.1500
45.1500
55.8500
8936
8
48.1750
45.1750
55.8750
8940
9
48.2000
45.2000
55.9000
8944
10
48.2250
45.2250
55.9250
8948
11
48.2500
45.2500
55.9500
8952
12
48.2750
45.2750
55.9750
8956
13
48.3000
45.3000
56.0000
8960
14
48.3250
45.3250
56.0250
8964
15
48.3500
45.3500
56.0500
8968
16
48.3750
45.3750
56.0750
8972
17
48.4000
45.4000
56.1000
8976
18
48.4250
45.4250
56.1250
8980
19
48.4500
45.4500
56.1500
8984
20
48.4750
45.4750
56.1750
8988
10.17.1 China Modulation Loop Frequency and Divider
fMod = 7.7 MHz, PM = 13,QM = 181, M = 1
37
4516D–CT0–10/05
10.18 New Zealand Base
Table 10-42. Country Setting
Name
RA1[1:0]
RA2[1:0]
Setting
00
01
Value
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
110
01
11
1
01
D1 = 4
D2 = 8
D3 = 2
IMIXI
DR1I[1:0]
FRMT
GDEM
1
00
0
1
infra
M=1
low
low gain
Table 10-43. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
11
34.2500
40.2500
29.5500
4728
12
34.2750
40.2750
29.5750
4732
13
34.3000
40.3000
29.6000
4736
14
34.3250
40.3250
29.6250
4740
15
34.3500
40.3500
29.6500
4744
16
34.3750
40.3750
29.6750
4748
17
34.4000
40.4000
29.7000
4752
18
34.4250
40.4250
29.7250
4756
19
34.4500
40.4500
29.7500
4760
20
34.4750
40.4750
29.7750
4764
10.18.1 New Zealand Modulation Loop Frequency and Divider
fMod = 4.7 MHz/4, PM = 8,QM = 96, M = 1
38
U3600BM
4516D–CT0–10/05
U3600BM
10.19 New Zealand Hand
Table 10-44. Country Setting
Name
RA1[1:0]
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
101
01
Setting
00
01
11
1
01
Value
max
min
D1 = 4
D2 = 8
D3 = 2
IMIXI
DR1I[1:0]
FRMT
GDEM
0
00
0
1
supra
M=1
low
low gain
Table 10-45. Channel Frequencies and 1st LO Divider, fRef3 = 6.25 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
11
40.2500
34.2500
44.9500
7192
12
40.2750
34.2750
44.9750
7196
13
40.3000
34.3000
45.0000
7200
14
40.3250
34.3250
45.0250
7204
15
40.3500
34.3500
45.0500
7208
16
40.3750
34.3750
45.0750
7212
17
40.4000
34.4000
45.1000
7216
18
40.4250
34.4250
45.1250
7220
19
40.4500
34.4500
45.1500
7224
20
40.4750
34.4750
45.1750
7228
10.19.1 New Zealand Modulation Loop Frequency and Divider
fMod = 4.7 MHz/4, PM = 8,QM = 96, M = 1
39
4516D–CT0–10/05
10.20 Korea Base
Table 10-46. Country Setting
Name
RA1[1:0]
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
Setting
10
00
01
1
00
100
00
1
00
1
1
high
high
gain
Value
max
D1 = 8
D2 = 8
D3 = 1
infra
M=1
GDEM
Table 10-47. Channel Frequencies and 1st LO Divider, fRef3 = 5 kHz
40
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
46.6100
49.6700
38.9700
7794
2
46.6300
49.8450
39.1450
7829
3
46.6700
49.8600
39.1600
7832
4
46.7100
49.7700
39.0700
7814
5
46.7300
49.8750
39.1750
7835
6
46.7700
49.8300
39.1300
7826
7
46.8300
49.8900
39.1900
7838
8
46.8700
49.9300
39.2300
7846
9
46.9300
49.9900
39.2900
7858
10
46.9700
49.9700
39.2700
7854
11
46.5100
49.6950
39.9950
7799
12
46.5300
49.7100
39.0100
7802
13
46.5500
49.7250
39.0250
7805
14
46.5700
49.7400
39.0400
7808
15
46.5900
49.7550
39.0550
7811
U3600BM
4516D–CT0–10/05
U3600BM
10.21 Korea Hand
Table 10-48. Country Setting
Name
RA1[1:0]
RA2[1:0]
D1[1:0]
D20
D3[1:0]
KV2[3:1]
GMOD[1:0]
IMIXI
DR1I[1:0]
FRMT
Setting
10
00
01
1
00
100
00
0
00
1
1
high
high
gain
Value
max
D1 = 8
D2 = 8
D3 = 1
supra
M=1
GDEM
Table 10-49. Channel Frequencies and 1st LO Divider, fRef3 = 5 kHz
Channel
Number
TX Channel Frequency
(MHz)
RX Channel Frequency
(MHz)
fLO = 1/2 fVCO3
(MHz)
DV3I[14:0] = N
1
49.6700
46.6100
57.3100
11462
2
49.8450
46.6300
57.3300
11466
3
49.8600
46.6700
57.3700
11474
4
49.7700
46.7100
57.4100
11482
5
49.8750
46.7300
57.4300
11486
6
49.8300
46.7700
57.4700
11494
7
49.8900
46.8300
57.5300
11506
8
49.9300
46.8700
57.5700
11514
9
49.9900
46.9300
57.6300
11526
10
49.9700
46.9700
57.6700
11534
11
49.6950
46.5100
57.2100
11442
12
49.7100
46.5300
57.2300
11446
13
49.7250
46.5500
57.2500
11450
14
49.7400
46.5700
57.2700
11454
15
49.7550
46.5900
57.2900
11458
41
4516D–CT0–10/05
Table 10-50. Korea Modulation Loop Frequencies and Dividers
N Channel
PM
QM
fMod (MHz)
1
13
157
7.640
2
13
95
7.485
3
13
105
7.510
4
13
157
7.640
5
13
123
7.555
6
13
157
7.640
7
13
157
7.640
8
13
157
7.640
9
13
157
7.640
10
13
181
7.700
11
13
107
7.515
12
13
109
7.520
13
13
111
7.525
14
13
113
7.530
15
13
115
7.535
Table 10-51. Crystal Specifications
Drive level < 0.01 µW
Parameters
Symbol
Min.
Load resonance frequency with 14 pF load capacitance
Load capacitance
Frequency tolerance
–30
Shunt capacitance
Motional capacitance
Series resistance
Note:
42
Typ.
Max.
Unit
11.15
MHz
14
pF
+30
ppm
3.1
pF
fF (1)
9.2
20
Ω
(1) Necessary to stay within adjustment range of oscillator FAOS (0:2) = 0 ... 5
U3600BM
4516D–CT0–10/05
U3600BM
11. Ordering Information
Extended Type Number
Package
Remarks
U3600BM-NFNY
SSO44
Tube, Pb-free
U3600BM-NFNG3Y
SSO44
Taped and reeled, Pb-free
12. Package Information
9.15
8.65
Package SSO44
Dimensions in mm
18.05
17.80
7.50
7.30
2.35
0.3
0.25
0.10
0.8
16.8
44
0.25
10.50
10.20
23
technical drawings
according to DIN
specifications
1
22
43
4516D–CT0–10/05
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