HOLTEK HT9015

HT9015
Preliminary
RF Single Chip for Cordless Phone
Features
·
·
·
·
Operating voltage: 2.7V~6V
Extremely low power consumption current
- I
CC= 0mA (typ.) in battery-saving mode
- I
CC= 8.5mA (typ.) in standby mode
- I
CC= 13.5mA (typ.) for communication
Built-in IF decoder, compander and PLL
IF decoder
- 1st/2nd Mixers, RX VCO
- RSSI quadrature detector, IF AMP
- Noise detector
·
·
·
Compander
- Expander, Compressor, Limiter
- Receive AMP, MIC AMP, PRE AMP
PLL
- RX PLL, TX PLL
- Local oscillator
- Data latch control
- Unlock detector
Four threshold variable battery alarms
General Description
nal strength and built-in noise detector for S/N
quality.
The HT9015 is an RF single chip for cordless
phone systems. Internally these are three major
parts, a PLL, an IF decoder and a compander.
The compander provides better S/N ratio for
audio signal processing.
The PLL provides radio channel selection for
either the transmitter or receiver. Frequency
locking status of the selected channel can be
monitored by a control register.
The HT9015 has a wide-range applications in
FM/FSK, Transmitting/Receiving of VHF
bandwidth including cordless phone, narrow
band voice and data transceiver systems.
The IF decoder provides two frequency down
converters that let high frequency signals pass
through a mixer and local oscillator to be lowered for frequency even base band signals. It
also provides an RSSI (receiver signal strength
indicator) function to detect the IF output sig-
The most significant advantage of the HT9015
is in the reduction of many external components making it well suited for cordless phone
baseset, handset radio section.
1
April 10, 2000
Preliminary
HT9015
Block Diagram
G N D 2
T X _ O U T
R X _ O U T
4
5
C _ R E C T
3
V C O _ C O N T
V C O 2 V C O 1
2
1
4 7
4 8
V C C 2
1 S T M IX _ IN
4 6
4 5
4 4
V C C 3
L O 1
L O 2
S IG _ O U T
C L K
D A T A
S T B
T X
P L L
6
T X _ IN
R X
P L L
R X
V C O
1 s t
M ix e r
R e g u la to r
7
8
L O
O S C
9
2 n d
M ix e r
4 3
E _ R E C T
4 1
2 N D M IX _ IN
4 0
N _ R E C
1 0
3 9
1 1
D a ta L a tc h
C o n tro l
1 2
1 3
3 8
L o w B A T
A la r m
1 4
IF
A M P
L P F
F IL _ IN
C O M P _ O U T
C _ N F
M IC _ O U T
R S S I
L im ite r
C o m p re s s o r
Q u a d
D e te c to r
C _ M U T E
1 6
2 N D M IX _ O U T
V C C 1
IF _ IN
3 6
D E C
3 5
G N D 1
3 4
1 5
3 3
IF _ O U T
Q U A D
E x p a n d e r
1 7
L P F
E _ M U T E
3 2
A F _ O U T
1 8
3 1
C o m p a ra to r
P R E
A M P
M IC
A M P
N o is e
F ilte r
R e c e iv e r
A M P
3 0
M IC _ IN
1 S T M IX _ O U T
4 2
3 7
F IL _ O U T
V R E F
N _ F IL _ O U T
N _ F IL _ IN
1 9
D a ta
C o m p
2 0
P R E _ IN
2 1
2 2
2 3
P R E _ O U T E X P _ O U T R E C E _ IN
2 4
R O 1
2 5
R O 2
2
2 6
B A T _ A L M
2 7
2 8
R S S I D _ C O M P _ O U T
2 9
D _ C O M P _ IN
April 10, 2000
Preliminary
HT9015
Pin Assignment
V C O 2
1
4 8
V C O 1
C _ R E C T
2
4 7
V C O _ C O N T
R X _ O U T
3
4 6
V C C 2
T X _ O U T
4
4 5
1 S T M IX IN
G N D 2
5
4 4
V R E F
T X _ IN
6
4 3
1 S T M IX O U T
V C C 3
7
4 2
E _ R E C T
L O 1
8
4 1
2 N D M IX IN
L O 2
9
4 0
N _ R E C
S IG _ O U T
1 0
3 9
2 N D M IX O U T
C L K
1 1
3 8
V C C 1
D A T A
1 2
3 7
IF _ IN
S T B
1 3
3 6
D E C
F IL _ O U T
1 4
3 5
G N D 1
F IL _ IN
1 5
3 4
IF _ O U T
C O M P _ O U T
1 6
3 3
Q U A D
C _ N F
1 7
3 2
A F _ O U T
M IC _ O U T
1 8
3 1
N _ F IL _ O U T
M IC _ IN
1 9
3 0
N _ F IL _ IN
P R E _ IN
2 0
2 9
D _ C O M P _ IN
P R E _ O U T
2 1
2 8
D _ C O M P _ O U T
E X P _ O U T
2 2
2 7
R S S I
R E C E _ IN
2 3
2 6
B A T _ A L M
R O 1
2 4
2 5
R O 2
H T 9 0 1 5
4 8 S S O P
Pin Description
Pin No.
Pin Name
I/O
Description
1
VCO2
I
Connects LC network with VCO1 pin to provide the tank circuit
for the received voltage control oscillator
2
C_RECT
¾
Normally connected to ground through a capacitor.
3
RX_OUT
O
Receiver phase detector output. The PDT of RX-PLL detects
phase errors from the received PLL. The output is connected to
external low pass filter.
4
TX_OUT
O
Transmitter phase detector output. The PDT of TX-PLL detects
phase errors from the transmitted PLL. The output is connected
to an external low pass filter.
5
GND2
¾
Digital ground
6
TX_IN
I
14-bit programmable transmit counter input. The output signal
from the external VCO circuit can be AC coupled to this pin.
3
April 10, 2000
Preliminary
Pin No.
Pin Name
I/O
HT9015
Description
7
VCC3
¾
Positive power supply for digital block circuits.
8
LO1
I
This pin connects to LO2 pin with external crystal and capacitor.
9
LO2
O
This output pin generates a reference frequency used for the
PLL and the second mixer local oscillator when connected to
LO1 pin with an external crystal and capacitor.
10
SIG_OUT
O
This pin outputs four-type states and is selected by an internal
control register. There are RSSI state and noise state and RX/TX
PLL lock states.
Open drain output.
11
CLK
I
Clock input pin
12
DATA
I
Serial data input pin
13
STB
I
Data strobe control pin
14
FIL_OUT
O
Splatter filter output pin
15
FIL_IN
I
Splatter filter input pin
16
COMP_OUT
O
Compressor output pin
17
C_NF
¾
Normally connected to ground through a capacitor.
18
MIC_OUT
O
Microphone amplifier output pin
19
MIC_IN
I
Microphone amplifier input pin
20
PRE_IN
I
Pre-amplifier input pin
21
PRE_OUT
O
Pre-amplifier output pin
22
EXP_OUT
O
Expander output pin
23
RECE_IN
I
Receiver amplifier input pin
24
RO1
O
Receiver amplifier output pin
25
RO2
O
Receiver amplifier output pin
26
BAT_ALM
O
Battery alarm output pin. When the battery voltage is lower
than the internal setting threshold this pin is active.
Open drain output.
27
RSSI
O
Receiver signal strength indicator output pin, the output signal
depends on the IF amplifier output signal.
28
D_COMP_OUT
O
Data comparator output pin
29
D_COMP_IN
I
Data comparator input pin. Input to comparator to distinguish
digital data from audio.
30
N_FIL_IN
I
Input to noise filter
31
N_FIL_OUT
O
Output from noise filter
4
April 10, 2000
Preliminary
Pin No.
Pin Name
I/O
Description
HT9015
32
AF_OUT
O
FM demodulator output pin. Output signal frequency is within
the audio band.
33
QUAD
I
Normally provides a 455kHz carry frequency for the FM quadrature detector.
34
IF_OUT
O
IF amplifier output pin. Signal will later pass through external
90°C phase shifter for quadrature detector.
35
GND1
¾
Analog ground
36
DEC
¾
Normally connected to VCC1 through a capacitor.
37
IF_IN
I
IF amplifier input pin it is necessary to use the IF filter network
to get high quality IF signal.
38
VCC1
¾
Analog power supply
39
2NDMIX_OUT
O
Second mixer IF signal output pin and down converter. IF frequency is 455kHz.
40
N_REC
¾
Connect to ground through capacitor.
41
2NDMIX_IN
I
Second mixer RF signal input pin and down converter. Frequency is 455kHz.
42
E_RECT
¾
Expander rectifier filter capacitor pin.
43
1STMIX_OUT
O
First mixer IF signal output pin and down converter. IF frequency is 10.7MHz.
44
VREF
O
Reference voltage input for compander.
45
1STMIX_IN
I
The first mixer RF signal input. Carrier frequency from
20~60MHz.
46
VCC2
¾
Directly connects to the two voltage regulators inside.
47
VCO_CONT
I
Normally connected to ground through a capacitor.
48
VCO1
I
Connects LC network with VCO2 pin to provide the tank circuit
for the received voltage control oscillator.
Absolute Maximum Ratings
Supply Voltage...........................VSS-0.3V to 6V
Storage Temperature.................-55°C to 150°C
Input Voltage .................VSS-0.3V to VCC+0.3V
Operating Temperature ..............-20°C to 70°C
Note: These are stress ratings only. Stresses exceeding the range specified under ²Absolute Maximum Ratings² may cause substantial damage to the device. Functional operation of this device
at other conditions beyond those listed in the specification is not implied and prolonged exposure to extreme conditions may affect device reliability.
5
April 10, 2000
Preliminary
HT9015
Electrical Characteristics
Symbol
Parameter
Ta=25°C
Test Conditions
Conditions
VCC
VCC1=VCC3
Min.
Typ.
Max.
Unit
¾
3.6
¾
V
VCC
Operating Voltage
ICC1
Current 1 Consumption
3.6V All on
¾
13.5
¾
mA
ICC2
Current 2 Consumption
3.6V RX-RF ON
¾
8.5
¾
mA
ICC3
Current 3 Consumption
3.6V RX-AF ON
¾
3.5
¾
mA
ICC4
Current 4 Consumption
3.6V TX-RF ON
¾
2.1
¾
mA
ICC5
Current 5 Consumption
3.6V TX-AF ON
¾
1.7
¾
mA
ICC(A)
Current Alarm Supply
3.6V RL= 100kW
¾
100
¾
mA
ICC(BS)
Supply Current in Battery
Saving Mode
3.6V All off
¾
0
¾
mA
IREF
VREF Voltage
3.6V
¾
¾
1.5
¾
V
VIH
Data Input Threshold
3.6V
¾
¾
VCC3
¾
V
VIL
Data Input Threshold
3.6V
¾
¾
0
¾
V
IIH
Data Input Current
3.6V VIH= VCC
¾
0
¾
mA
IIL
Data Input Current
3.6V VIL= GND
¾
0
¾
mA
fCK
CK Input Frequency
3.6V
¾
38
1000
kHz
¾
¾
Regulator
Symbol
Ta=25°C
Parameter
Test Conditions
VCC
Conditions
VREG
Output Voltage
3.6V IOUT= 1mA
IOUT (MIN)
Minimum Load Current
3.6V
VOUT= VREG
(Open)-0.05V
Min.
Typ.
Max. Unit
1.7
2
2.3
V
¾
3
¾
mA
Detector
Symbol
Ta=25°C
Parameter
Test Conditions
VCC
Conditions
Min.
Typ.
Max.
Unit
VBAT-L
Detection Voltage 1
3.6V
¾
¾
3.3
¾
V
VBAT-H
Detection Voltage 1
3.6V
¾
¾
3.37
¾
V
VBAT-L
Detection Voltage 2
3.6V
¾
¾
3.15
¾
V
VBAT-H
Detection Voltage 2
3.6V
¾
¾
3.2
¾
V
6
April 10, 2000
Preliminary
Symbol
Parameter
Test Conditions
VCC
Conditions
HT9015
Min.
Typ.
Max.
Unit
VBAT-L
Detection Voltage 3
3.6V
¾
¾
3.05
¾
V
VBAT-H
Detection Voltage 3
3.6V
¾
¾
3.10
¾
V
VBAT-L
Detection Voltage 4
3.6V
¾
¾
2.78
¾
V
VBAT-H
Detection Voltage 4
3.6V
¾
¾
2.82
¾
V
VOL
Output Low Level Voltage
3.6V ISINK= 0.1mA
¾
0.1
¾
V
ILEAK
Output Leak Current
3.6V VALM= 3.6V
¾
0
¾
mA
VTH
Minimum Detection Level
3.6V f= 500Hz
¾
¾
¾
mVrms
VOL
Output Low Level Voltage
3.6V ISINK= 0.2mA
¾
0.1
¾
V
ILEAK
Output Leak Current
3.6V VDATA= 3.6V
¾
0
¾
mA
VTH-H
Noise Detection Level
3.6V
¾
¾
0.57
¾
V
VTH-L
Noise Detection Level
3.6V
¾
¾
0.47
¾
V
VOL
Noise Detection Level
Voltage
3.6V ISINK= 0.2mA
¾
0.1
¾
V
ILEAK
Output Leak Current
3.6V VSIG= 3.6V
¾
0
¾
mA
VTH-L
RSSI Comparator
Detection Voltage
3.6V
Comparator
Output L ® H
¾
0.72
¾
V
VTH-H
RSSI Comparator
Detection Voltage
3.6V
Comparator
Output H ® L
¾
0.8
¾
V
VHYS
RSSI Comparator Hysteresis
3.6V
¾
¾
0.08
¾
V
PLL Detection
Symbol
dBmV=dBmV EMF (Open), Ta=25°C
Parameter
Test Conditions
VCC
Conditions
Min.
Typ. Max. Unit
fIN
Operating Frequency
3.6V
¾
¾
46.61
¾
MHz
VIN
TX-PLL Input Sensitivity
3.6V
¾
¾
103
¾
dBmV
VLO
Local Oscillator Input
Sensitivity
3.6V fLO= 10.240MHz
¾
110
¾
dBmV
ICP1
Charge Pump Output Current
3.6V VCP= 1.8V
¾
200
¾
mA
ICP2
Charge Pump Output Current
3.6V VCP= 1.8V
¾
400
¾
mA
ILEAK
Charge Pump Leak Current
3.6V
¾
0
¾
mA
fLO
Local Oscillator Operating
Frequency
3.6V VLO= 112dBmV
¾
10.24
¾
MHz
7
¾
April 10, 2000
Preliminary
HT9015
RX-VCO IF + MIX section
fIN (MIX 1)=46.61MHz, fIN (IF)=455kHz, Df=3kHz fm= 1kHz, dBmV=dBmV EMF (Open), Ta=25°C
Symbol
Parameter
Test Conditions
VCC
Conditions
3.6V
¾
KV
Conversion Gain
VVCO
RX VCO Oscillation Level 3.6V fVCO= 25~55MHz
Min.
Typ.
Max.
Unit
¾
1
¾
MHz/V
¾
110
¾
dBmV
1st and 2nd Mixer, IF AMP
Symbol
Parameter
Ta=25°C
Test Conditions
VCC
Conditions
Min.
Typ. Max.
Unit
12dB
SINAD
12dB SINAD Sensitivity 3.6V Input 50W
¾
20
¾
dBmV
fMIX1
Mixer Operating
Frequency
3.6V 1STMIXER
¾
46.61
¾
MHz
fMIX2
Mixer Operating
Frequency
3.6V 2NDMIXER
¾
10.7
¾
MHz
GVC
Conversion Gain
3.6V Excluding Filter Loss
¾
26
¾
dB
GIF
IF AMP Gain
3.6V
¾
75
¾
dB
VOD
Demodulated Output
3.6V VIN (MIX 1)= 70dBmV
¾
220
¾
mVrms
S/N
S/N Ratio
3.6V VIN (MIX 1)= 70dBmV
¾
55
¾
dB
AMR
AM Rejection Ratio
3.6V VIN (MIX 1)= 70dBmV
¾
40
¾
dB
RIN1
Input Impedance
3.6V 1st MIX IN
¾
2.1
¾
kW
CIN1
Input Impedance
3.6V 1st MIX IN
¾
3.5
¾
pF
RIN2
Input Impedance
3.6V 2nd MIX IN
¾
5.8
¾
kW
CIN12
Input Impedance
3.6V 2nd MIX IN
¾
2.5
¾
pF
RIN
Input Resistance
3.6V IF IN
¾
1.5
¾
kW
RO1
Output Resistance
3.6V 1st MIX OUT
¾
330
¾
W
RO2
Output Resistance
3.6V 2nd MIX OUT
¾
1.5
¾
kW
VRSSI1
RSSI Output Voltage
3.6V VIN (MIX 1)= 20dBmV
¾
1
¾
V
VRSSI2
RSSI Output Voltage
3.6V VIN (MIX 1)= 60dBmV
¾
2.4
¾
V
¾
8
April 10, 2000
Preliminary
HT9015
Compressor + MIC AMP
Symbol
Parameter
fIN=1kHz, Ta=25°C
Test Conditions
Conditions
VCC
Min.
Typ. Max. Unit
Vrefc
Input Reference Level
3.6V VOM=-10dBV
-10.5
dBV
VOC
Output Deviation
3.6V VOM=-30dBV
-0.2
dB
V4
MIC AMP Voltage Gain
3.6V
tHDC
¾
20
Total Harmonic Distortion 3.6V VOM=-10dBV
¾
0.3
%
VNOC
Output Noise Level
3.6V Input-GND Short
¾
-61
dBV
Vlim1
Limiting Level
3.6V COMP Out, VIM= 0dBV
¾
1.3
¾
VP-P
Vlim2
Limiting Level
3.6V MIC Out, VIM= 0dBV
¾
2.6
¾
VP-P
VMUTE
Mute Output Level
3.6V
¾
-96
¾
dBV
¾
Expander + PRE AMP + Receiver AMP
Symbol
Parameter
dB
Ta=25°C
Test Conditions
VCC
Conditions
Min.
Typ. Max. Unit
VrefE
Input Reference Level
3.6V VOP=-10dBV
¾
-10
¾
dBV
VOE
Output Deviation
3.6V VOP=-35dBV
¾
0.5
¾
dB
GP3
PRE AMP Voltage Gain
3.6V
¾
0
¾
dB
THD1
Total Harmonic Distortion 3.6V
¾
0.5
¾
%
VMUTE
Mute Output Level
3.6V
¾
¾
-76
¾
dBV
GRNG2
PRE AMP Voltage Gain
Setting Range
3.6V
¾
¾
0
¾
dB
GRNG1
Receiver AMP Voltage
Gain Setting Range
3.6V
¾
¾
6
¾
dB
CTCE
Crosstalk CE
3.6V VIM=-20dBV
¾
-95
¾
dB
GS
Voltage Gain
3.6V
¾
0
¾
dB
DRS
Maximum Output Level
3.6V THD= 3%
¾
3
¾
VP-P
¾
RL= 150W
VRI=-15dBV
9
April 10, 2000
Preliminary
HT9015
Functional Description
in the shift register is sent into the latch to control the block, see the input timing for serial
data as shown below.
The HT9015 is a signal chip RF IC for cordless
phone applications. It has applications for
46/49MHz cordless phones as well as CT0 cordless phones that have frequency bands between
20MHz and 60MHz. This chip enables external
components in the base set and hand set radio
section application circuits to be reduced.
Serial data format of four registers
According to previous input timing Specs, the
HT9015 can be easily set up using four registers. The TX divider determines the TX PLL
locked frequency; the RX divider determines
the RX PLL locked frequency; the REF divider
determines the TX and RX PLL frequency reference which is also called channel space. The
control register is an important unit which controls the radio link, voice control and power saving during base set and hand set
communication.
The HT9015 is manufactured or a special process called BiCMOS, or bipolar process and
CMOS process. Because the RF and IF parts
need high frequency actions such as mixer,
VCO, IF amplifier and demodulator, those
parts are implemented in high performance bipolar circuits. The other digital functions are
designed using CMOS circuits. Sometimes this
chip is known as ²COMBO², the meaning of
COMBO is one chip combined with RF, IF and
PLL parts.
All data format contains 20 bits, but some registers need only 16 bits, They have a common
field of 20 bits data format called ²code² which
determine what data belongs to whom. See the
table below.
The HT9015 provides data latch interface controlled by a microcontroller. There are four internal registers inside the HT9015; TX
(transmitter) divider, RX (receiver) Divider,
REF (reference) divider and Control Register.
All registers can be set through the data latch
control interface. The data latch control interface contains DATA, CLK and STB control signals.
Code
Input timing for serial data
1
1
REF register
1
0
TX register
0
1
RX register
0
0
Control register
Data is read on the timing of the rising edge of
CLK. When STB receives a high signal, DATA
³ 1 m s
C L K
Register
Four register selection
³ 0 .2 m s
³ 0 .2 m s
³ 0 .2 m s
D A T A
³ 0 .1 m s
³ 0 .1 m s
³ 0 .2 m s
S T B
³ 0 .2 m s
O p e r a tio n
S ta te
P r e v io u s S ta te
N e w
S ta te
Figure 1 Input timing for serial data
10
April 10, 2000
Preliminary
HT9015
· REF register
Divide number range is from 5 to 4095.
This register includes TEST bits which must be set to 0.
D o n 't C a r e T e s t
0
R 0
B C
R 1
R 2
1 2 - b it R
C o u n te r
R 4
R 6
R 3
R 5
R 7
C o d e
R 8
R 9
R 1 0
R 1 1
1
1
1 s t
S T B
Divide number:
2
3
11
R= R0 + R1 ´ 2 + R2 ´ 2 + R3 ´ 2 + ¼ + R11 ´ 2
BC bit is BATTERY ALARM detection setting.
· TX register
Divide number range is from 5 to 16383.
D o n 't C a r e
1 4 - b it N
N 0
N 1
N 2
N 3
N 4
N 5
N 6
S
C o d e
C o u n te r
N 7
N 8
N 9
N 1 0
N 1 1
N 1 2
N 1 3
1
1 s t
0
S T B
Divide number:
2
3
N= N0 + N1 ´ 2 + N2 ´ 2 + N3 ´ 2 + ¼ + N12 ´ 2
12
+ N13 ´ 2
13
· RX register
Divide number range is from 5 to 16383.
D o n 't C a r e
1 4 - b it N
N 0
N 1
N 2
N 3
N 4
N 5
N 6
C o d e
C o u n te r
N 7
N 8
N 9
N 1 0
N 1 1
N 1 2
N 1 3
1 s t
0
1
S T B
Divide number:
2
3
12
N= N0 + N1 ´ 2 + N2 ´ 2 + N3 ´ 2 + ¼ + N12 ´ 2
13
+ N13 ´ 2
· Control register
This register includes battery saving control for the TX/RX circuits or MUTE controls for the commander block or changing threshold level for the battery alarm.
D o n 't C a r e
S IG
T X L D
1 s t
R X L D
O U T
R S S I
T X
N D
L D , R S S I, N D S e le c tio n
R F
B a tte ry
S a v in g
A F
R X
C P
M U T E
C h a rg e C O M P
P u m p
M U T E
C u rre n t
11
R F
A F
B a tte ry
S a v in g
B A T
C P
M U T E
C h a rg e E X P
P u m p
M U T E
C u rre n t
B A 1
C o d e
B A 2
B A T T E R Y
A L A R M
T h r e s h o ld
0
0
S T B
April 10, 2000
Preliminary
HT9015
¨ Battery saving control
0 ¼¼¼¼Operation
1 ¼¼¼¼Battery saving
Bit
Control Block
TX-RF
TX-PLL
TX-RF= 1 and
RX-RF= 1
LOCAL OSC= OFF
TX-AF
MIC AMP, Compressor, Splatter
RX-RF
RX-VCO, RX-PLL, 1st MIX, 2nd MIX IF AMP, NOISE DET,
DATA COMP, RSSI
RX-AF
Pre AMP, Expander, Receiver AMP
¨ MUTE control
0 ¼¼¼¼normal
1 ¼¼¼¼MUTE
MUTE for Compressor output.
These bits prevent the compander block going into a battery saving mode. Current consumption
therefore does not decrease.
¨ Charge pump current control
PLL loop performance such as lock-up time can be changed by these control bits.
Bit
Control Output
0
1
TX CP
TX-PLL Charge Pump Output Current
200mA
400mA
RX CP
RX-PLL Charge Pump Output Current
200mA
400mA
¨ BATTERY ALARM detection setting
There are has four threshold levels for low battery detection.
These threshold levels are shown on the table below.
(1)
BC
(1)
(2)
BA1
BA2
VBAT-L
0
0
0
3.00V
0
0
1
3.25V
0
1
0
3.30V
0
1
1
3.45V
1
0
0
1
1
1
(2)
Battery Saving
BC bit in REF divider
Only for BATTERY ALARM block
12
April 10, 2000
Preliminary
HT9015
¨ SIG_OUT selection
The SIG_OUT terminal generates combination states of RX and TX lock detectors. The RSSI and
NOISE detector are shown in figure 2 below.
SW1 and SW2 in Fig. 3 determine the output on SIG_OUT using selection bits in a control register according to the figure below.
L D T X
L D R X
R S S I
D e c id e S W 1
a n d L D O U T
N D
D e c id e S W 2
a n d D E T O U T
E x a m p le : T X lo c k d e te c to r o p e r a tio n
L D T X
L D R X
R S S I
N D
1
0
0
0
Figure 2 SIG_OUT bits
R X P L L
S W 1
L O C K D E T E C T O R
L D
O U T
S IG _ O U T
R X L D
T X L D
T X P L L
S W 2
D E T O U T
IF A M P
N O IS E D E T E C T O R
R S S I
R S S I
In te rn a l
R S S I D E T
N D
N _ R E C
N _ F IL _ O U T
N _ F IL _ IN
A F O U T
E x te rn a l
Figure 3 Signal output block diagram
13
April 10, 2000
Preliminary
HT9015
· Example of divider setting
When the LOCAL OSC frequency is 10.240MHz, RX VCO has to oscillate at frequencies from
35.915MHz in 20kHz or 25kHz step.
¨ Reference frequency at the PHASE DETECTOR should be set to 5kHz.
¨ 10.240MHz ¸ 5kHz = 2048, \ R= 2048
¨ Calculate dividing number N for RX divider
¨ 35.915MHz ¸ 5kHz = 7183, \ N (CH16)= 7183
¨ 35.935MHz ¸ 5kHz = 7187, \ N (CH17)= 7187
¨ Finally you set the following registers.
R X D iv id e r fo r 7 1 8 3
C o d e
N
1
1
1
1
0
0
0
0
0
0
1
1
1
0
0
1 s t
1
S T B
R E F D iv id e r fo r R = 2 0 4 8
T e s t B C
1
1
0
C o d e
0
0
0
1 s t
0
0
0
0
0
0
0
1
1
1
S T B
· The power saving arrangement is one of the features in the HT9015.
This is achieved through an inside control register to arrange the power consumption of the three
major parts (RF. IF. PLL). There are two-pair DC power supplies for the HT9015, VCC1-GND1 and
VCC3-GND2. The DC power VCC1 provides operating voltage for the IF detector and the compander
analog parts.
The DC power VCC3 provides the operating voltage for the PLL and data latch control. It also has a
built in 2.0V regulator VCC2 for the RX front end. See the power supply arrangement as shown on
the table below.
VCC1
GND1
1st MIX, 2nd MIX, IF AMP, QUAD, NOISE DET. RX-VCO DATA COMP,
COMPANDER, RECEIVER AMP, SPLATTER.
VCC3
GND2
RX-PLL, TX-PLL, LOCAL OSC, DATA LATCH CONTROL
14
April 10, 2000
Preliminary
· Mixers
Intermediate frequency (IF) decoder part
A Mixer is a non linear device whose purpose
is to convert radio frequencies (RF) to intermediate frequency (IF) (RF-to-IF frequency
translation). In the frequency conversion process, RF signals are combined with the local
oscillator frequency in a non linear device.
The output of the mixer contains an infinite
number of harmonic and cross-product frequencies which include the sum and the difference between the desired RF carrier and
the local oscillator frequencies. The IF
band-pass filter are tuned to the different frequencies. Therefore, the IF signal is filtered
out by the BPF. In the HT9015 the double conversion method (Figure 4) is applied to produce the lower IF.
The figure below shows a simplified block diagram for a double-conversion super heterodyne
FM receiver. Heterodyne means to mix two frequencies together in a non linear device or to
translate one frequency to another using non
linear mixing. The super heterodyne receiver is
an improvement over other receiver in gain, selectivity, and sensitivity characteristics.
The super heterodyne receiver is divided into
five parts:
· RF section. Generally consists of a preselector
and an amplifier stage.
· Mixer conversion section. Includes a ra-
dio-frequency oscillator stage (commonly
known as a local oscillator) and a mixer conversion stage (commonly known as a frequency detector) to produce the IF signal.
· The IF section. Generally consists of a series of
IF amplifiers and bandpass filters and known
as the IF strip. Most of the receiver gain and selectivity is achieved in the IF section.
· The FM demodulator section: The quadrature
FM demodulator uses a 90° phase shift, a single tuned circuit, and a product detector to demodulate the FM signals.
· The audio amplifier section. The audio section
comprises several cascaded audio amplifiers
and one or more speakers. The number of amplifiers used depends on the audio signal
power desired.
The first IF is a relatively high frequency
(10.7MHz), for good image-frequency rejection, while the second IF is a relatively low
frequency (455kHz) that allows the IF amplifiers to have a relatively high gain and still
not be susceptible to oscillations.
2 n d IF
Q u a d ra tu re
D e te c to r
IF _ A M P
2 n d L o _ o s c
( C r y s ta l)
R S S I
L P F
N _ F IL _ O U T
1 s t L o _ o s c
(R X _ V C O )
2 n d IF
Figure 4 The illustration of mixers
A F _ O U T
2 n d M ix e r
C e r a m ic F ilte r
N _ F IL _ IN
1 s t M ix e r
(4 5 5 k H z )
1 s t IF
2 n d L o _ o s c
( C r y s ta l)
1 s t L o _ o s c
(R X _ V C O )
Q U A D
1 s t IF
R F
(1 0 .7 M H z )
C e r a m ic F ilte r
R F
IF _ O U T
In te rn a l
D E C
IF _ IN
2 n d _ M ix in
R F - a m p lifie r
1 s t_ M ix o u t
P r e s e le c to r
2 n d _ M ix o u t
R e c e iv e
a n te n n a
HT9015
N o is e F ilte r
N o is e C O M P
D _ C O M P _ IN
D a ta C O M P
R S S I C O M P
D _ C O M P _ O U T
R S S I
Figure 5 Intermediate frequency decoder block
15
April 10, 2000
Preliminary
· Limiting IF Amplifier, RSSI (Received Signal
HT9015
· Quadrature detector
Strength Indicator) and RSSI Comparator
Once the signal leaves the IF section, it must
be demodulated so that the baseband signal
can be separated from the IF signal. This is
accomplished by the quadrature detector. A
quadrature detector (Figure 7) uses a 90°
phase shifter (Ci), an L/C tuned circuit, and a
phase comparator to demodulate FM signals.
The basic function of the IF amp is to boost
the IF signal and to help handle impulse
noise. The IF limiter applies very high gain to
the IF frequency such that the top and bottom
of the waveform are clipped. This helps in reducing AM and noise intercepted upon reception. The limiting IF amplifier consists of four
differential amplifiers (Figure 6).
L C -T a n k
IF -O U T
D E C
A M P 1
O F -IN
A M P 2
A M P 3
Q u a d ra tu re
D e te c to r
A M P 4
In te rn a l
2 n d IF
S
(R S S I)
Figure 6 Limiting IF Amplifier, RSSI and RSSI comparator
V
L
D D
C
D iffe r e n tia l to
S in g le - E n d e d C o n v e r te r
L C -T a n k
R
D e m o d u la tio n
S ig n a l
IL 2 ¯
IL 1 ¯
L P F
f0 = 4 7 k H z
C
i
V
O
B u ffe r
¯
I1 ¯
IF _ A M P
V
I2 ¯
i
I= I1 + I2 ¯
Figure 7 Quadrature detector
16
April 10, 2000
Preliminary
HT9015
· Noise detector
control register setting. The high state expresses noise level more than 0.4V and the
low state expresses noise level under 0.4V.
Figure 8 is a band pass filter which can detect
noise energy on N_REC pin. There is also a
pass through the noise comparator to determine two states on SIG_OUT pin by internal
V
B a n d - P a s s F ilte r
F O = 3 1 k H z
N o is e
F ilte r
N _ F IL _ IN
E x te rn a l
V
O U T
D D
H ig h - P a s s F ilte r
F C = 2 5 k H z
R 5
A M P
R 4
C 3
N _ F IL _ O U T
N _ R E C
R 3
A u d io S ig n a l
C 1
N o is e C o m p a r a to r
N o is e D e t.
In te rn a l
C 4
C 2
E x te rn a l
R 1
R 2
Figure 8 Noise detector
17
April 10, 2000
Preliminary
HT9015
Compander
In the HT9015, the compressor will take a signal with a 75dB dynamic range (-5dB to
-80dB), and reduce it to a 37.5dB dynamic
range (-7.5dB to -45dB) by attenuating strong
signals,while amplifying low level signals. The
expander does the opposite in that the 37.5dB
signal range is increased to a dynamic range of
75dB by amplifying strong signals and attenuating low level signals. The 0dB level is internally set at 316.227mVrms - that is the signal
level which is neither amplified nor attenuated.
See Figure 9 below. Through the action of the
compander, the noise of the transmission medium is constant under -80dBV.
The compander (compressor and expander) is
composed of two variable gain circuits which
provide compression and expansion of the signal dynamic range. In consideration of the wide
band noise and maximum dynamic range
which exist in the transmission medium, the
general signal handling technique lowers the
general communication quality by reducing the
S/N ratio and generating a clipping phenomenon. However the compander improves the
communication quality by automatically controlling the gain based on the input signal level
to increase the valid dynamic range and to improve the S/N ratio.
C o m p re s s o r
In p u t
C o m p re s s o r
O u tp u t
E x p a n d e r
In p u t
T r a n s m is s io n
M e d iu m
0 d B V
- 5 d B V
- 1 0 .5 d B V
0 d B V
- 7 .7 5 d B V
- 1 5 .2 5 d B V
- 2 0 d B V
- 3 0 d B V
- 4 0 d B V
- 2 5 .2 5 d B V
- 3 5 .2 5 d B V
- 1 0 .5 d B V
- 3 0 d B V
- 4 0 d B V
- 5 0 d B V
- 4 5 .2 5 d B V
- 7 0 d B V
- 8 0 d B V
- 5 d B V
- 2 0 d B V
- 5 0 d B V
- 6 0 d B V
E x p a n d e r
O u tp u t
- 6 0 d B V
- 7 0 d B V
N o is e
- 8 0 d B V
Figure 9 Illustration of compressed and extended signal
18
April 10, 2000
Preliminary
HT9015
PLL
erence frequency for the receiver (RX) and
transmitter (TX) loops.
The figure below shows a simplified block diagram of the programmable universal dual
phase-locked loop (PLL). It provides accurate
channel frequencies for cordless phone.
This dual PLL is fully programmable through
the mC serial interface and supports most country channel frequencies including USA, Spain,
Australia, Korea, New Zealand, U.K., Netherlands, France, Taiwan, and China.
The PLL contains one 14-bit programmable
counter, one phase detector, charge pump, unlock detector and the 2nd local oscillator. The
12-bit programmable counter provides the ref-
V C O _ C O N T
V C O 1
V C O 2
R X _ O U T
T X _ O U T
R X _ V C O
C h a rg e
P U M P (R X )
C h a rg e
P U M P (T X )
1 4 - B it R X
C o u n te r
P h a s e
D e te c to r (R X )
P h a s e
D e te c to r (T X )
1 2 - B it R E F
C o u n te r
L O C A L
O s c illa to r
1 4 - B it T X
C o u n te r
D a ta L a tc h
R e g is te r
L O 2
L O 1
S T B
D A T A
C L K
T X _ IN
Figure 9 PLL block diagram
19
April 10, 2000
R F IN
4 6 .6 1 M H z
V C C 2
C 1 0 1
1 0 0 0 0 p F
C 9
L 1 0
C 1 3
4 5
4 4
V R E F
4 6
C F 1
1 0 .7 M H z
R 9
3 3 0 W
4 5 5 k H z
V C C 1
V C C 1
C 3 0
1 0 m F
N _ R E C
2 N D M IX _ O U T
V C C 1
IF _ IN
D E C
G N D 1
IF _ O U T
Q U A D
3 3
V C C 1
C D
3 4
~
3 5
~
3 6
~
3 7
~
3 8
C 2 9
9 1 p F
C 2 4
0 .1 m F
3 9
C 2 5
0 .1 m F
C 1 9
1 0 0 0 p F
4 0
C 2 1 C 2 3
2 2 m F 0 .1 m F
C 1 7
2 .2 m F
4 1
~
4 2
~
4 3
V C C 2
V C O -C O N T
V C O 1
V C O 2
C _ R E C C T
R X -O U T
T X _ O U T
V C C 3
S IG _ O U T
C _ N F
R 1 6
R 2 2
R 1 7
1 0 k W
C 3 6
1 m F
R 2 1
2 k W
1 9
M IC _ IN
R 1 8
3 .3 k W
P R E _ IN
P R E _ O U T
E X P _ O U T
R E C E _ IN
2 7
2 6
2 5
2 0
2 1
2 2
2 3
R O 1 2 4
R O 2
B A T _ A L M
R S S I
D _ C O M P _ O U T
1 8
M IC _ O U T
1 7
R 2 0
2 0 k W
T
V C C 3
1 0 k W
M IC
C 3 8
1 m F
R 2 4
2 0 k W
R 2 7
1 0 0 k W
1 0 0 0 p F
C 3 7
1 m F
C 2 3
C 3 4
R 1 9
2 2 0 p F
2 2 0 p F
5 0 k W
3 0
N _ F IL _ IN
3 2
3 1
N _ F IL _ O U T
2 9
D _ C O M P _ IN
2 8
A F _ O U T
1 6
C O M P _ O U T
1 5
C 3 2
A u d io O u tp u t
R 1 5
1 .5 k W
1 4
R 1 4
C 3 1
1 0 m F
R 1 3
R 1 1
D A T I
C 2 8
C 2 7
R 1 2
F IL _ IN
1 3
C 2 6
S T B
F IL _ O U T
1 0 k W
D A T A
S T B
1 2
D A T A
1 1
C L K
1 0
C L K
M ic r o c o n tr o lle r
O U T
R 1 0
1 0 0 k W
9
L O 2
8
L O 1
7
C 2 0
C 2 2
S IG
H T 9 0 1 5
4 8 S S O P
2 N d M IX _ IN
4 7
4 8
C 1 5
C 1 0
0 .1 m F
C 1 1
1 0 m F
C 1 2
1 0 0 0 p F
2 .2 m F
L 1 1
1
2
3
4
6
G N D 2
T X _ IN
C 9
1 0 0 0 p F
5
E _ R E C T
R 1 0 2
5 .1 k W
C 1 4
1 0 m F
R 1 1 2
1 0 k W
C 8
0 .1 m F
C 1 8
1 0 m F
1 S T M IX _ O U T
1 S T M IX _ IN
C 1 0 2
0 .2 2 m F
R 1 0 1
1 5 k W
R 1 1 1
1 5 k W
C 1 1 1
1 0 0 0 0 p F
C 1 0 3
1 0 0 0 0 p F
C 1 1 2
0 .2 2 m F
C 1 1 3
1 0 0 0 0 p F
V C O
V C C 3
X 't a l
1 0 .2 4 0 M H z
D A T O
K e y b o a r d & L C D In te r fa c e
R 2 7
1 0 0 k W
V C C 1
C 3 9
1 m F
R E C E IV E R
V C C 1
R
R 2 6
2 0 k W
R 2 5
2 0 k W
R 2 3
2 0 k W
April 10, 2000
20
HT9015
Preliminary
Application Circuits
Preliminary
HT9015
China CT0 frequency
· Base set
RX Counter Value
TX Counter Value
fIN-R Input
(Ref. Freq.=
(Ref. Freq.=
Frequency (MHz)
5.00kHz)
5.00kHz
(1st IF= 10.7MHz)
Channel
Number
TX Channel
Frequency (MHz)
1
45.250
9050
37.550
7510
2
45.275
9055
37.575
7515
3
45.300
9060
37.600
7520
4
45.325
9065
37.625
7525
5
45.350
9070
37.650
7530
6
45.375
9075
37.675
7535
7
45.400
9080
37.700
7540
8
45.425
9085
37.725
7545
9
45.450
9090
37.750
7550
10
45.475
9095
37.775
7555
· Hand set
RX Counter Value
TX Counter Value
fIN-R Input
(Ref. Freq.=
(Ref. Freq.=
Frequency (MHz)
5.00kHz)
5.00kHz
(1st IF= 10.7MHz)
Channel
Number
TX Channel
Frequency (MHz)
1
48.250
9650
34.550
6910
2
48.275
9655
34.575
6915
3
48.300
9660
34.600
6920
4
48.325
9665
34.625
6925
5
48.350
9670
34.650
6930
6
48.375
9675
34.675
6935
7
48.400
9680
34.700
6940
8
48.425
9685
34.725
6945
9
48.450
9690
34.750
6950
10
48.475
9695
34.775
6955
21
April 10, 2000
Preliminary
HT9015
U.S.A. CT0 frequency (10 channels)
· Base set
RX Counter
TX Counter Value
fIN-R Input
(Ref. Freq.=
Frequency (MHz) Value (Ref. Freq.
= 5.00kHz)
5.00kHz
(1st IF= 10.695MHz)
Channel
Number
TX Channel
Frequency
(MHz)
1
46.610
9322
38.975
7795
2
46.630
9326
39.150
7830
3
46.670
9334
39.165
7833
4
46.710
9342
39.075
7815
5
46.730
9346
39.180
7836
6
46.770
9354
39.135
7827
7
46.830
9366
39.195
7839
8
46.870
9374
39.235
7847
9
46.930
9386
39.295
7859
10
46.970
9394
39.275
7855
Channel
Number
TX Channel
Frequency
(MHz)
TX Counter Value
(Ref. Freq.=
5.00kHz
fIN-R Input
Frequency (MHz)
(1st IF= 10.7MHz)
RX Counter
Value (Ref. Freq.
= 5.00kHz)
1
49.670
9934
35.915
7183
2
49.845
9969
35.935
7187
3
49.860
9972
35.975
7195
4
49.770
9954
36.015
7203
5
49.875
9975
36.035
7207
6
49.830
9966
36.075
7215
7
49.890
9978
36.135
7227
8
49.930
9986
36.175
7235
9
49.990
9998
36.235
7247
10
49.970
9994
36.275
7255
· Hand set
22
April 10, 2000
Preliminary
HT9015
Holtek Semiconductor Inc. (Headquarters)
No.3 Creation Rd. II, Science-based Industrial Park, Hsinchu, Taiwan, R.O.C.
Tel: 886-3-563-1999
Fax: 886-3-563-1189
Holtek Semiconductor Inc. (Taipei Office)
5F, No.576, Sec.7 Chung Hsiao E. Rd., Taipei, Taiwan, R.O.C.
Tel: 886-2-2782-9635
Fax: 886-2-2782-9636
Fax: 886-2-2782-7128 (International sales hotline)
Holtek Semiconductor (Hong Kong) Ltd.
RM.711, Tower 2, Cheung Sha Wan Plaza, 833 Cheung Sha Wan Rd., Kowloon, Hong Kong
Tel: 852-2-745-8288
Fax: 852-2-742-8657
Copyright Ó 2000 by HOLTEK SEMICONDUCTOR INC.
The information appearing in this Data Sheet is believed to be accurate at the time of publication. However, Holtek
assumes no responsibility arising from the use of the specifications described. The applications mentioned herein are
used solely for the purpose of illustration and Holtek makes no warranty or representation that such applications
will be suitable without further modification, nor recommends the use of its products for application that may present a risk to human life due to malfunction or otherwise. Holtek reserves the right to alter its products without prior
notification. For the most up-to-date information, please visit our web site at http://www.holtek.com.tw.
23
April 10, 2000