tda5155 NXP Semiconductors, tda5155 Datasheet - Page 11
tda5155
Manufacturer Part Number
tda5155
Description
Pre-amplifier For Hard Disk Drive Hdd With Mr-read/inductive Write Heads
Manufacturer
NXP Semiconductors
Datasheet
1.TDA5155.pdf
(24 pages)
Philips Semiconductors
8.7
The serial interface programming is summarized in
Section 8.7.10.
8.7.1
d0:
d1:
d2:
d3:
d4:
d5:
1997 Apr 08
By default (d0 = logic 0), write data passes from the
write data input via the data flip-flop to the write driver.
The write driver toggles the current in the head at the
falling edges of:
When d0 = logic 1, the write data flip-flop is not used.
The signal polarity is non-inverting from the inputs WDIx
and WDIy to the outputs nWx and nWy.
By default (d1 = logic 0), the pre-amplifier senses PECL
write signals at WDIx(v) and WDIy(v). When
d1 = logic 1, the pre-amplifier senses input write
currents at WDIx(i) and WDIy(i).
By default (d2 = logic 0), the write current is inhibited
under low supply voltage conditions. The write current
inhibit is made inactive by programming d2 to logic 1.
By default (d3 = logic 0), in write mode low supply
voltage, open head, and other conditions are monitored
and flagged at HUS. If d3 = logic 1, HUS is LOW in write
mode and HIGH in read mode.
The amplifier read gain may be programmed in the
configuration register. By default (d4 = logic 0), the read
gain is typically 160 with R
read amplifier gain is 3 dB higher (226 in this case).
In order to minimize the write-to-read recovery times,
the first stage of the read amplifier may be kept biased
during write mode. By default, (d5 = logic 0) the read
amplifier is powered down during write mode, and the
fast settling procedure is activated after write-to-read
switching. If d5 = logic 1 the read amplifier is kept biased
during write mode, and the fast settling procedure still
occurs if the head is changed or the MR current is
re-programmed.
Pre-amplifier for Hard Disk Drive (HDD)
with MR-read/inductive write heads
V
I
data
data
Operation of the serial interface
=
C
=
I
----------------------------------------------
ONFIGURATION
WDIx i
V
----------------------------------------------------- -
WDIx v
–
2
I
–
2
WDIy i
V
WDIy v
MR
= 28 . If d4 = logic 1, the
or
11
8.7.2
By default, d1 = d0 = logic 0, the pre-amplifier powers up
in sleep mode. If d1 = logic 0, d0 = logic 1 or d1 = logic 1,
d0 = logic 0 the circuit goes in standby mode.
If d1 = d0 = logic 1, the circuit goes in active mode (read or
write mode depending on the R/W input).
8.7.3
Selection of a wrong head (H10-H15) causes an head
unsafe condition. HUS goes HIGH when in write mode a
wrong head is selected and when d3 in the configuration
register is LOW. When in read mode and a wrong head is
selected, head H0 is therefore selected and if d3 in the
configuration register is LOW, HUS goes LOW.
8.7.4
The circuit is prepared for servo writing. However, the
device will not be guaranteed.
8.7.5
d2 = d1 = d0 = logic 0. The circuit is not in test mode. This
is the default situation.
8.7.5.1
d2 = logic 0, d1 = logic 0, d0 = logic 1. In read mode, the
voltages at Rx and Ry (at the top of the MR elements) of
the selected head are fed to outputs RDx and RDy.
By measuring the output voltages single ended at two
different I
measured according to the following formula:
Open head and head short-circuited-to-ground conditions
can therefore be detected.
d2 = logic 0, d1 = logic 1, d0 = logic 0. Same as before,
with the difference that I
value of 5 mA. Measuring in the same way as above with
I
shorted together.
8.7.5.2
d2 = logic 0, d1 = logic 1, d0 = logic 1. The temperature
monitor voltages are connected to RDx and RDy.
The output differential voltage depends on the
temperature according to: dV = 0.00364
0 < T < 140 C. The temperature may be measured with a
typical precision of 5 C.
R
MR1
MRx
> 5 mA, enables the detection of MR elements
=
P
H
S
T
MR
V
-------------------------------------- -
I
EST
OWER CONTROL
ERVO WRITE
EAD SELECT
MRx1
RDx1
MR head test
Temperature monitor
currents, the MR resistance can be accurately
–
–
V
I
MRx2
RDx2
MR2
for the x-side.
is fixed to a minimum constant
Preliminary specification
TDA5155
T + 1.7;
Related parts for tda5155
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
NXP Semiconductors designed the LPC2420/2460 microcontroller around a 16-bit/32-bitARM7TDMI-S CPU core with real-time debug interfaces that include both JTAG andembedded trace
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
NXP Semiconductors designed the LPC2458 microcontroller around a 16-bit/32-bitARM7TDMI-S CPU core with real-time debug interfaces that include both JTAG andembedded trace
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
NXP Semiconductors designed the LPC2468 microcontroller around a 16-bit/32-bitARM7TDMI-S CPU core with real-time debug interfaces that include both JTAG andembedded trace
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
NXP Semiconductors designed the LPC2470 microcontroller, powered by theARM7TDMI-S core, to be a highly integrated microcontroller for a wide range ofapplications that require advanced communications and high quality graphic displays
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
NXP Semiconductors designed the LPC2478 microcontroller, powered by theARM7TDMI-S core, to be a highly integrated microcontroller for a wide range ofapplications that require advanced communications and high quality graphic displays
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
The Philips Semiconductors XA (eXtended Architecture) family of 16-bit single-chip microcontrollers is powerful enough to easily handle the requirements of high performance embedded applications, yet inexpensive enough to compete in the market for hi
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
The Philips Semiconductors XA (eXtended Architecture) family of 16-bit single-chip microcontrollers is powerful enough to easily handle the requirements of high performance embedded applications, yet inexpensive enough to compete in the market for hi
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
The XA-S3 device is a member of Philips Semiconductors? XA(eXtended Architecture) family of high performance 16-bitsingle-chip microcontrollers
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
The NXP BlueStreak LH75401/LH75411 family consists of two low-cost 16/32-bit System-on-Chip (SoC) devices
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
The NXP LPC3130/3131 combine an 180 MHz ARM926EJ-S CPU core, high-speed USB2
Manufacturer:
NXP Semiconductors
Datasheet:
Part Number:
Description:
The NXP LPC3141 combine a 270 MHz ARM926EJ-S CPU core, High-speed USB 2
Manufacturer:
NXP Semiconductors
Part Number:
Description:
The NXP LPC3143 combine a 270 MHz ARM926EJ-S CPU core, High-speed USB 2
Manufacturer:
NXP Semiconductors
Part Number:
Description:
The NXP LPC3152 combines an 180 MHz ARM926EJ-S CPU core, High-speed USB 2
Manufacturer:
NXP Semiconductors
Part Number:
Description:
The NXP LPC3154 combines an 180 MHz ARM926EJ-S CPU core, High-speed USB 2
Manufacturer:
NXP Semiconductors
Part Number:
Description:
Standard level N-channel enhancement mode Field-Effect Transistor (FET) in a plastic package using NXP High-Performance Automotive (HPA) TrenchMOS technology
Manufacturer:
NXP Semiconductors
Datasheet: